O ,. 0RNL--6 086/VIDE91 000527
Physics Division
ATOMIC DATA FOR FUSION
VOLUME 1
COLLISIONS OF H, H2,He and Li ATOMS and IONS' with
ATOMS and MOLECULES
C. F. Barnett
Oak Ridge National Laboratory
Published and Ed,]ted byControlled Fusion Atomic Data Center
O H.T. Hunter and M. I. KirkpatrickSeries Technical Editors
I. Alvarez, C. Cisneros, University of Mexico, ,and R. A. Phaneuf
Contributing Editors
Date Published- July 1990
Prepared for theOffice of Fusion Energy
U.S. Department of EnergyWashington, DC 20545
Budget Activity No. AT 05 30 04 0
Prepared by theOAK RIDGE NATIONAL LABORATORY
Oak Ridge, Tennessee 37831-6372operated by
'MARTIN MARIETTA ENERGY SYSTEMS, INC.for the
U. S. DEPARTMENT OF ENERGY
under contract DE-AC05-84OR21400 _ _ '_i .......r
Printed in the United States of America. Available from
National Technical Information Service
U.S. Department of Commerce
5285 Port Royal Road, Springfield, Virginia 22161NTIS pr=ce codes--Printed Copy: A-99Microfiche A0]
This report was prepared as an account of work sponsored by an agency of theUnitedStatesGovernment.Neither theUnited StatesGovernmentnorany agencythereof, nor any of their employees, makes any warranty, expressor implied, or qlFassumes any legal liability or responsibility for the accuracy, completeness, orusefulness of any information, apparatus, product, or process disclosed, orrepresentsthat itsuse would notinfringe privatelyownedrights.Reference hereinto any speclflccommercial product, process,or servicebytrade name, trademark,manufacturer, or otherwise, does not necessarily constitute or imply itsendorsement, recommendation, or favoring by the United States Government orany agency thereof. The views and opinions of authors expressed herein do notnecessarily state or reflect thoseof the United StatesGovernmentor any agencythereof.
I
iii
ATOMIC DATA FOR FUSION
VOL. 1
COLLISIONS OF H, li2 , }le, AND bi ATOMS AND
IONS WITH ATOMS AND MOLECULES
Foreword ........................... xiil
Series Preface ........................ xv
Abstract ............................ xvli
Introduction .......................... I-i
A. Electron Capture Collisions
H + H -> H- + H + ........................ A-2H + H2 -> H"_ + H2 . ....................... A-8
• . A-10H + He -> H- + He + • .....................
H + Li -> H- + Li + ....................... A-16
H + H- -> H- + H ........................ A-20
H. + H -> H + H . ........................ A-22
H. + H2 -> H .......................... A-28
H* + H2 -> H- . ......................... A-30H _ + He -> H + He . ....................... A-32
H . + He -> H- + He2+ ....................... A-38
H. + Li -> H + Li . .............. ......... A-40
@ H. + H- -> H- + H. .....................A-44
H_ + H- -> 2H ........................... A-46
H* + He + -> o(He 2. Total) ................. A-48H. + }le. -> H + He 2_ ..................... A-54
H2 + + H -> H 2 + H + ....................... A-58
H2+ + H2 _> H2 . . . ...................... A-58
I]2+ + He -.> H2 4 He + ......... .............. • A-58
H2.(u) + H2 _> H2 .... ..................... A-60
He . + H -> He + H + ....................... A-62
He + + H--> He + H ....................... A-86
He . + H 2 -> He .......................... A-68
He . + He -> He + He + ...................... A-70He . + Li -> He 4 Li . . . . : .................. A-76
He . + He* -> He + He 2* ..................... A-86
He 2. + He + -> He* + He 2+(Partial & Total) ............ A-84
He 2. + H- -> He . + H ..................... A-86
He 2. + H -> He + + H . ............... ....... A-88
He 2+ 4 H 2 -> He . . . . .................. A-94
He 2* + H 2 -> He ......................... A-96He 2. + He -> He . 4 He + ...................... A-98
He 2+ + He -> He + He2+ . .................... A-J04
He 2. + Li -> He + + Li _ ..................... A-I10
He 2_ + Li -> }le + Li2 . ..................... A-I14
l
iv
q
B. Electron Capture into Excited States Q
H _ + H -> H(2s) + H+ ............... ........ B-2H* + H -> H(2p) + H' • ................. B-8
H + + H 2 -> H 2_) .................... B-14
H . + H 2 -> H 2p) ..................... B-14
H . + H 2 -> H Lyman-a Total) .............. B-16
H . + H 2 -> H Balmer-_) ................. B-18
H + + H 2 -> H Balmer-B) ................ B-18
H . + H 2 -> H 3s) ..................... B-20
H* + H 2 -> H 3p) ...................... B-20H . + H 2 -> H 3d) . • ................... B-20
H + + He -> H 2s) + He* ................... B-22
H* + He-> H 2p) + He' B-28
H . + He -> H Balmer-_) + He + B-34
H . + He -> H 3s) 4 He* .................... B-40
H . + He -> H(3p) + He" • ................. B-46
H* + He -> H(3d) + He + .................. B-52
H + + [ai -> H(2s) + bi + • ................. B-58
H + + bi -> H(2p) + Li* • ................. B-58
H + + Li -> H(3s) + Li* .................. B-60
H + 4 Li -> H(3p) + Li _ .................. B-60
H . + Li -> H(3d) + Li + .................. B-60
He+ + H2 -> H(21S + 23S) .................. B-62
He. + H2-> He(21P) ...................... B-64
He+ + H2 -> He(31p) ...................... B-64
He + 4 H2 -> He[x = 44"7.1 nra) ................ B-66
He + + H2 -> He(x = 587.6 nra) ............... B-66He + + H2 -> He(x = 667.8 nra) ................ B-66
He* 4 He -> He(21S 4 23S) + He + .............. B-68
He + _ He -> He(21p) + He + ................. B-74
He + + He -> He(31S) + He* • ................ B-80
He + + He -> He(31p) + He" • ................. B-80
He + + He -> He(31D) + He + ................. B-80
He _ + h3 -> He(33S) + He* • ................. B-82
He* + He -> He(33p) + He + .................. B-82
He + + He -> He(33D) + He* • .................. B-82
He . + He -> He(41S) + He + .................... B-84
He* + He -> He(41P) + He _ • .................. B-84
He + + He -> He(41D) + He 4 ................... B-84
He + + He -> He(43S) + He + • .................. B-86
He + + He -> He(43p) + He' • ............... B-86
He + + He -> He(43D) + He" • • ................. B-86
He + + Li -> He(53.7 nm) + Li + ................ B-88
He + + Li -> He(58.4 l_n) + Li + .................. B-88
He 2+ + H -> He_(2s) + H* .................. B-90
He 2. + H -> He+(2p) + H* • ................ B-96
He 2+ + H .-> He_(Ly1_lan-a) + H + • ................ B-lO2
He 2+ + H-> He.(Lyman-B) + H _ • ................ B-lO2
He 2+ + H -> He+(L_allan-_') + H + ................. B-J02
He 2. + H-> He.(Balmer-a) + H _ ................ B-J02
He 2. + H -> He+(3p) + H.
He 2_ + H -> He+(3s+3d) + H* .................. B-104................. B-104
He 2+ + H -> He.(4p) + H. ................ _ . . B-104
He2+ + H2 -> He+(2s) ....... .............. B-J06He 2+ + H 2 -> He .(2p) ..................... B-lO6
He2* + H2-> He.(LY man-=) ...... '. ............ B-lO8
He2+ + H2-> He+(b_.an-B) ................... B-lO8
I
V
O B. Electron Capture into Excited States (Cont'd]
He 2. + H2 -> He +(Ly111an-Y) .......... . ........... B-IO8
He 2+ + H 2 -> He+(Balnler-a) . . . B--108
He 2. + H2 -> He+(3p) ................... . . B-IlO
He 2+ + H 2 -> He_(3s+3d) . . . . ........... B-IlO
He 2. + H 2 -> He+(4p) ....................... B-IlO
He 2+ + He -> He +(2s) + He + ................ , B-112
He 2+ + i,i -> He+(2p) + [si+ . ................. B-.II8
He 2+ + [,i-> He+(3p) + bi + ...... .... . . . ....... B-I18He 2. + Li -> He+(4p) + Li! . . .......... . . . . B-118
He 2+ + bi -> He+(3s+3d) + Li + . . ., .............. B-II8He 2. + bi -> He+(4S+4d) + Li _ .................. B-II8
He 2+ + Li -> He+(Ly_llan-a) + 5i + ............. . . . . B'I20He 2. + Li -> He+(b]nllan-B) + Li . ........... ..... B-120
He 2. + Li -> He+(by]llan-7) + Li _ ................. B-120
He 2+ + Li -> He+(Salnler-_) + bi + . ...... ........... B-122
He z+ + Li -> He+(Ba].mer-_]) _• Li . . ............. . . . B-122
He 2+ + 5i -> He+(Ballner-1) + Li + . .... ............ B-122
He 2. + Li -> He+(Ba]nler-o) + Li + . . . ........ . . B-122
C. E×citatiol ! and Spectral bine Emission
H + H-> H(2s) .... ...................... eZ2-> H(2p) ......................... C-2-> H(3s) .......................... C-4
-> H(3p) ............. . . ........... C-4-> H(3d) ....................... C-4
O -> H(Balnler-a) ...................... C-4
H + H 2 -> H(2s) [projectile ] .................. C-6
-> H(2p) [projectile] .... .......... C-6-> (2s) [target] . . ................. . . C-6-> (2p) [target] ............. ......... C-6
-> (L_nan-a) .... .............. C-8
-> H(3s) i ...... ......... ....... " ' C-10-> H(3p+3d .......................... C-lO-> H(Balmer-_) ...................... C- 12
-> H(4s) . ................... .... (i!-14-> H(4p+4d) ...................... C-14
-> H (Balmer-8) ........................ C-14
H(2s) + H2 -> H(b_allan-a) ..... . . .... .... . . C-16-> H(3s) ....................... C-18-> H (Bahner-c,) .................. C-18
H(2s) + He -> H(L_allan-¢,) ........ ............ C-20
-> H(3s) . . . .................... C-22-> H (Balnler-a) ..................... C-22
H + He -> H(h_nnan-a) ...................... C-24
-> H(2s) ..... ................... C-30
-> H(2p) ..... . ................. C-30-> H(3s) ..................... <:-32
-> H(3p) .... ..... . .......... C-32-> H(3d) ....... ............... C-32-> H(3p43di .................... C-32-> H (Balnler-a) ................... C-34
--> H (Balmei-_) ................... C-34
~> H(4s) .................. .... C-36
O -> H(4p+4d) ...................... C-36-> He(31P) ...................... C-38
!
vi
C. Excitation and Spectral Lille Eluissio,l (Cont'dl. O
H + He -> He(33P) .......... . • .......... . • C-38
-> He(33D) .................. C-38
-> He(41S) ........................ C-40
-> He(41p) ...... : ................. C-40
-> He(41D) ....................... C-40
-> He(43S) ........................ C-42
-> He(43P) ..... . ........... ........ C-42-> He (43D) .......................... C-42
i
H _ + H -> H(2B) ......... .............. .... C-44
-> Ii(2p) ......................... U-44-> H(n=2) ........................ C-48
-> H(n=3 ) ......... .... ........ C-48-> H(n=4) ......................... C-48
H . + H2 -> H+ + H(2B) + H ........... _ ....... C-50
-> H . + H(2p) + H ................... C-50
-> H + + H(3p) + H .................... C-52
-> [_(Lyman- a) ..................... C-54-> H (Balnler-_) .................... C-56
-> H(Balmer-D) .................... C-56
-> H (Balmer-x) .................... C-56J
-> H2 (L]allan-Band ) .................... C-58
-> H2 (U_llan-Band ) .................... C-58
H+ + He -> He(21S) ....................... C-60
-> He(21p) ..................... C-60
-> He(21S + 21P') ' O
, . . ................ C-60
-> He(31S) ........................ C-66
-> He(31p) ....................... C-66
-> He(31D) ....................... C-66
-> He(41S) ..................... C-68
-> He(41P) ....................... C-68
-> He(41D) ....................... C-68
-> v.u.v. (20-140 nra) .................. C-70
He + + H -> H(n=2) ........................ C-72
-> H(2s) ........................ C-74
-> H(2p) ....................... C-74
He + + H2 -> H(b]allan-a) ..................... (;-78
-> H (L_allan-B) .................... C-78 I
-> H (Balmer-a) ..................... C-80
-> H(Balmer-B) . .................. C-80
-> H(2B) ..... .................. C-82-> H(2p) ...................... C-82-> H(3B) ..................... C-84-> H(3p) • ...................... C-84-> He +(2s) ...................... (]-86
He + 4 He -> He(21S) [target] ................. C-88
-> He(21p) [ta,rget ] ............... C-88
-> He(23S) [ta, cIet] ............... C-90
-> He(23P) [target] ............ C-90
-> He(31S) target] ............. C-92
-> He(31p) target] ............ C-92
-> He(31D) target] .............. (?-92
-> Iie(33S) ta£_get ] ........... C-94
-> He(3]P) target] ............. C-94 O-> He(33D) target] ......... C--94
iI
vii
c. Excitation and Spectral Line Emission (Co[_t'd)
He + + He -> H_(41S) [target] .................. C-96
_> He[41p) itarget ] .................. C-96
-> He(_iD) [target] ................. C-96
-> He(4]S) [target] .................. C-98
-> He(43p) [target] .................. C-98
-> He(43D) [target] .................. C-98
-.> He* (n=2) [projectile] ................ C-100
-> He+ (n=3) [projectile ] ................ C-I02
He + H2 --> H(Balmer-_,) ..................... C--I04
-> H (Balmer-B) ..................... C-]04
He + He _> He(21S) ....................... C-I06
_> He(21p) ....................... C-]06
_> He(31p) ..... .................. C-I08
_> He(31D) ...................... C-!08
_> He(33p) ...................... C-I08
_> He(33D) ........................ C-i08
41S) ....................... C-110-> He(4 _ .............-> He( P) ........... C-II0
_> He(43S) ........................ C-I12
_> He(43p) ...................... C-I12
_> He(2s 2 IS) ...................... C-I14
_> He(2s2p3p) ...................... C-I14
_> He(2p 2 ID) ...................... C-I14
_> He(2s2plp) ..................... C-]14
_> He-(is2s 2 2S) .................... C-I14
He 2_ + H -> H(2s) ....................... C-i16
-_ H(2p) ........................ C-I16
He(23S) + He(llS) -> He(31p) + He ............... C-I18
-> He(33p) + He ................ C-120
-> He(43S) + He .............. C-122
-> He(43D) + He ................ C-122
-> He 4 He(43S) ................ C-124
-> He + He(43D) ................ C-]24
H+ + 51(2s) -> Li(2p) .................. _ • C-126
-> 5i(670,8 nra) .................. C-126
He + + Li(2s) -> Li(670.8 nra) ................. C-128
He 2+ _ Li(2s) -> bi(2p) ..................... C.-130
-> Li(670.8 nra) .................. C-130
D. Ionization Collisions and Charqe Production
H '- H2 -> Total Slow Positive Ion Production ......... D-2-> Total Slow Electron Production ............ D-2
-> H + H2 . + e ...................... D-4
H/ + H -> H4 + H + + e ...................... D-6
_|_ + H- -> H2 + + e ....................... D-J2
H + t. H2 -> Total Slow Electron Production .......... D-J4-> H . + H2 • e .................... D-!6
viii
D. Ionization Collisions and Charqe Production (toni'd) O
H* + H 2 -> Total Production of H2 + ............... D-16-> Total Production of H. ................ D-16
H. + He -> Electrons and H- . .................. D-18
-> H* + He* + e ......... D-24
-> (H + He*) or (H+ + He+ + e) .............. D-24
-> H + + He 2+ + 2e . . . . . ................ D-34
-> (H- + He 2+) or (H* + He 2* + 2e) ............ D-34
He(21S) + H -> He + H+ + e ................... D-42-> He}l* + e ........... D'42
-> (He + H. + e) or Hell+ + e) ......... D-42
He (23S ) + H -> He + H+ + e ................... D-_4-> Hell. + e ..................... D-44
-> (He + H* + e) or (Hell_ + e) ........... D-44
He(23S) + H 2 -> Total Ionization ................ D-46
-> Rearrangement Ionization ............ D-46
He (21S) + H2 -> Total Ionization ................ D-48
-> Rearrangement Ionization ............ D-48
H* + He _ -> (H . + He 2+ + e) .................. D-50
-> (H. + He 2. + e) or (H ° + He 2+) ............ D-50
He . + He* -> (He . + He z. + e) ........... D-58
-> (He + He 2_) or (He*
• w • • • •
+ He 2_ + e) .......... D-58
He + H2 -> Total Slow Positive Ion Production ......... D-64-> Total Slow Electron Production ............ D-64
-> He + H2 . + e ..................... D-66-> Total H + Production .................. D-66
He + He -> Total Slow Positive Ion Production .......... D-68-> Total Slow Electron Production ............ D-68-> He 4 He . + e ...................... D-70
-> He + He 2* 4. ?e .................... D-70
He . _ H -> He + + H . + e ..................... D-72
He . + H 2 -> Total Slow Positive Ion Production ......... D-76
-> Total Slow Electrpn P_:oduction ........... D-76
He + + H 2 --> (He + H2 .) or (He . + H2+ + e) ............ D-78-> Total H . Production ................. D-78
-> He + + H _ 4 H . + 2e ................. D-78
He . + He -> Total Slow Positive Ion Production ......... D-80
-> Total Slow Electron Production . , ......... D-80 I
-> He* + He* + e ............... D-90
-> He + + He 2. + 2e . . . ................ D-90
He 2_ + H -> He 2. + H+ + e .................... D-96
He 2+ + H 2 -> Total Slow Positive ]on Production .......... D-]O0-> Total Slow Electron Production ........... D-lO0-> Total H. Production ................ D-lO2
-> H_ Production by Ionization Col]islons ....... D-102
-> Total tt 2 Production ................ D-lO2
-> 1t2 . Production by Single-Ionization ........ I)-.132
ix
D. Ionizatlml ColllSious aild Charqe Production {Con t'd)
He 2. + He -> Total Slow Positive Ion Production ......... D-104
-> Total Slow Electron Productiol] ......... _ . . D-lO4-> He 2. + He + + e ................... D-[I_
-> He 2. + He 2+ + 2e .................. D-II4
H + + Li -> H . + Li + i e . . . , . , . ....... . D-]22
He + + Li -> He _ + Li + + e ................ .... D-126
He 2+ + Li -> He 2. + Li _ + e ................... D-128
E. Electron Loss or Strippinq Collisions
H + H -> H. + H + e ............ ........... E-2
H(2s) + H(Is) -> H+ + H 4 e ........ ..... ..... E-4
H + H 2 -> H . + H 2 + e ...................... E-6
H(28) + H2 -> H+ + H 2 + e ................. .... E-8H + He -> H . + He + e .................... E_]O
H(2s) + He -> H. + He + e ...... ............. . F,-14
He + H -> He _ + H + e .................. E-16
He + H2 -> He . + H2 + e ..................... E-18
He + Hz -> He 2. + H z + 2e .................. , . B-J8He* + H2 -> He or He + ......... E-20
He* + H2 -> He _ + H 2 + e ......... ........ . E-20
He* + H2 -> He + H2 .......... ........ E-2 o
O He • He -> He + + He + E-22e
He + He -> He 2+ + He + 2e ..................... E-22
He _ + H -> He 2+ + H 4 e ...................... E-28
He . + H2 -> He 2. + H2 + e ........ ............ E-30He _ 4 He -> He _-. + He + e .................... E-32
F. Electron Detachment Collisions
H- + H -> H + II + e ..................... F-2
-> (H + H + e) or (H + H-) ............... F-2-> H+ _ H + 2e .................. F-4
11- + H _ -> H + H _ + 2e ............ . ........ F-6
H" + H 2 -> H + H 2 + e ...................... F-8
-> H+ + H2 + 2e ....................... F-10H- + He -> H + He + e ...................... F-12
-> H+ + He + 2e ................... F-14
He" + H -> He + H + e ...................... F-16
He" + |I2 -> He + II2 + e ..................... F-18
-> He _ + H2 + 2e ........ . ............ F-18
He- + He -> He + He + e ................... F-20-> He + + He + 2e ................... F-20
Li" + H2 -> Li + H2 + e .................... F-22-> Li + + '_ + 2e F-22
Li" + He -> Li + He + e .................... F-24
-> Li + } }le 4 2e .................... F-24
0
X,
G. Dissociative Coli] sions
H + H 2 -> H-4 (H . 4 H*)+ e ................. 0-2
-> H + (H + + H*) + 2e . • . ..... , , ...... 0-2-> H+ -! (H _ + H+) + 3e .................... 0-2
-> H + (H + H _) 4 e . . • , ............ . . . 0-4
-> H+ + (li + H_) + 2e ............ . . . , . . . 0-6
-> lt- + (H' + H) ..... • • .............. C_-8
H* 4 li2 -> H + + H + + H + _ 2e ................... , 0-].0
He + + H 2 -> He + + H . + H + + 2e .... . . . ........... G-12
He 2+ 4 H2 -> He 2. + (H + + H) + e (via iSOg) . .......... G-g4-> He 2. + (H . + H) 4 e (via 2POu) ..... ...... 6]-.16
.> He + + (H. + H I • .................. O218-> He + + (H . + H ) + e . . ..... ......... 0-20
-> He 2. + (H . + H .) + 2e ........ . . . . . . 0222-> He + (H + + H+) ' . .... ............... G-24
H2 + -_. H2 -5. H+proj. . ....................... G-26
H2 + + H -> H_proj........ ................... 0-28
H2 . + H2 -> ||proJ. ................ ..... G-30
-> (H + + H) + H2 ............... • .... 0-3.2
H2 + + He -> Total H + • . • • ........ G-34
-> (H . + H) + He ........ ............ 0-36 O
H2 + H2 -> H.(Fast,Total) .......... .......... G-38
-> H (Fast,To_al ) ................. 0-40
-> Total Destruction of Fast H 2 Proj . . ........ G-42
H3 + + H2 -> Total Destruction of H3+ ....... .... 0-44
H2 + + H2 -> Total Destruction of H2 + . .............. 0-46
H3 + H2 -> H.(Total,Projectile) ................. 0-48
-> H2+ (Total, Projectile ) ................ 0-50
-> H(Total, Projectile) ................. G-52
-> H2(Total,Projectile) ................ . . G-54
H3 _ + He -> H.(T0 tal) ................... . . . . G-56-> H2 • • ..................... G-5R
Hell . + H2 -> Total Hell . Disoociation Prod ............ G-60
HeH + + He -> Total HeH . Dissociation Prod. • .......... G-62
H, Particle Interchanqe Reactions
H+ + D2 -> D+ + HD ....................... H-2
-> HD . + D ....................... H-2
HD + + D2 -> HD2 . + D ...... ................ H-4
-> D3 +
+ H ............. . ......... H-4 O
x 1/)CIt
O H. Particle Interchanoe Re.actions Lcont'd)
J
HD+(v=O) + He -> Hell _ + D . ....... , .............. H-6
HD+(v=I) + He -> HeH + + D ............. , ...... H-6
HD+(u=2) + He -> Hell. + D _ . .......... ......... H-6
HD+(u=3) + He -> Hell+ + D , . . . ................ H-6
HD +(v=4) + He -> Hell. + D .................... ' H-6
H2 + + Fie -> Hell_ + H ................ .... . • H-8
H2 _ + H 2 -> H3 . + H .............. , . ........ H-lO
D2+ + D2 -> D3 . + D ............ • .......... _-12
........ D,2. _+ ,'. (u=0,)_, ,+, .H2 .... >, .HD 2 .rF, ,H .... , .......................... , .... ..................... ., H,..rI4 .... . ........
D2 +(u=i) + H2 -> HD2 + + H . H-14. • • • . • • o • • , ,,, • ,., • • • • , •
D2+(v=2) + H2 -> HD2* + H . ....... . . . . ....... . H-14
D2+(u=3) + H 2 -> HD2 _ + H .... ............... H-14
H2+(v=0) + D2 -> HD2 . + D ........ . .. ........ H-16
H2+(v=I) + D2 -> HD2 . + D . . . ........... • . . .... H-i6
H2 +(u=2) + D 2 -> HD2 + + D ..................... H-16
• H2.(u=3) + D2 -> HD2 _ + D .................. . . H-16
H2+(u=4) + D 2 -> HD2 . + D ..................... H-16
0References ........... ............ . . . • R--1
Appendix iz Calculation of Cross Sections and Rate Coefficients
fronl Chebyshev Fitting Parameters ...... ,, .... 1-1
Appendix 2: ALADDIN Database System and Data Files ....... 2-1
Ap_,endix 3z Atomic Physics (Handy Conversion Unfts and formulas) 3'i
O
J
O FOREWORD
The Controlled Fusion Atomic Data Center (CFADC) was
founded informally at Oak Ridge National Laboratory by Clarence
F. Barnett in 1959, and was officially established six years
later. The continuing mission of the CFADC is to identify,
compile, evaluate and recommend data on atomic and molecular
collision processes which are important in fusion energy
research. "Barney" dedicated much of his professional career to
the promotion of effective scientific communication between the
atomic and fusion research communities, and was still-actively
engaged in this mission at the time of his death in 1989. This
"RedboOk" volume represents a major part of his continuing
professional efforts during the years following his formal
retirement from ORNL in 1985. Barnett's insights, guidance and
dedication to this mission will.be sorely missed by the CFADC
and by the fusion research community.
Ronald A. Phaneuf
Hamilton T. Hunter
M. Imogene Kirkpatrick
David H. Crandall (DOE) •
This photo is from his "official" retirement in 1985. His
spirit will continue to encourage us in the future.
O Series PreZace
The primary objective of the Controlled Fusion Atomic Data
Center at Oak Ridge National Laboratory is to publish and
distribute handbooks containing numerical and graphical cross-
section and other physical data relevant to fusion energy
research. In 1977, a two-volume compilation was published as
ORNL reports ORNL-5206 and ORNL-5207. Since that time, a
large volume of pertinent data has become available, necessi-
tating an update and expansion of the previous compilation. .
The specific volumes in this series, entitled "Atomic Data forFusion," are listed below.
Vol. i, "Collisions of H, H2, He, and Li Atoms and Ions withAtoms and Molecules," C. F. Barnett, ORNL, ORNL-6086
(June 1990).
Vol. 2, "Collisions of Electrons with Atoms and Molecules F"
J. W. Gallagher, National Institute of Standards and
Technology; and D. C. Gregory, ORNL (in preparation).
" E W ThomasVol. 3, "Particle Interactions with Surfaces, . . ,
Georgia Institute of Tecl_nology, ORNL-6088 (January
1985).
0 " W. L Wiese NationalVol. 4, "Spectroscopic Data for Iron, . ,
Bureau of Standards, ORNL-6089 (March 1985).
Vol. 5, "Collisions of Carbon and Oxygen Ions with Electrons,
H' .}{2' and He," R. A. Phaneuf, ORNL; R. K. Janev,nstltute of Physics, Yugoslavia; and M. S. Pindzola,
Auburn University, ORNL-6090 (.January 1987) .
Vol. 6, "Spectroscopic Data for Titanium, Chromium, and
Nickel," W. L. Wiese and A. Musgrove, National
Institute for Standards and Technology, ORNL-6551
(September 1989).
C. F. Barnett
H. T. Hunter
M. I. KirkpatrickR. A. Phaneuf
June 1990
xvii
ABSTRACT
This report provides a handbook of ,recommendedcross-section andrate-coefficient data for inelastic
collisions between hydrogen, helium and lithium atoms,
molecules and ions, and encompasses more than 400
different reactions of primary interest in fusionresearch. Published experimental and theoretical data
have been collected and evaluated, and the recommended
data are presented in tabular, graphical and
parametrized form. ProcesSes include excitation andspectral line emission, charge exchange, ionization,
stripping, dissociation and particle interchange
reactions. The range of collision energies is
appropriate to applications in fusion-energy research.
r
I-i i
INTRODUCTION
This volume contains recommended cross-section and rate'coefficient data for inelastic collisions between hydrogen,
heliumand lithium atoms, molecules and ions, and encompasses
383 different reactions of primary interest in fusion research.
Published experimental and theoretical data have been collected
and evaluated, and the recommended data are presented in
tabular, graphical and parametrized form. Inelastic processesinclude excitation and spectral-line emission, charge exchange,
ionization, stripping, dissociation and particle interchange
reactions. Emphasis has been given to the range of collision
energies appropriate to diagnostic and modelling applications infusion-energy research.
The data which form the _ basis for this volume of
recommended d_ta are those which were available as of September
1988. The bibliographic files of the ORNL Controlled Fusion
Atomic Data Center provided the lists of references for thisvolume. In the vast majority of cases, the numerical data were
obtained from the original publications, either from tables
where available, or from figures using a precision graphical
digitizer system. The rms uncertainty associated with the
digitization system was determinedto be less than 2%.
The recommended data in this compilation are based almost
O exclusively on experimental data. Theoretical data have beenconsidered when it was desirable to extend the measurements to
higher or lower collision energies, and also for a few importantreactions where experimental data were unavailable. Specific
references to the literature and notes are presented for each
reaction, along with an estimated uncertainty in the recommendedcross section. The latter was determined from uncertainties
quoted in the original data sources, and also from theconsistency of the data when more than one source was available.To determinethe recommended cross sections in the latter case,
relative weightings were made on the basis of the reliability of
the different experimental methods used. In some cases,
possible effects on the measurements due to other competing
processes were also considered in detez_ining the reconunendedcross section and its estimated uncertainty. For some
reactions, it was not possible to estimate an uncertainty. In
all cases, the estimated accuracies of the recommended dataarebelieved to have been conservatively estimated, and are intended
to represent upper limits.
Reaction rate coefficients have been calculated from the
recommended cross-section data where appropriate for fusion
applications, and where the energy range of the available data
permits. These are based on Maxwellian velocity distributionsfor each reactant, where each may be characterized by a
O different temperature, and also for the case of a monoenergetic
I-2
(neutral) beam interacting with a Maxwellian distribution. Thetemperature ranges for the calculated rate coefficients are
constrained by the energy range over which cross-section dataare available. The tabulated Values for the rate coefficients
have been flagged in those temperature ranges where the limited
energy range of the data appreciably influences their accuracy.
For convenience, least-squares Chebyshev polynomial fits to
the recommended cross-sections and rate coefficients are pre-sented for each reaction. These polynomial fits are indicated
graphically, and a statement is made concerning the accuracy ofeach fit to the recommended data. Practical deuails on the
least-squares fits and sample computer programs for rapidlygenerating the recommended cross sections and rate coefficients
from the fitting coefficients are presented in Appendix i.
For further ease of retrieval and application of the recom-mended cross-section data, a PC-DOS formatted diskette has been
prepared and is available for distribution. Included on this
diskette are data files with the Chebyshev fitting coefficients
for each reaction encoded in ALADDIN format, 1,2 along with a copy
of the ALADDIN program (written in FORTRAN-77). The ALADDIN
program and data files may also be conveniently transmitted by
electronic mail. Further details about ALADDIN are presented in
Appendix 2, along with samples of the data entries from each
chapter. Information about how to obtain the program and data @files for this and other compilations may also be found inAppendix 2.
i. R. A. Hulse, "The ALADDIN Atomic Physics Database System,"pp. 63-72 in Atomic Processes in Plasmas, AIP Conference
Proceedings 206, ed. Y. K. Kim and R. C. Elton, AIP, NewYork, 1990.
2. ALADDIN Manual, A System for Storage, Exchange and Manaqe-
ment of Atomic and Molecular Data for Fusion, IAEA-NDS-AM-
17, Atomic and Molecular Data Unit, Nuclear Data Section,International Atomic Energy Agency, Vienna, June 1989.
O A. Total Electron Capture Cross Sections '(* denotes rate coefficient data also)
Page
Electron Capture by Neutral H ....... A-2
H + H -> H- + H_ ............ A-2*' A-8
H + H2 -> H- + H 2 ...........H + He -> H- + He _ .......... A-10*
H + Li -> H- + Li' ........... A-16*
H + H- -> H- + H ............ A-20
Electron Capture by H + ........... A-22
H + + H -> H + H' ........... A-22"
H + + H 2 -> H ............. A-28
H* 4. H 2 -> H- . ............ A-30H+ + He -> H + He + . ........ A-32"H + + He -> H- _ He 2° . ....... A-38
H . + Li -> H + Li _ .......... ._-40"
H' + H- -> H- + H-_ ......... A-44
H + + H- -> 2H ........... A-46
H+ + He' -> ,:,(He2' Total) ..... A-48"H+ + He + -.> H + He21 ........ A-54"
O Electron Capture by H2 + .......... A-58
H2 + + H -> H 2 + }'tt. . ......... A-58H2 _' + H2 _> H2 ............. A-58
H2 + + He -> H2 + He' . ......... A-58
H2+(,,) + H2 -> H2 ............ A-60
Electron Capture by He + .......... A-62
He + + H -> He + H _ . ...... A-62"
He' + H- -> He + H ....... A-86
He' + H 2 -> Fie ........ A- 68He' + He -> He 4 He t ...... A-70*
He' + Li -> He + Li t .... A-76"
He + + He' -> He + He 2' ..... A-86"
Electron Capture by He 2+ .......... A-84
He 2_ + He' -> He' + He2'(Partial & Total) A-84He 2+ + H- -> He _ + H ..... A-86He 2+ + H -> He' + I-I_ . . A-88"
He 2' + Hz -> He' .... A-94
t-te 2' + H2 -> }le ..... A-96He _'! + He -> He_ + He + . A-98"
O He2' 4- He --> He + He 2-_ . A-].04*He2"- + Li _-> He_ + Li' , . A-]_10*He 24 + Li -> Fie 4- I_,i2' ..... A-].I4*
J
A-2
Electron Capture Cross Sections for
H + H -> H" + H +
Energy Velocity Cross Section
(eV/amU) (cm/s) (cm 2)
2,0E+03 6.21E+07 1.56E-18
4.0E+03 8.79E+07 3.64E-18
7,0E+03 ].16E+08 7.63E-18
1.0E+04 1.39E+08 1.]8E-17
1.6E+04 1.76E+08 1.63E-17
2.0E+04 1.96E+08 1.55E-17
3.1E+04 2.45E+08 9.98E-18
4.0E+04 2.78E+08 5.58E-18
7,0E+04 3.68E+08 1.48E-18
7.3E+04 3.75E+08 1.37E-18
References: 33, 34, 396
Accuracyi E < 8x103 eV/amu - 50%; E > 8x103 eV/amu - 20%
Note: For energies less than 8xl03 eV/amu large discrepancies exist between the data.
For a Chebyshev fit of the abo9 - cross sections it is necessary to use the following parameters.
Eml n = 2.0E+03 eV/amu, Ema x = 7.3E+04 eV/amu
C hebyshev Fitting Parameters for Cross Sections @
AO AI A2 A3 A4 A5 A6 A7 A8
-'79.9637 .00368622 -1.08628 -.302134 .0745111 .148356 -.0426883 .0535533 -.0289283
The fit represents the above cross sections with an rms deviation of 1.0%.
The maximum deviation is 2.0% at 2.0E+04 eV/amu.
See appendix for Chebyshev f_t details.
A-3
H + H-.'> I-I- + H+
c..-,. En rgyCross .JL.ot.ior-1vs. e
'lO-;S ; , -T--___'[ , i , i , rT_
m
_F"
• EU,._i \
0
0
0 - RecomrnendedL_U ....... Data
....... Chebyst_ev Fit
10-1B ] __J__, , , , ,,J .... J_ L.... LL_L_L_J_--
Erlergy (eV/4::Jm u)
A-4
[]lectron Capture Rate Coofficle.t.s for 0
II + II -> I,I- + II 4
Maxwell Jan - Maxwelllan Rat.e Coe£flcJents (cm3/s)
li
Temp. Equal H Temp. (eV)
(eV) Temp, I000. 2000, 5000, I0000. 12000, 15000, 20000.
i 0E+02 ] 96E-14 7,56E-II 2 82E-I0 ] 01E-09 I_62E-09 1,70E-09 1.72E-09 1,65E-09
2 0E+02 2 57E-12 9.22E-II 3 06E-10 ] 03E-09 ].63E-09 1.70E-09 ].72E-09 1.65E-09
0E+02 3 36E-II 1 29E-10 3 56E-I0 1 07E-09 1.64E-09 1,71E-09 1.72E-09 1.64E-09
7 0E+02 ] 29E-I0 ] 90E-10 4 32E-10 1 13E-09 1,65E-09 I./IE-09 1.72E-09 1.63E-09
1 0E+03 2 58E-I0 2 58E-I0 5 10E-10 I 18E-09 1.66E-09 1.72E-09 1 72F-0q 1 63E-09
2 0E+03 7 64E-10 5 1OE-10 7 64E,-]0 ] 34E-09 1.70E-09 Io72E-09 1 71E-09 1 60E-09
4 OE+03 1 45E-.09 9 91E.-10 ] ]8E-09 1 55E-09 1.72E-09 1,72E-09 1 67E-09 1 55E-09
7 0E+03 I 72E-09 I 46E-09 1 55E-09 1 70E-09 1,71E-09 ].67E-09 ] 60E-09 1 47E-09
1 0E+04 1 65E-09 I 66E-09 1 70E-09 1,72E-09 1.65E-09 1.60E-09 1 52E-09 1 38E-09
2 0E+04 ] 14E-09' I 63E-09 ] 60E-09 1.52E-09 ].38E-09 1,33E-09 i 26E-09 _ ] 14E,-09'
Acc_iracyz * - Possible Error G:eater Than 10%
•* - Possible Error Greater Than 100%
Note: For Chebyshev fits of the above rate coefficients it is necessary to use the following parameters. _&
Eml n = 1.0E+02 eV, Ema x = 2.0E+04 eV
Chebyshev Fitting Parameters for Rate Coefficients
H
Temp.
(eV) AO Al A2 A3 A4 A5 A6
i000. -4 34136E+01 1.77058E.00 -2 19086E-02 -2.54539E-01 -5.12704E-02 1.82644E-02 9°]2815E-03
2000. -4 22]41E+01 ].02952E+00 3 42057E-02 -1,66830E-01 -5,60021E-02 5,86271E-03 8 15346E-03
5000, -4 09368E+01 2.82198E-01 -5 96305E-03 -7,32604E-02 .3.54191E'02 -5.05727E-03 2 39134E-03
I0000 -4 04860E+01 -3.08846E-02 -5 68396E-02 -4.34280E-02 -1.90470E-02 -4.61028E-03 -i 80695E-05
12000. -4 04639E+01 -7.77066E-02 -6 68905E-02 -3.99404E-02 -1,61322E-02 -3.99466E-03 -2 04042E-04
15000. -.4 04949E+01 -I.18325E-01 -7 60484E-02 -3.69771E-02 --1,33535E-02 -3.24675E-03 -2 69603E-04
20000. --4 06294E+01 -1.47825E-01 -8 23614E-02 -3.42640E-02 -].08621E-,02 -2.44826E-03 -2 60694E-04
Equal Temp. -4 70326E+01 4.89621E+00 .-2 27782E400 4,67042E-01 -2.66936E-01 1.22082E-01 -I 65425E-02
See appendJ× for Chebyshev fit details.
q
A-5
®
H + H--> bl- -t-t--t '_ ,
Moxwelian - Maxwelion
10-_, I I I_ _ _ _ r"F_' F--T--r-Fq'TT'[' I V _ T_I I i 1 L
H Temp.
- (eV)
A --I000,
x -- 2000.• i --_ , ml
, -__'L'_: v - _ooo,
-_,o-_- __/<_, : _--,oooo,O m -E _ ._
cp - @ --12000,.+_
C - .,_//
,9 ./ff" m --15000,
_- []--20000,0 "
g .///
o i_-I - DcltoLY: .-
-///
- - ..... Chebyshev Fit
EqLiOITenlp,
,/10- - _ /i , , , ,,, I ._L__L_L.LZ_Z_LJ_L ...... L___L_I__Z_LL.LJ_
I(# 103 104 1()_'t1 Ternf-_. (eV)
Q
A-6
Electron Capture Rate Coefflolents for 0
II + II -> II- 4-H "1
Beam - Maxwel]lan Rate CoetfleJents (cm3/s)
iI
Temp. 11 Energy (eV/amu)
(eV) i0000. 20000. 40000, 450[)0, 50000. 60000. 70000.
1,0E.100 1.63E-09'* 3 03E-09"* 1.55E-09"* 1.2LIE-09** 1.02E-09'* 7.26E-10'* 5 45E-I0'*
2.0E+00 1.63E-09' 3 03E-09" 1.55E-09"* I 24E-09'* 1.02E-09"* 7.26E-I0"* 5 45E-I0'*
4.0E400 1.63E-09' 3 02E-09" 1.55E-09"* 1 24E-09'* 1.02E-09"* 7.26E-I0'* 5 45E-I0'*
7.0E+O0 1.63E-09' 3 02E-09' ].55E-09"* ] 24E-09'* 1.02E-69'* 7.26E-I0 *_ 5 455,_i0 **
I.OE+01 1.63E-09' 3 01E-09* I,_5E-09'* 1 24E-09'* ].02E-09"* 7.26E-I0"* 5 43E-10'*
2.0E+01 ].63E-09' 300E-09* 1.54E-09"* ] 24E-09'* 1.02E-09"* 7.26E-IU** 5 27E-I0'*
4.0E+OI 1.63E-09' 2 98E-09" 1,54E-09'* 1 25E-09"* 1.02E-09"* 7.27E-19'* 4.94E-I0'*
7.0E+01 1.63E-09" 2 96E-09" 1,54E-09'* ] 25E-09'* ] 02E-09"* 7.28E-I0'* 4.62E-I0'*
1.0E+02 1.64E-O9" 2 94E-09" 1.54h-09"* 1 25E-09'* 1 03E-09'* 7.29E-I0"* 4 42E-I0'*
2 0E+02 1.66E-09' 2 89E-09" 1.54E-09'* i 25E-09'* i 03E-09'* 7.29E-I0'* 4 10E-10**
4 0E+02 1.71E-09' 2 81E-09" 1.55E-09' 1 26E-09'* 1 04E-09'* 7.19E-I0'* 3 91E-10**
7 0E+02 ].76E-09" 2 71E-09" I 55E-09" i 27E-09'* 1 05E-09"* 7.03E-10'* 3 B6E-10**
1 0E403 1.80E-09 _ 2 62E-09' 1 54E-09' 1 28E-09' 1 05E-09'* 6.9_E-10'* 3 88E-10'*
20E+03 1.88E-09' 2 40E-09" 1 52E-09' ] 27E-09' l 05E-09'* 6,86E-I0'* 4 08E-10 _*
4 0E+03 1.90E-09 2 ]2E-09' 1 42E-09' 1 21E-09' 1 02E-09'* 6.97E-10'* 4 5lE-lO**
7 0E+03 1.86E-09' i 85E-09" i 28E-09' i 12E-09' 9.66E-I0' 7.01E-10** 4,92E-I0'*
10E+04 1.78E-09' 1 67E-09" 1 ]6E-09' 1 03E-09' 9.10E-10* 6.90E-I0'* 5,1lE-lO**
2 0E+04 1.4BE-09* 1 29E-09" 9 21E,-IO * 8 39E-I0' 7.61E-I0'* 6.22E-I0'* 5.03E-I0'*
Accuracyz * - Possible Error Greater Than 10%
• * - Possible Error Greater Than 100%
Note: For Chebyshev fits of the above rate coefficients it is necessary to use th_ following parameters.
Eml n = 1.0E+00 eV, Ema × = 2.0E+04 eV
_shev Fitting Parameters for Rate Coefficients
II
Energy
(eV/amu) AO AI A2 A3 A4 A5 A6
i0000. -4 04105E+01 2.91340E-02 -2 63688E-02 -6.02938E,-02 -4 80367E-02 -1.89721E-02 -1.81756E-03
20000. -3 96573E+01 -3.51288E-01 -i 95694E-01 -7.65178E-02 -1 76176E-02 6 760241!',-05 B.20202E-04
40000. -4 07630E+01 -].72032E-01 -] 30927E-01 -8.]2602E-02 -3 ?0555E-02 -8 68416E-03 3.26863E-03
45000. -4 ]i299E+01 -I.]6178E-01 -I 03253F-01 -7.22628E-02 -3 62733E-02 -I 02_39E-02 ].83555E-03
50000. -4 14810E+01 -7.82977E-02 -7 66264E-02 -5,87240E-02 -3 17702E-02 -] 03177E-02 -4.83902E--04
60000. -4 21440E+01 -5.01687E-02 -2 65441E-02 -1.l]314E-02 -8 49686E-03 -i 30422E-02 -1.43358E~02
70000. -4 28827E+01 -7.9016{)E.-02 ] 09848E-01 8.45395E-02 -3 13642E-02 -4 50109E--02 -6.86268E-03
See appenclix l_ot Cbebyshev fit deta]Is.
0
A-7
®
H -t-ld->H- + H+
Beclm - Moxwelliow_ ,i
A-8
Electron Capture Cross Sections for
I1 + 1-12 -> H-
Energy Velocity CLose Seot ion
(eV/ainu ) (om/s) (cm 2 )
4.0E+01 8.79E+06 1.05E-18
7.0E+01 1.16E+07 1,78E-18
1.0E+02 1.39E+07 2.52E-18
1.4E+02 1.64E+07 3.08E-18
2.0E+02 1.96E+07 2.74E-18
4.0E+02 2.78E+07 1.70E-18
7.0E+02 3.68E+07 1,24E-18
1.0E+03 4.39E+07 1.31E-18
2.0E+03 6,21E+07 5.28E-18
4.0E+03 8.79E+07 1.46E-17
7,0E+03 1.16E+08 2.18E-17
I.OE+04 1,39E+08 2.32E-17
2.0E+04 1.96E+08 1.91E.-17
4.0E+04 2.78E+08 9.93E-18
7.0E+04 3.68E+08 4.07E-18
1.0E+05 4.39E+08 1.68E-18
2.0E+05 6.21E+08 1.72E-19
4.0E+05 8.78E+08 6.12E-21
4.6E+05 9.42E+08 2.97E.-21
References_ 26, 27, 28, 29, 3_. 31, 32, 33, 35, 396
Acourao_ 25%
N ote._____The quoted results are believed to be accurate to within 25%, although the data presented
in some of the references may deviate by 50-60%.
For a Chebyshev fit of the above cross sections it Is necessary to use the following parameters.
Emi n = 4,0E+01 eV/amu, Ema x = 4.6E+05 eV/amu
Chebyshev FittinH Parameters for Cross Seotion_
AO A1 A2 A3 A4 A5 A6 A7 A8
-82.8333 -1.65457 -2.60408 --1.53870 -.368649 .413620 -.165702 -.127116 .256041
The fit represents the above cross sections with an rms deviation of 9,5%.
The maximum deviation is 26.2% at 1.0E+03 eV/amu.
See appendix for Chebyshev Fit details.
A ¸'o 9
H + H_->H-
Cross Section vs. Energy
-1610 -" , 1 i"111111'" I I-TTmll _ I i-riilll i"'l"i IllITl i I I1'11"_
, /'_'*"""'_',
10-,__ '_ _
\i _// / _ --
E 10-' -
i0 - --
(1,) -- --
C/)
0iv
U
10-2_- Recommended
_ ----Data
.... _. Chebyshev F tr_-2 __.L_Z_UJIiii _ L_LU_ZUL__L_L_Lu_L_-L1d
lo' lo_ lo_ _o_ lo_ lo_Energ y (eV./1:]rrlL0
0
A-lO
Elec:tron Capture Cross Se_tlons for A
H + lie -> H- + lie +
Energy Velocity Cross Section
(eV/amu) (cm/s) (cm 2)
7.7E+02 3.85E+07 1.47E-19
1.0E+03 4.39E+07 2.]5E-19
2.0E+03 6.21E+07 5.80E-19
3.0E+D3 7.,61E+07 1.04E-18
4.0E4.03 8.79E+07 1.61E-18
5.0E+03 9.82E+07 2.23E-18
6.0E+03 1.08E+0B 2,88E-18
7.0E+03 I.]6E+08 3.46E-18
9 0E+03 1.32E+08 4.34E-18
i 0E+04 1.39E+08 4.83E-18
2 0E+04 ].96E+08 6.51E-18
3 0E+04 2.41E+08 6.06E-18
4 0E+04 2.78E+08 5.28E-18
7 0E+04 3.68E408 2,92E-18
].0E+D5 4.39E+08 1.46E-18
2.0E+05 6.21E+08 2.33E-19
4.0E+05 8.78E+08 2,47E-20
7.0E+05 ].16E+09 1.87E-21
7_6E405 1.21E+09 1.16E-21
35, 268, 269, 270 O29,References _ 26, 27,
Aceuraoyl 30%
For a Chebyshev fit of the above cross sections _t is necessary to use the following parameters.
Eml n = 7.7E+02 eV/amu, Ema x = 7.6E+05 eV/amu
Chebyshev Fitting Parameters for Cross Sections
AO A1 A2 A3 A4 A5 A6 A7 A8
-85.52]5 -1.87685 -3.06302 -.492323 .117220 -.0269941 -.0479364 -.0315786 -.0439288
The fit represents tile above cross sections with an rms deviation of ].8%.
The maximum deviation is 2.9% at ?.0E+05 eV/amu.
See appendix for Chebyshev fit details.
?
A-'I1
H + He ->H- + He+
Cectlon vs EnergyCross J °
10-2 ..... t, I f iJ_LIII._L__LI Illlll I 1 I I JJ
1d 10_I 1,04 10s 106Energy (eV/_:_rnu)
e
A-_|. 2.
Electron Capture Rate Coefficients for O
H + He -> H- + Fie+
Maxwellian - Maxwellian Rate Coefficients (cm3/s)
H
Temp. Equal He Temp. (eV)
(eV) Temp. i. i00. 500. i000. 5000. i0000. 20000.
7 0E+01 3.79E-15 4.61E-16 7 47E-15 4.58E-13 2.43E-12 5 54E-II ].74E-I0 4.26E-I0
I 0E+02 5.02E-]4 1,13E-14 5.02E-14 7.92Ei]3 3.11E-12 5 78E-II 1.77E-I0 4.28E-10
2 0E+02 1.14E-12 5,09E-13 7.92E-13 2.54E-12 5.86E-12 6 60E-li 1.87E-I0 4.37E-]0
4 0E+0_ 7.50E-12 4.40E-12 5.11E-12 8.38E-12 1.34E-II 8 33E-]I 2.08E'i0 4.55E-I0
7 0E+02 2.48E-II 1.57E-II 1.69E-II 2,20E-II 2,93E-II 1 lIE-10 2.40E-I0 4.82E-I0
] 0E+03 5.00E-II 3.24E-ii 3.40E-II 4 0BE-li 5.00E-II "i 41E-]0 2.71E-I0 5.08E-]0
2 0E+03 1.67E-I0 1.16E-10 I.]9E-10 1 29E-I0 1.41E-10 2 45E-I0 3.72E-I0 5.86E--I0
4,0E+03 4.19E-I0 3.22E-]0 3.25E-I0 3 35E-i0 3.47E-I0 4.42E-I0 5.48E-I0 7.17E-I0
7.0E+03 7.02E-I0 5.86E-I0 5.88E-I0 5 96E-]0 6.05E-10 6.72E-I0 7.44E-I0 8.55E-I0
],0E+04 _ 8.73E-I0 7.70E-I0 7.71E-]0 7 76E-I0 7,82E-I0 8.26E-I0 8.73E-I0 9,,43E-I0
2.0E+04 1.04E-09 1.02E-09 1.02E-09 i 02E-09 ].02}5-09 1.02E-09 1,03E-09 1.04E-09
Notes: For Chebyshev fits of the above rate coefficients it is necessary to use the fullowing parameters.
Emi n = 7.0E+01 eV, Ema x = 2.0E+04 eV
Chebyshev Fitting Parameters for Rate Coefficients i
He
Temp.
(eV) AO Al A2 A3 A4 A5 A6
i. -5.10941E+01 6.54972E+00 -2.07764E+00 6.21336E-01 -3.71355E-01 1.34135E-01 -1 51404E-02
i00. -5.00589E+01 5.62889E+00 -1.42974E+00 2.34011E-01 -1.74762E-01 5.]7776E-02 1.40144E-02
500. -4.81708E+01 4.05303E+00 14.72178E-01 -2.11436E-01 -1.16459E-02 ].30366E-02 9.51225E-03
1000. -4.71671E+01 3.28859E+00 -1.32390E-01 -2.90109E-01 -I.07340E-02 2.14696E-02 2.38292E-03
5000. -4.45966E+01 1.61569E+00 ].93393E-01 '-1.64393E-01 -5.91438E-02 7.61287E-03 6.54831E-03
i0000. -4.34391E+01 9.76929E-01 1.85422E-01 -8.18919E-02 -5.25533E-02 -5.26730E-03 3.99780E-03
20000. -4.24393E+01 4.84530E-01 1.19557E-01 -3.07242E-02 -3.26702E-02 -9.20869E-03 ].64244E-04
Equal Temp. -4.97998E+01 5.73848E+00 -1.74839E+00 4.04712E-01 -2.79431E-01 1.17900E-01 -2.07435E-02
See appendix for Chebyshev fit details.
A-13q
e
H + He->H- + He*
Me×weliGn- Maxwe ian
' A-14
Electron Capture Rate Coefficients for
lle + H -> H- + lie.
, , L
Beam - Maxwei]ian Rate Coefficients (cm3/s)
H
Temp. He_ Energy (eV/ainu) '
(eV) i0000. 20000. 40000. 70000. i00000, 200000. 500000.
1 0E+00 6.69E-i0 1.28E-09 1.46E-09 1 07E-09 6 41E-10 1.45E-I0 8.66E-12'*
2 0E+00 6.68E-I0 1.27E-09 1.46E-09 i 07E-09 6 40Ell0 ].45E-I0 8.67E-12'*
4 0E+00 6.67E-I0 ].27E-09 1.46E-09 i 07E-09 6 40E-10 ].45E-I0 8.67E-12'*
7 0E+00 6.66E-]0 1.27E-09 1.46E-09 ] 07E-09 6 39E-I0 1.44E-I0 8.67E-12'*
] 0E+01 6.65E-I0 1.27E-09 ].46E-09 i 07E-09 6 39E-I0 1.44E-I0 8.67E-12"*
2 0E+01 6.64E-I0 1.27E-09 1.46E-09 ] 06E-09 6 38E-]0 1.44E-]0 8.67E-12'*
4 0E+01 6 63E-I0 1.26E-09 1.45E-09 i 06E-09 6 37E-I0 1.44E-I0 8.68E-12'*
7.0E+01 6 63E-10 ].26E-09 ].45E-09 1 06E-09 6 36E-]0 1.44E-I0 8.68E-12 *_
1.0E+02 6 64E-I0 1.25E-09 1.44E-09 1 05E-09 6 35E-I0 ].44E'I0 8.69E-12'*
2 0E+02 6 69E-I0 1.24E-09 1.43E-09 l.O5E-09 6.33E-I0 1.44E-I0 8.72E-12'*
4 0E+02 6 82E-I0 1.24E-09 1.42E-09 1.04E-09 6.3]E-I0 1.44E-I0 8.77E-12'
7 0E+02 7 04E-J0 ].23E-09 1.40E-09 1.03E-09 6.30E-I0 1.44E-10 8.85E-12'
i 0E+03 7 25E-I0 ].22E-09 1.39E-09 1.02E-09 6.30E-I0 1.45E-I0 8.93E-12'
2 0E+03 7 87E-I0 1.21E-09 1.34E-09 9.96E-I0 6.29E-I0 1.47E-]0 9.20E-12'
4 0E+03 8 79E-I0 I.]8E-09 1.27E-09 9.60E-I0 6.26E-I0 1.52E-]0 9.70E-12'
7 0E+03 9 65E-10 ].15E-09 1.18E-09 9.11E-10 6.18E-!0 1.60E-10 1.04E-II*
i 0E+04 1 01E-09 Io]2E-09 ].]IE-09 8.67E-I0 6.07E-I0 1.68E-I0 1.]0E-II*
2 0E+04 i 05E-09 1.04E-09 9.50E-I0 7.54E-I0 5,63E-I0 i.90E,]0 1.34E-II*
Accuracy: * - Possible Error Greater Than 10%
• * - Possible Error Greater Than 100%
Notes: For Chebyshev fits of the above rate coefficients it is necessary to use the following parameters.
Emi n = 1.0E+O0 eV, Ema x = 2.0E+04 eV
Chebyshev Fitting Parameters for Rate Coefficients
He
Energy
(eV/amu) AO AI A2 A3 A4 A5 A6
]0000. -4.19935E+01 2.19891E-01 1.24242E-01 2 58739E-02 -] 96928E-02 -2.10662E-02 -9.41303E,03
20000. -4.10635E+01 -7.94718E-02 -3.94031E-02 -i 87660E'02 -9 93076E-03 -4.65478E-03 -1.66689E-03
40000, -4.08823E+01-].64742E-01-9.93840E-02 -4 75948E-02 -] 79398E-02 -4.36181E-03 4.08769E-04
70000. -4.14695E+01 -1.30558E-01 -7.6]140E-02 -3 80809E-02 -1 75717E-02-6.97521E-03 -1.71873E-03
i00000. -4.23878E+01 -4.00395E-02 -2.39094E-02 -i 67316E-02 -i 22134E-02 -7_I1472E-03 -2.89733E-03
200000, -4.52157E+01 9.]7644E-02 7.16076E-02 4 20628E-02 1 78905E-02 4.6230]E-03 -6.38872E-04
500000. -5.07701E+0] ].52640E-01 1,03844E-01 5 55224E-02 2 32810E-02 7.67676E-03 2.39728E-03
See appendix for Chebyshev fit details.
0
A-15
He + H-->bl + He*
Beam - Maxwelliclrs
_----T--1--Frll_q _ r'T-FrT]_l _ 1 _rll _ rl_,,_l _ _ _LL
- ' - He Energy
_ - (eV/orn u)L.
z_ -- 10000. ,
=--- x -- 20000.
10__ __._..-" _Jg:><_ -- _ --40000,_. ......
' t_ --
-.# : - _ - 7oooo.E !_
o • -- I00000,
r- E m --200000.(b 10'o 10- -LE- - [] 500000.(I.)O
U - Recommended(D+-' _DatarD
rr
10-1 ,.- -"-'"I" - Chebyshev FitII _.
10 -1; __ I I J lJiJl[ _i I _ltIH]J /--4 I lJ_lll I I I IJu]l _L_L_LJ.ZL_
lo° ld ld lo_ lo_ ld• H Temp. (eV)
A-16
Electron CaptUre Cross Sections for
H + Li -> [I- + Li +
Energy Velocity Cross Seotlon
(eV/ainu) (cre/s) (cre2)
3,0E+05 7.61E+08 1.71E-18
4.0E+05 8.78E+08 8.97E-19
5.0E+05 9.82E+08 6,99E-19
6.0E+05 1,08E+09 6.13E-19
7.0E+05 ].]6E+09 5.48E-19
8.0E+05 1.24E+09 4.93E-19
9.0E+05 1.32E+09 4,49E-19
1.0E+06 1.39E+09 4.15E-19
References_ 268
Accuracy: 30%
For a Chebyshev fit of the above cross sections it is necessary to use tile follow_ng parameters.
Emi n = 3,0E+05 eV/amu, Ema x = 1.0E+06 ev/amu
Chebyshev Fitting Parameters for Cross Secti9ns
AO A1 A2 A3 A4 A5 A6 A7 A8
-83.5i67 -;651028 .130590 -.0639887 .0130205 6.98064E-03 -3.26857E-03 5.16789E-05 i
The fit represents the above cross sections with an rms deviation of 0.0%.
The maximum deviation is 0.0%.
See appendi x for Chebyshev fit details.
A-.17
H + L,i--_l-I- '"_- Li +
Ct-ass%ectionvso IEr-_ergyt-
I018,0 j ] r 1.........1--7--I.... r---r-- .x
16,0 -
14-,0 -
f-,-..,
0 _E0"----'12.0 - -
0
C)q9
O"3cn 10,0 -U30 Reconlmerlded
CD ..... Data
8.0 -
........ Chebyshev Fit
"N
%.,,
6.0 - ",,,,. -",,.,
"_,
\.,\,,,
, "_x_.
4..0 J t L __L_L___ ___L___L_.....
•ld lo<_Enerl:jy (e.,VA3r-13u)
, A- 1 _.1
El(_c,[: l'oLi Captu['e Rate Coef['taiellto for , 0Gi + li -;' II- ,t. I.,i 't
Beam -_ Maxwelltan Rate Coe£fletents (ClTi3/fi)
II
'['emp. Li Energy (eV/ainu)
(eV) 300000, 350000. 400000. 450000. 500000. 550000. 500000,
10E+O0 6,,t9_-10'* 9 94E-10'* 7 89[',-10'* 7 33E-10'* 6,87H-10"* 6,"/2[",-10'* 6,59[",-10'*
2 0E+00 6,48[';-i0'* 9 94E-I0'* 7 89E-10'* 7 33E-i0'* ' 6.8-IE-10** 6,72E-.10'* 6,59E-i0'*
4 0E+00 6,47E-I0'* 9 94E-ID** 'l 89E-10** 7 33P,-I0'* 6.87E-I0'* 6.72E-10'* 6.59E-I0'*
7 OB+00 6.46E-I0'* 9 94E-I0'* 7 90E-10** 7 33E-I0'* 6,87_:-i0'* 6,72E-I0'* 6.5('E-I0'*
1 0E-I01 6,45E-I0'* 9 94E-i0'* 7 90[':-10'* 7 33L']-I0'* 6,87E-I0'* 6,72E-I0'* 6,59E-]0'*
2 0E+01 6,43E-I0"* 9 94E-I0'* 7 91E-10** 7 33E-I0'* 6,87E-I0 _* 6,72E-]D** 6,59E-I0'*
4 0E+01 6,40[':-10'* 9 95E-I0'* 7 93E-I0'* 7 33E-I0'* 6,88E-I0'* 6,72['I-10'* 6,59E-I0'*
7 0E+01 6 37E-I0'* 9 95E-I0'* 7 95E-I0'* 7,33E-I0'* 6,88E-I0'* 6,72E-I0'* 6,59E-I0'*
1 0[':+02 6 34E-I0'* 9 95E-I0'* 7 96E-I0'* 7,33E-i0'* 6,89E-I0'* 6,72E-i0'* 6,59E-I0'*
2 0E+02 6 28E-10'* 9 95['3-10'* 7 99E-I0'* 7,33_,-i0'* 6,89E-i0'* 6,72E-I0'* 6.59E-I0'*
4.0E+02 6 19E-10** 9,96E-I0'* 8,05E-I0'* 7 33E-I0'* 6 91E-10** 6,721-";-10'* 6,59[':-10'*
7.0E+02 6 09E-10** 9 87E-I0'* 8,1DE-10** 7 33E'I0'* 6 92E-I0'* 6 72E-I0'* 6_59E-I0'*
I.OE+03 6 02E-lO** 9 70E-I0'* 8,15E-10** 7 34['.'-10'* 6 93E.-I0'* 6 72E-I0'* 6,59E.'10**
2,0E+03 5 84E-.I0'* 9 04E-10** 8.24E-I0'* 7 39E-I0'* 6 961;:'i0'* 6 741;:-i0'* 6,59E-i0'*
4.0E+03 5 62E-I0'* 8 tOE-10** 8,13E-I0'* 7 49E-I0'* 7 02E-10** 6 76E-I0'* 6,60E-I0'*
7.0E+03 5 43E-I0'* 7 33E-I0'* 7,7BE-10'* 7 49E-10'* 7 09E-10** 6 81E-10** 6,61E-i0'*
1.0E404 5,31[':-10'* 6 89E-I0'* 7,46E-I0'* 7 39E-I0'* 7 liE-10** 6 84E-'I0'* 6,63E-I0'* ig
2.0E+04 5,]1E-I0'* 6,17E-10'* 6.75E-I0'* 6 96E-10'* 6 92E-I0'* 6 77E-I0'* 6,55E-10'*
Accuracy_ * - Possible Error Greater Than 10%
• * - Possible Error Greater Than 100%
Notez Fok ChObyshev fits of the above Late coefficients it is necessary to use the followJn_j parameters,
Elnin = 1,0E+00 eV, Ema x = 2.0E+04 eV
c!lebyshev Fitting Parameters for }{ate Coefficients
Li
Energy
(eV/ainu) AO AI A2 A3 A4 A5 h6
300000. _4.24630E+01 -i 12797E-01 -4 "/3823E-02 -9 52319E-03 2 18237E-03 2,8809BE-03 1,39108E-03
350000. -4.16874E+01 -2 00135E-01 -i 31634E-01 -5 41437E-02 -i 93565E-.03 1,56830E-02 i 05923E-02
400000, -4,19480E+01 -3 48038E-02 -4 56039E-02 -3 81117E-02 -2 13775E-02 -6.73960E-03 1 93438E-03
450000. -4.20718E+01 -.4 96888E-03 -8 42094E-03 -i 19219E-02 -I 19411E-02 -8,70975E.-03 -4 48543E-03
500000. -4.21803E+01 1 24481E-02 3 32025E-03 -3 09575['3-03 -5 02533E-03 -4.35643E-03 -3 20289E-03
550000. -.4.22344E+01 5 60707E-03 3 46072E-03 4 86332E-04 -i 43623E.-03 -1.96514E-03 -I 82432E-.03
600000. -4,22797E+01 -3 0]170E-04 -3 84669E-04 -9 55080E-04 -1 27882E-03 -1.24680E-03 -I J61491!;-(}3
See appenc]jx for Chebyshev fit details.
0
A.-.I9
Li + H ->H- + I_i+
A.-20
Irl]uc_troll CiTtl.Jtlll'O Cl:'Ot-Ili ,tJeOtj(.,n£t for
I1 + II- -', I1- + II
Enet'gy Velclcity Creus ,3_c_tton
( eV/ainu ) ( c ill/i_l ) (tin 2 )
2,0E.I.00 ],9(iE.t.06 ] I'13E,.14
4,0I?I+00 :I, 70E.t-06 1 241!',-.1 4
7,OE+O0 3,60E+06 I ]5E-]4
], 0F,-t.01 4,39E.I.06 ]. 071_-i 4
2, OI_.i.()l 6,21 F,.i.O6 {I 97 E-.l5
4,OE+OI 0 79E+06 7 24E-15
7,0E+OI ] 16E+07 5,99E-] 5
9,9E+01 1 38E._07 5,27E-15
2 0E+02 ] 96E+07 4,20[..:-]5
4 0E4.02 2 78E.I.07 ' 3,19E-15
7 0E+02 3 68E+07 2,43E-.15
1 0_I+03 4 39E+07 1,90E-]5
2 0E+03 6.2]E+07 9,49E-]6
4 0 E-I,O3 8.79E+07 ' 3,29_-16
7 IE+03 1,17E+08 ],03E-]6
Referencesl 162, 27], 272, 281
Accuracy I 30%
IINote_____]For energies less than 40 eV the data were taken from the theoretical papers of Ref. 271
and 272.
["or a Chebyshev fit of the above cross sections lt is necessary to use the following parameterE].
Emi n = 2.0E+O0 eV/ainu, Ems x 7,1E+03 eV/ainu
Chebyshev FittiDc] Parameters for Cros.____S_______ct_!io_tLs
AO Ai A2 A3 A4 A5 A6 A7 A8
-67.0414 -2.13773-.748888 -.288550 -.136764 -.0116298 ,0247820 ,00770226 2,252]0E-04
The fit represents the _bove cross sections with an rms deviation of 0,3%.
The maximum deviation IE_ 0.7% at 4.0E+02 eV/anu.
See appendix for Chebyshev fit details.
, A~ 2;1.
Ii
H + H- > H- + H
._ ('_" _ i* __Cr-0ss _:_ec:tlcn vs_ F_net_gy
,1(_ 13___.... F--F]'-rTn'i F.........r--1--r-r zrrrl-----T--F]-l-rTrt ....... n---r-i-r-r]xr
10-,4 "_-O _. "--... _
E ""'--,, -(.) "'-... -
f"£_ .,,.
_+...j 'N. %,
(_) _,. --
(1) "\
tO \,_ ..
U)O f;_e co rr-im e 11d e d
U "l(h-15_. - ....... Data
I
- - ...... Chebysllev Fit
,}.(-;- I[ ....... L__._.L._LJ_IJI.]J____L.L..±_LLIJIL ..... _L___L_I_.L.LI_L _L
lo° ld lc:/ IcF ld'Energy (eV/%ln-'lu)
0
A_22
ahl'Lluc_tron CaLJtt.lre CroslJ _eoLlotul for V
, lr l' ,i ii -> it ._ lr I
F:I_oL'gy VolooJLy Cross _;ooL ion
( eV/allltl ) (om/_l) (sm 2 )
I, 2 _:"01 4,79 F,.tO5 4,961_-15
2,0 F_-01 6,21 _:,F()5 4,701,:-15
4, Of-01 8,79E.05 4,451::-15
7,Of-OI 1,16[.:4-06 4,24E-15
J,OE+OO I,391_+06 4,IOF,-I5
2,0E+OO i, 961,_.06 3,U3E-15
4,0E+O0 2,78E.t.06 3,50E-15
7,0_.I O0 3,6 O_,+06 3,33_-15
i, OE+O1 4,39 E-I.O6 3,17[_-15
2,0_].FOJ 6,21_:+06 2,93E-15
4,Of+OI [J,79E+06 2,70 F_-I5
7 ,Of+Oi I, 16_407 2,54E-15
I,OP..02 ].39E+07 2,44E-15
2,OF,.102 1,96E.07 2,22E-15
4.0E+02 2,78E+07 2,03F,-15
7,0 E'102 3,60 E+07 1,88E-I 5
I,0E+03 4,39E.07 1,71F,-15
2,0[,,'+03 6,21 F,+07 1,44FJ-I5
4,0E.03 8,79E+07 1,201_-15
7,0E+03 ] ,]6E+0O 9,42E-16
1,DE.04 J, 3gE+00 7,75E-16
2,Of+04 1,96 E+O8 4,45E-16
4.0E+04 2,78E+08 I,67E-I 6
7,0I_+04 3,6Of+OB 3,'17E-17
i,Of+05 4,39E+08 ] ,01E-17 A
2, OE+05 6.21E+0O 6,09E-19
4,0E+05 8,78E+08 i ,76E-20
6.3E+05 i,]0F,.09 i,35E-21
i, 2, 3, 4, 5, 6# 7, 8, 9o .10, 273, 395
_. II+ Energy! < 10 eV/amu, 10%1 10 eV/ems - ixl03 eV/amu0 15% I Ixl03 oV/amu - ixl05
oV/amuo 5%I ixlO 5 sV/ems - 6,25x105 eV/ems, 20%
tLq._ (1) Thls reaotlon has been measured by three dlffelent techniques! ], SLatis GasTarget, 2. Cross f]oatnB,3, Merged Beams,
(2) The maximum deviation of tile reoomlnended data from the data points In the referencescited la le_u than 45_.
(3) Newman In reforenc,e 9 found that when D atoms Were tile target the ureas ueotlon
deorsased 16% from that using Ii atoms at an energy of ,12 eV, AL high energies tileoros_ sections were Lifesame,
(4) ?he recent ref, 273 extends the measurements tlp to an energy of 7,5x106 eV/ainu.
Tile eroiis aeetlons are (a) 2,0X106 (_V/amu - 5.25xi0 "24 0.,2; (b) 3,5x106 eV/alnu -
2.14xi0 -25 sm2; (e) 5,0xk06 eV/amu - 3.1xi0 -26 sm2; (d) 7.5xi06 eV/amu - 4.10xi0 -2? em2.Quoted errors sre as great au 43%,
Per iiChebyllhev fit of tlm above cross sections it Is necessary to use the following parameters.
_mil,_ 1,2E-Ol eV/alnu, F.'inax= 6,3_.F05 eV/amu
eb__V l,'it;ttn¢.l l'arametc.rs for Cross Soc'Lions
AO Al A2 A3 A4 A5 A6 A7 AB
-72.6656 -5.49142 -3.42948 -1.90377 -,870009 -,198932 ,0[137431 ,121252 .08271[J2i
'Phe [lt represents tile above e/oss eootlons wlth am rms dee ratlon of 4,5%.
'l'he maximum deviation Is 13.5_ at ].0F,_05 eV/an,u, i
Boo apporldlx for Chebyshev fit details, V
A-23]
I-1+ -t- t1-> H -t- H+
Cross Section vs, Energ.y
'lC)-":---FTrlTIllF--T_'TTrI14"---FFIrII_ll _qTI1TII' 11 ll-iilll I llllulr--FTmTr_,.
Z
I'q
10-__C -- , -
,_o ::
(/) lac,_ 10-Or) z
O _" RecommendedLP _1 -------- Dcfle
10-Ig / Chebyshev Fit
10-_c_
L10 -21 _1!ljlll[ _L_J_DLLIlI!_1 1ll/l!!l J lllJJl, JJ_.,_]! lllllil I I 111!111, 1 IJ_LIIII
lo-' 1o0 lo' lo"_ 18 lo_ 18 lo_Energy (eV/a m u)
• ,
A-2a
_lectron Capture Rat_ Coefficients for O
H+ 4- I] -> II + H"
,Maxwsl]iaD - Maxwe]llar, Rate Coofficlents (cm3/s).,
H .F
Temp, Equal I1 [I'elnp (eV)
(eV) Temp. ], 10, 100, i000, 5000, I0000, 20000.
1,0E+00 8,10E-09 8,]0E-09 1.56E-08 3,63E-08 7.65E-08 9,74E-0B 8,95F]-08 6.84E-08
2,0E+00 1.06E-08 9.50E-09 1,61E-08 3,64E-0B 7,65E-08 9,_4E-0B B,95E-UB 6,84E-OB
4.0E+00 1,38_l-08 i.] 6_-08 1,71E-08 3,67E-08 _ 7,66E-08 9,74E-08 8,95l_-08 6,84E-08
7.0E+00 1,711']-08 1,3BE-08 I,B5E-08 3,71E-08 7,66E-08 9.74E-08 8.95E-08 6.84E-08
1,0E401 i. 96E-08 1,56E-08 1.96E-08 3,75E-08 7,67E-0B 9,74E-08 8,95E-08 6.84E-08
2,0E+01 2,56E-.08 2.00E'08 2.30E-08 3,87E-08 7.69E-08 9,74E-08 8.95E-08 6.84E-08
4.0E+01 3,33}_:-08 2,59E:08 2.79E-08 4,10E-08 7,73f,]-08 9,74E-08 8,94E-08 6.84E-08
7,0E+01 4,10E-08 3,18E-08 3,33E-08 4.40E-08 7 78E-08 9,74E-08 8.94E-08 6.83E-08
1,0E+02 4,66r']-08 3,63E-08 3.75E-08 4 66E-08 7 84E-08 9,74B-08 8.93E-0B 6.83E-08
2,0E+02 5 88E-08 4,,67E-08 4,74E-08 5 36E-08 0 00E-08 9,73E-08 8.91E-08 6.81E-08
4,0E+02 7 21B-08 5,BgE-08 5.93E-OB 6 30E-08 8 30E-08 9.72E-08 8.87E-08 6.77E-08
7,0E+02 8 30E-08 6.95E-08 6.98E-08 7 21E-08 8 65E-.08 9,70E-08 8.80E-08 6,72E-08
1 0E+03 8 92_-0B 7.65_-08 7.67E-08 7 84E-08 8 92Ei08 9,67E-08 8,73E-98 6.66[:;-08
20E+03 9 70E'08 8.92E-08 8.93E-08 9 00E-08 9 48E-08 9,54E-08 8,51E-08 6.49E-08
4 0E+03 9 36_:-08 9.70E-08 9,70E-08 9 71E-08 9 74E-08 9.17E-08 8.06E-08 6.16E-08
7 0E+03 8 06E-08 9.54E-08 9,54E-08 9 52E-08 9 36E-08 8,51E-0B 7.43E-08 5,70E-08
I 0E+04 6 84E-08 8.95E-08 8.95E-08 8 93E-.08 8 73E-08 7.84E-08 6.84E-08 5.30E-08
2 0E-F04 4 23E-OB 6.B4E-08 6,84E-08 6 B3E-08 6 66E-08 6.00E-08 5,30E-08 4,23E-08
Notesz For Chebyshev fits of the above rate coefficients lt is n_cessary to use the following parameters, W
_Imin = 1,0E+00 eV, Ema x = 2,0E+04 eV
C_heb_hev Fit_in 9 Parameters for Rate Coeffoicients
H
Temp.
(eV) AO AI A2 A3 A4 A5 A6
]. -3,44869E+01 ] 27901E+00 -2.75515E-01 -I 94518E-01 -4.14913E202 -1.79417E-02 -4,17985E-03
10, -3,41227E+01 9 80499E-01 -I.17702E-01 -2 36330E-01 -4.90489E-02 -5.73981E-03 -8,76848E-03
100. -3,34478E+01 5 02257E-01 -2,99001E-03 -i 75672E-01 -9.20126E-02 -1.06753E-02 3,21804E-03
1000. -3.25740E.01 4 69533E-02 -4.61309E-02 -8 81367E-02 -6.79803E-02 -2.9373BE-02 -4,422]0E-03
50U0. -3.24495E+01 -i 48073E-01 -].15160E-01 -7 59145E-02 -4.13891E-02 -].79143E-02 -5.55664E-03
]0000. -3.26521E+01 -i 74458E-01 -1.25225E--01 -7 36305E-02 -3,55149_I-02 -1.3826]E-02 -4.10388E-03
20000. -3,31787E40] -i 63538E-01 -1,]5089E'01 '6 54004E-02 -3.0]053E-02 -].10769E-02 -3,10752E-03
Equal Temp, -3.44313_H01 I 06711E+00 -5.19907B-01 -2 29247E-01 -6.98896E-02 -1.36578E,-02 4.42580E-04
See appendix for Chebyshev fit details.
A- 2,,5
H* + H ->H + H*
Moxwellion Moxwel ion(lC)
sO
X 11.0 / " 1 I ! t'11111", 'l I I l"rl'}l l ' 1 I i i"lllTr_-r i i ! ii111 i i i 1111
H Temp.
10.0 " (eV)
A --1.
9.0 I x -- I0.
8.0 X _ v -- 100.\
,.cD\. _ -- I000.
ME 7.0o • --5000 *
c 6.0q) • --10000.u
5.0 - [] --200000U
Recommended40
o DatarY
3.0
Chebyshev Fit
2.0
Equal Temp.
1.0
0.0 1 I I l.lllll 1 1 I 11111
lO0 lo' lO_ lO_ lo" 1o_H+ Temp. (eV)
O
A-26
Electron Capture Rate Coefficients for O
H + I-]4" -> H + H+
Beam - Maxwe]]ian Rate Coefficients (cm3/s)
R +
Ten ip. H Energy (eV/amu)
(eV) ]0000. 20000. 40000. 70000. i00000 200000. 500000.
1.0E+00 1.08E-07 8.72E-08 4.62E-08 i 38E-08 4.43E-09 3.78E-I0 4.79E-12'*
2.0E+00 ].07E-07 8,71E-08 4.62E-08 , ] 38E-08 4.43E-09 ].78E-I0 4.79E-12"*
4.0E+00 1.07E-07 8.70;']-08 4.6]E-08 1 38E-08 4.43E-09 3,77E-I0 4.79E-12 _*
7.0E+00 1,07E-07 8.69E-08 4.60E-08 ] 38E--08 4.43E-09 3.77E-I0 4.79E-12'*
1.0E+01 1 07E-07 8.68E-08 4.59E-08 1 38E-08 4.43E-09 3.77E-I0 4.79E-12'*
2.0E+ol i 07E-07 8.65E-08 4.57E-08 i 37E-08 4.43E-09 3.77E-I0 4.79E-]2'*
4,0E+01 ] 07E-07 8.61E-08 4,55E-08 1 3 ]-08 4.44E-09 3.76E-I0 4,80E-12'*
7.0E+O] 1 06E-07 8.57E-08 4.52E-08 1 37E-08 4.44E-09 3.76E-I0 4,80E-12'*
].0E+02 i 06E-07 8,53E-08 4.50E-08 1 37E-08 4.45E-09 3.76E-I0 4.81E-12'*,
2,0E+02 ] 05E-07 8.45E-08 4.45E-08 ] 37E-08 4.48E-09 3.77E-I0 4.83E-12"*
4,0E+02 1 04E-07 8.34E-08 4.39E-08 1.37E-08 4.55E-09 3.79E-I0 4.88E-12 **
7,0E+02 ] 03E-07 8.21E-08 4.34E-08 1.38E-08 4.67E'09 3.84E-10 4.96E-12'*
1.0E403 i 01E-07 8 ]0E-08 4 31E-08 1.40E-08 4.79E-09 3.89E-10 5.03E-12'*
2,0E+03 9 70E-08 7 79E-08 4 23E-08 1.46E-08 5.17E-09 4.1lE-]0 5.29E-12'*
4,0E+03 9.00E-08 7 24E-08 4 lIE-08 ].56E-08 5.91E-09 4.64E-I0 5.82E-12'
7,0E+03 8.16E-08 6 57E-08 3 92E-08 1.66E-08 6.90E-09 5.69E-]0 6.71E-12"
],0E+04 7.46E-08 6 03E-08 3 74E-08 1.72E-08 7.74E-09 7.01E-10 7.80E-12'
2.0E+04 5.70E-08 4 72E-08 3 20E-08 1.75E-08 9.46E-09 1.28E-09 ].36E-II* i
Accuracy: * Pos._ib]e El-[or Gl:tutter Than ]0%
•* - Possible Error Greater Than ].00%
Notes: For Chebyshev [:its of the above late coefficients it is necessary to use tile following parameters.
El.in = 1.0E4-00 eV, Ema x = 2.0E+04 eV
Cliebyshcv Fitting Parameters for Rate Coe[ficients
I!
El_e_gy
(eV/ainu) AO A1 A2 A3 A4 A5 A6
10000. -3 23588E+01-2.28428E-(]]-I 47539E-0] -7.73418E-02 -3.29()02E-02 '].0914]E-02 -2.93]58[',-03
20000. -3 27829[]+01-2.26775E-01-] 38750E-01-7.04432E-02-3.03096E-02-].00013E-02-].47228E-03
40000. _-3 39547E+0] -].36550E-0]-7 ]5786E-02-3.65682E-02 -2.10115E-02-].]]355E-02 -4.14062E-03
700(]0. -3 607361]401 1.0908411-01 7 352[:6F'-02 2.31264E-02 -7.74992E-03-1.38165E-02-8.49906E-03
]00000. -3 8]082E+01 3.09](]7E-01 ] 95996E-01 8.14408E-02 ].35787E-02-9.21346E-03-I.02081E-02
200000. -4 29608E+0] 3.96726[<-01 2 990001!:-0] 1.81207E-01 8.74182E-02 3.26701E-02 7.33350E-03
500000. -5 17564E+0] 3.37283E-01 2 43298E-0] ].48098E-01 7.72749F,-02 3.54105E-02 ].56884[']-02
See a[Jpendix for Chebyshev fit (]etai].s.
A-27
Q
bl + H+ ->H + H*
Beam -. Maxwellian
10-6' _ I 1 I lllII I " I l I IllII I 1 I 1 tllll I ' i 1 I'l'II'l'l I "'1' 1'1 11'1'1:I:
: - H Energy
- (eV/am u)
10-'_ _ _ -loooo.: - x -- 20000.
- v --40000.
,,p.. 10-8 .:.....e -: _ - 70000,rq / -
o • --100000.
r- m --200000.'_ 10-,+- - I_ -- 500000.qP0 E
U _ Recommended<1.)+-' io ----- Datao I0
-- .... Chebyshev Fit
10-,_1# 10' ld 10' ld lC)_
H* Temp. (eV:)
lP,,
k
A-28
'_lectron Capture Cross Sections for
' H+ + 112 -> H
Energy Velocfty Cross Section
(eV/ainu) (cm/s) (cre2)
2.6E+00 2%24E.06 1.81E-17
4.0E+00 2.78E+06 4.96E-]7
4.7E+00 3,.01E+06 5.68E-17
7.0E+00 3_68E+06 2.76E-17
].0E+01 4.39E+06 1.30E-17
1.4E+01 5.20E+06 1.01E-17
2.0E+01 6,21E+06 1.lIE-17
4.0E401 8.79E+06 1.68E-17
7.0E+OI ].16E+07 2.61E-17
1,0E+02 1.39E4.07 3.65E-17
2.0E+02 1.96E+07 6.96E-17
4.0E+02 2.78E+07 1.56E-16
7.0E+02 3.68E4-07 2.93E-]6
1.0E+03 4.39E+07 4.26E-16
2.0E+03 6,,21E+07 6.88E-16
4.0E+03 8.79E+07 9.33E-16
7.0E+03 1.16E+08 9.57E-16
1.0E+04 1.39E+08 8.66E-16
2.0E+04 1.96E+08 5.79E-16
4.0E+04 2.78E+08 2.50E-16
7.0E+04 3,68E+08 7.78E-17
1.0E+05 4.39E+08 2.91E-17
2.0E+05 6,21E+08 !.76E-18 _&
4.0E+05 8.78E+08 6.09E-20
7.0E+05 1.16E+09 3.64E-21
1.0E+06 1_39E+09 4.14E-22
2.0E+06 ].96E+09 1.68E-23
4.0E+06 2.77E+09 1.03E-24
References: 7, 27, 35, 36, 37, 38, 39, 40, 4], 42, 43, 44, 45, 47, 48, 62, 273, 395
Accuracy: E < i00 eV/amu - Unknown; E > 100 eV/amu - 10%
htO__ (l) The peak in the cross section at 4 eV comes from the data of reference 41. The
origin of this maximum is unknown.
(2) Recent data of reference 273 extend the energy range to 7.5xi06 eV/ainu. The cross
sections reported are: (a) 2.0x106 eV/amu - 7.00x10 -24 Cm2; (b) 3.5xi06 eV/amu -
4.85x10 -25 cm2; (c) 5.0x106 eV/amu - 6.47 xl0 -26 cm2;(d) 7.5×i06 eV/amu _ 6.30xi0-27
cm 2 , Errors of 10-15% are reported.
For a Chebyshev fit of the above cross sections it is necessary to use the following parameters.
Emi n = 2.6E+00 eV/amu, Ema x = 4.0E+06 eV/amu
Che_hp__hev Fittinq Parameters for cross sectlons
AO AI A2 A3 A4 A5 A6 A7 A8
-82.5164 -6.70755 -6.10977 -2.628]0 .709759 .639033 .]02980 _261240 -.263817
Tile tit represents the above cross sections with an rms deviation of ]5.5%.
The maximum deviation is 41.3% at 1.0E_0] eV/ainu.
See appendix for Chebyshev f_t details.
A-29
H+ + H; ->H
Cr-ossSection vs. Energ,v
""-IU'PS:__ I I,_,Ul , t_TrfT--"T--titlllll_iIlllUl t irJtlUl 1 I lllll:Jj
10-;_-
10-10__8__7-' "l: -" '
IN
E
c 10- _-0
(J
cn 10-2c-0")
O Rec:onlrrlended
10-2,= --Data
i
10_2:_ ...... Chebyshev Fit
10-_:_
ICi -2' I i ' I UL_L2_LU_U__ .. _,l,,,i -,..r
100 10' 102 103 10'_ 10s lC.)6 107Energy (eV/::l r-r-iu.)
,lD
A-30
Double Electron Capture Cross Sections for O
[I'_'+ 1-12- > H- + 2H4
Energy Velocity Cross Section
(eV/amu ) (cm/s) (cm 2 )
2.0E+02 1.96E+07 1.17E-20
4.0E+02 2 78E+07 2_22E-20
7.0E+02 3 68E+07 4.82E-20
1,0E+03 4 39E+07 8.94E-20
2.0E+03 6 21E+07 2.80E-19
4.0E+03 8 79E+07 8.64E-19
7.0E+03 ] 16E+08 2.09E-18
1.0E+04 i 39E+08 3.63E-18
2.0E+04 1 96E+08 8.89E-18
4.0E+04 2.78E+08 2.21E-18
7.0E+04 3.6_E+08 2.42E-19
1.0E+05 4.39E+08 3.15E-20 L
2.0E+05 6.21E+08 1.84E-22
4.0E+05 8.78E+08 7.22E-25
7.0E+05 1.16E+09 6.64E-27
1.0E+06 1.39E+09 2.70E-28
References: 35, 44, 50, 51, 52, 53, 54
Accuracy.. E < ixl04 eV/amu - 25%; ixl04 eV/amu < E < ixl05 eV/amu - 15%; E > ixl05 eV/amu - 40%
For a Chebyshev fit of the above cross sections it is necessary to use the following parameters.
Eml n = 2,0E+02 eV/amu, Ema x = 1.0E+06 eV/amu
Chebyshev Fittinq Parameters for Cross Sections
AO A1 A2 A3 A4 A5 A6 A7 A8
-95.8165 -7.17049 -.7.48288 -1.93034 761153 .556689 -.0542859 -.270184 -.0147551
The fit rppresents the above cross sections with an rms deviation of 9.4%,
The maximum deviation is 15,0% a t 1.0E+04 eV/amu.
See appendix for Chebyshev fit details.
A-31
0
H+ + t42 ->H- + 2H+
Cross Section vs. Energy
' -1710 _ l I I , I III, i' I , I ,llll' ..d'J'_l-T--l--,llll ' I " 'l
10-_9
_E 10-2
oC io-___ 10-_
_- 10_2.4 RecommendedU _Data
10 "_-Chebyshev Fit
10-2_ 1, :__--
10-2
1('/-2 I 1 l 11,1111 ,I 1 I ll. llll . I I 1 I11111 1 I I_LLLU./ _-,,,'
102 10_ 104 10s 10_Energy (eV/am u)
0
A-32
Electron Capture Cross Sections for OII+ .I.Hs -> II + He +
Energy Velocity Cross Section
( eV/al_u ) ( c Ii,/s ) ' (cre2)
9.9E+0i i.38E+07 4.28E-22
2.0E+02 1.96E+07 2.46E-21
4.0E+02 2.78E+07 1.77E'20
7.0E+02 3.68E+07 1.]2E-i9
i_ 0E+03 4.39E+07 4.73E-I 9
2.0E+03 6.21E+07 4.25E-I 8
4.0E+03 8.79E+07 i. 98E-I 7
7.0E+03 1.16E408 5.18E-17
1.0E+04 1.39E+08 8.52E-17
2.0E+04 1.96E+08 1.75E-]6
2,4E+04 2,15E+08 1,83E-16
4,0E+04 2,78E+08 1,41E-16
7,0E+04 3,68E¢08 6,98E-17
1,0E+05 4,39E+08 3,38E-17
2,0E+05 6,21E+08 3,95E-18
4.0E+05 8,78E+08 3,22E-19
7,0E+05 1,16E+09 3,07E-20
1,0E+06 1,39E+09 5,42E-21
2.0E+06 ].96E+09 1.42E-22
4.0E+06 2.77E+09 3.29E-24
7.0E+06 3,65E+09 1.62E-25 O1.0E+07 4.36E+09 2.09E-26
].lE+07 4.57E+09 ].02E-26
Referencesz 27, 35, 37, 40, 47, 49, 51, 82, 83, 84, 85, 86, 87, 88, 89, 272
Accuracy: E < 5x103 eV/amu - 40%; E > 5xi03 eV/amu -20%
For a Chebyshev fit of the above cross seetlons it is necessary to use the following parameters,
Emi n = 9.9E+01 eV/amu, Ema x = 1.lE+07 eV/amu
_shev Pittinq Parameters for Cross Sections
AO AI A2 A3 A4 A5 A6 A7 A8
-92.7819 -4.69073 '8.99666-.490484 .935276 -.0504853 -.0410750 -.0730136 .0189320
The fit represents the above cross sections with an rms deviatlon of 10.0%.
The maximum deviation Is 18.7% at 7.0E+02 eV/amu.
See appendix for Chebyshev fit details,
A-33
H+ + He -.->H --t- Pte+
Cr-ooo._,o.:;_cklon._ vs. Energy
10-16 . ,//-'",.., -_= =
10-17
0 "-" 1_1g_E -,,!.4
1(7'2co _--
(b 21lC)- -
g..)
o 10-22- _ RecommendedU -- Data
10-_.._...... Chebyshev Fi_
1C)-24
10-2_!10-2, I iJJJJul ii, J lJliJ
10' 10_ lr_ 104 10' 106 107 10aEnergy (eV/'!:lrnu>
0
l::_L[;c_tt'Oll CaL:_ttllO Rntc_ C,q,_c,[flc_iont;l,_ fur
II + ._ Ilo .-,', II + lie 't i
blaxwe.l]lall - Maxwell]an l(aLo CoeffJclent_ (um3/ei)
ii +
'/'emp, [':qua] llo 'l'emp, (eV)
(eV) Tellip, 50, ] 00, 500, 1000, 5000, 100(10, 20000,
7,0E+01 7,211!:-14 5 81_;-34 9,77E-14 i 60E-12 1,021!;-31 6 38[;-i0 2,6{llq-0!J 8,50E-09
3,0E+02 2,79E-;L3 I 85E-]3 2,79E-]3 2 7{1E--]2 ],39E-I] 6 73E-.10 2,74E-09 8,57E-09
2,0E-I02 4,],1E-12 2 23E-]2 2,78E-]2 ] 0BE-II 3,22E-11 7 95E-I0 2,95E-09 [1,8]E-09
4,0E-I.02 4,51E-1] 2 ,13E-II 2.6llE-11 5 24E-]I 9,92E-II I 07E-09 3,3'IE-09 9,28E-09
7,0E+02 2,27E-I0 { 29E-I0 1,36E-I0 1 94E-]0 2.82.E-I0 ] 53E-09 4,03E-09 9 99[';-09
],0E+03 5,60E-10 3 32E-10 3,42E-I0 4 33E-I0 5,60E.-i0 2 06E-09 4.73E-09 1 07E-08
2,0E+03 2,54E-09 1 64E-09 1.66E-09 ] 03E-09 2,06E-09 4 15[,:-09 7_]2E-09 1 29E.-08
4,0E+03 0,33E-09 5.94E-09 5,97E-09 6 21E-09 6052E-.09 8 93E-09 ],1[IE-08 I 66E_08
7,01;I03 ].62E-00 ],29E-08 1,29E-0[J 1,31E-08 1,34E-08 i 53E-08 1,74E-08 2 07E-08
1,0E.I-04 2,12E-08 .I,82E-08 ],82E-08 ].83E-08 ],[15E-08 ,] qBE-08 2,]2E-08 2 33E-08
2,0E+04 2,60E-08 2,55E-0{] 2,55E-08 2,55E-08 2,55E-08 2 57E-,08 2.59E-08 2 60E-08
Notesl |_'orChebyshev fits of tl,e above rate ooef[iclol]ts _t: is necessary to use the followillg pal:ameters,
Eliot n = 7,0E.t.OI eV, [':max = 2,0E.t.04 eV'
C_hev Fttttn_Paral.eter_ for Rate CoefficientsI.le
Temp,
(eV) A0 AI A2 A3 A4 A5 A6
50. -4,54767E+01 6,67186E+00 -1.30388E+00 -3,33476E-01 4,39632E-02 -4 52889E-02 ] 85831E-02
100, -4.51974E+01 6,44612E400 -I,]8362E+00 -'1.72127E-01 4 66619E-02-4 04263|;3-02 1 55388E-02
500, -4,35832E+01 5,17359E-I00 -5.65656E-01 -3,28985E-0.I 3 2666]E--02-7 75934E-03 ] 090]0E-03
I000, -4,23753E+01 4,27018E+00 '-2.07470E-01-3,69408[.,:-01-9 50854E-04 i ]7863E-02-8 41076E-04
5000, -3,900'38E+01 2.05191E.F00 2.49124E-01 -2,32101E-01 -8 19217E-02 7 92950F,-03 I 06018F;-02
10000, -3075454E+01 1,24999E+00 2,32693E-0]-I,]0685[,I-01 -6 99375E-02--5 625/2E-03 6 74424|",-03
20000, -3,62570E+03 6,12670E-01 ].45632E-01 -4.25717E--02 -4 ]3562E-02-I.0336]E-02 9 2344]E-04
Equal Temp, -4,47894E+01 6,48647E+00 -1.50363[,I+00 '-5,56465E.-02 1 00897E-02-3.20031E-02 2 63002E-02
See appendix for Chobyshev flt d_tails,
A-3 5
II . + bte -> H -t_ He"
Moxwellian....Mclxwellicln
A.-]6
Eloc_!;rol_ Cclpt:uto Rltte Coc:l![]cJ_orltt_ [or
ilo .rII'I-> II .t lle'I
t_eam - Maxwellian l<at-u Coef![ic.lcJnt_ (um3/n)
II+
'l'emp, 11o Energy (eV/ainu)
(oY) 10000, 20000. 4000 o, 70000. 100000° 200000, 500000,
1 0t",100 1,lEE-OB 3 43E-OB 3 911];-08 2,56E-08 1 4BE-OB 2 45E-0Y 1,24_:-i0
2 0E+00 ] lEE-OB 3 ,12E-0B 3 91E-3B 2,561'3-0B 1 4fiE-Oil 2 45E-09 1,24_]-10
4 OE_00 ] ]BE-OB 3 42E-OB 3 901.']-08 2,56E..OB 1 4BE-08 2 45E-09 ] 24E-]0
7 0E-100 i 18El-OB 3 4]l!]-OB 3 90F]-0B 2.55E-OB I 4BE-'0B 2 45E-09 i 24E'10,,
] 0E-101 i ]8E-08 3 4]E-08 3 BgE-0B 2.55E-08 1 4BE-OB 2 45E-.09 1 24E-10
2 01,]+01 ] ]BE-OB 3 40E-0B 3 88E-0B 2,55E-0B ] 47E-OB 2 451]-09 ] 2,4E-]0
4 0_1401 1 ]9E-OB 3 3BE-0B 3 B7E-0B 2 54E-OB ] 47E-08 2 45E-09 1 24E-10
7 BE+OI I ]gE-OB 3 37E-OB 3 B5E-0B 2 53E-0B ] 46E-0B 2 45[_-,09 i 24E-]0
1 0E+02 1 20E-00 3 36E-OB 3,B4E-0B 2 53E-0B i 46E-0B 2 45E-09 i 24E-]0
20E+02 ] 2412-08 3 33E-OB 3,80E-0B 2 51E-0B ].45B-OB 2 45E-09 ] 24_]-10
4 0E+02 1,31E-OB 3 29_:-0B 3,76E-08 2 49E-08 1 45FI-OB 2 451{:-09 ] 25E-10
7,0E+02 1.41E-08 3 25E-08 3.70E-0B 2 47E-08 i 4,1E-0B 2 47E-09 ] 26E-I0
1,0E+03 ],51E-OB 3 21E-08 3,66[,;-0B 2 46E-OB 1 44E-OB 2 48E-09 I 27E-I0
2.0E+03 1,77E-OB 3,14E-OB 3,53E-0B 2 42E-OB i 44E-0B 2.55E-09 ] 30E-10
4,0E+03 2,]lE-OB 3,05[,;-0B 3,30E-OB 2,34E-08 1 44E-08 2.70E-09 1 36E-I(}
7.0E+03 2,39E-OB 2,95E,-08 3,03E-08 2,23E-08 ] 43L,]-08 2,941,'.-09 ] 45E-I0
1,0E.1O4 2.54E-'08 2,B7E-0B 2,B2E-OB 2,12E-0B ] 41_J-08 3,1BE-09 ] 551_;-102,0E+04 2,64E-OB 2.C, lE-08 2,37E-0B ],B3E-OB ] 32E-0B 3.B4E-09 ] 94E-10
Notest Fo_" Chebyshev fltn of the above rate coefflcients it Is necessary to use the following paran_etel:s.
Eml n = I,OE-IO0 sV, Ema x = 2.0P,+04 eV
Cheby_hev [_'Ittin_JPara_._ for Rate Coeff]clentslie
Energy
(eV/ainu) AO Al A2 A3 A4 A5 A6
10000, ,-3 59874E+01 4.17430E-01 ] 93060E-01 1,41316E-02 -4.62466E-02 -3,2069BE-02 -6.14466E-03
20000. -3 45210E+01 -i ]0051E-01 -5 31364E-02 -2.09508E-02 -B.28916E-03 -4.29131E-03 -2.80760E-03
40000. -3 43497E+01 -] 93363E-01 -] 15051E-01 -5,41354E-02 -1,98052F]-02-4,14043E-03 ].32023E-03
70000. -3 51059E+0] -I 20106E-01 -7 36757E-02 -4,02144E-02-2,03546E-02 -8.65732E-03 -2.24607E-03
I00000. -3 6]OB2E+OI -3 BBO36E-D2-i 73976E-02-].]6387E-02-],05935E-02-7,51826E--03-3.79933E-03
200000, -3 94814E.101 i 55478E-0] ] ]45121'.I-01 6.41579E-02 2.61502E-02 6,20BB9E-03 -],4]]06E-03
500000, -4.54567E+0] ] 49642E-01 i 06212E-01 6.21478E-02 3.03614E-02 ].2630BE-02 4.94057E-03
See appendix for Chebyshev flt details.
A-37
hie + t-I+ -> H + I--le+
Beam --N1axweilian
A-3 B
Double E]eotron CaptLlre Cross Sectlon_1 fo_
' 11+ + iI_ -> tl- + lle 2+
Energy Velocity Cross Se(_tlon(eV/ainu) (Cre/S) (era2 )
4,7E+02 3,01P,+07 , 2,70E-22
7,0E+02 3.68E.107 5.75E-22
1.OE+03 4 37E+07 ].12E-21
2.0E+03 6.21E+07 4.20E-21
4.0E+03 8,89E+07 1.78E'20
7.0E+03 I.] 6E+08 5,0BE-20
i. 0E+04 ], 38E+08 i, 06E-i 9
2.0E+04 I.96E+08 3.75E-19
3.2E+04 2.48E+08 7.08E-19
4.0E+04 2.78E+08 6,42E-19
7,0E+04 3.65E+08 1,73E-19
i. 0E+05 4,37E+08 3,76E-20
2.0E+05 6.21E+08 9.67E-22
4,0E+05 8.78E+08 7,64E-24
7.0E+05 3.15E+09 9.68E-26
1,0E+06 3,38E+09 3.76E-27
Referencesl 35, 50, 52, 53, 54
Accuracy_ E < ixl04 eV/amu -,factor 2 oi' more; E > ixl04' eV/amu - 40% I
For a Chebyshev fit of the above cross seotlons it is necessary to use the following parameters.Eml n = 4.7E+02 eV/amu, Emc x = 9,9E+05 ev/amu
Chebyshev Fittinq Parameters for Cross Sections
A0 AI A2 A3 A4 A5 A6 A7 ' A8
-98.3453 -4.13574 -6.43185 -1.70697 .435158 .417370 -,125015 -.191020 .0356727
_'he fit represents the above cross sections with an rms deviation of 10.0%,
'['hemaximum deviation is 20,7% at 2.0E+04 eV/amu.
See appendix for Chebyshev fit details.
A-39
Q
Ht + He ->1-1- + He_+
Cross Section vs, Energy
'-1810 - i i irlilrl I rillilll r i i i ___i i i ' _ ' _ i i __L --
-- 1 '' -
_. Z// --
10_x- ,_'
10-2__ ir,, _-
1 -c 0-2:-0
t._rO(b
uo 10-2:_Or)COO RecommendedK...
U 10-2, = _Data
_
' Chebyshev Fit10-2:___
10-_'-
10-27 , ii JJJiil i i J iJil!l 1 i i iJiJJi J t l.lliJJ
!0_ 103 104 105 106Energy (eV/amu)
0
A-40 __
Electron Capture Cross Sections for i
H + + Li -> H + Li +
Energy Velocity Cross Section
(eV/amu) (cm_s) (cre2)
2.5E+02 2.20E+07 1.75E-16
3.0E+02 2.41E+07 2.38E-16
4.0E+02 2.78E+07 3.79E-16
5.0E+02 3 lIE+07 5.40E-16
7.0E.02 3 68E+07 8.95E-16
1.0E_03 4 39E+07 1.40E-15
2.0E+03 6 21E+07 3.28E-15
3.0E+03 7 61E+07 4.26E-15
3.6E+03 8 33E+07 4.35E-]5
5.0E+03 9 82E+07 4 07E-15
8.0E+03 1 24E+08 2 68E-15
1.0E+04 1.39E+08 i 80E-15
1.5E+04 1.70E+08 7 52E-16
3.0E%04 2.41E+08 7 98E-17 ....
5.0E+04 3.11E+08 2 84E-17
8.0E+04 3.93E+08 i 77E-17
1.5E.05 5.38E+08 8.73E-18
2.0E+05 6.2iE+08 5.21E-18
3.0E+05 7.61E+08 1.88E_18
4.0E+05 8.78E+08 7.17E-19
5.0E+05 9.82E+08 2.93E-19
5.6E+05 1.04E+09 2.02E-19
References: 230a 231, 232, 233, 234, 235, 236, 237, 238, 239
Accuracy: 30%
Notes: (I) Gruebler et al. (Ref. 235) found up to a factor of 2 greater cross section when H +
was the projectile compared to D + incident at equivalent velocities.
(2) For data on electron capture cross sections of Li + + H see references 247, 248, 252,253.
For a Chebyshev fit of the above cross sections Jt is necessary to use the following parameters.
Emi n = 2.5E+02 eV/amu, Ema x = 5.6E+05 eV/amu
Chebyshev Fitti_l_ Parameters for Cross Sections
AO Al A2 A3 A4 A5 A6 A7 A8
-74.2905 -3.64125 -2.48131 .598612 .0178325 -.507845 -.166745 .]77271 .132733
The fit represents the above cross sections with an rms deviation of 6.4%.
The maximum deviation is 17.7% at 3.0E+04 eV/amu.
See appendix for Chebyshev fit dc:tails.
A - 4 ]
H* + Li->I-4 + Li+
Cross S ,ction Energy
.0-1,1- ............-. '1 I I I I II1[ '1 1 I I I III I I I I '11 1'1'1'I J I I' I 11114--
_
10-__-:_, . , :___:
' f_,,,,
_E, 10-16
C -© -
Q.) - --
CO - ,,%,U3 . _ 17 "_ -0 "J - - Recommendecl
U : - ----Data
--
....... Chebyshev Fi't
10-'__
1(")-19 J J J JlU. JJ. l _ J JltJll ,, J J i JJJJJl J I , JlJJJ_
10_ 103 10_ i0s 10GEnergy (eV/a m u)
0
A-42
Electron Capture Rate Coefficients for OLi + II+ -> li 4 Li 4
Beam - Maxwel]ian Rate Coefficients (cm3/s
H +
Temp. Li Energy (eV/amu)
(eV) i0000. 20000. 40000. 70000. i00000. 200000. 500000.
f
1.0E400 2.50E-07 5.82E-08 1.24E-08 7 44E-09 6.05E-09' 3.23E-09' 2.88E-I0'*
2.0E+00 2.49E-07 5.83E-08 1.24E-08 7 44E-09 6.05E-09' 3.23E-09' 2 88E-10 **
4.0E.00 2.49E-07 5.83E-.08 1.24E-08 7 44E-09 6.05E-09' 3.23E-09" 2 88E-I0'*
7.0E+00 2.49E-07 5.84E-08 1.24E-08 7 44E-09 6.05E-09" 3,23E-09" 2 88E-I0'*
1.0E+01 2.49E-07 5.84E-08 ].24E-08 7 44E-09 6.05E-09" 3.23E-09' 2 88E-I0 _*
2.0E±01 2.48E-07 5.86E-08 1.24E-08 7 44E-09 6.05E-09" 3 22E-09" 2 89E-I0'*
4.0E+01 2.48E-07 5.89E-08 i.24E-0B 7 44E-09 6.05E-09 3 22E--09' 2 89E-I0'*
7.0E+01 2.48E-07 5.95E-08 ].24E-08 7.44E-09 6.05E-09 3 21E-09' 2.89E-I0 *_
1.0E+02 2.47E-07 6.00E-08 1.24E-08 7 44E-09 6.05E-09 3 21E-09' 2.90E-I0'*
2.0E+02 2.44E-07 6.17E-08 ].25E-08 7 44E-09 6.05E-09 3 20E-09' 2.91E-I0'*
4.0E+02 2.39E-07 6.46E-08 1.27E'08 7 44E-09 6.05E-09 3 ]9E.-09" 2.93E-I0'*
7.0E+02 2.30E-07 6.81E-08 1.30E-08 7 44E-09 6.05E-09 3 ]8E-09' 2.93E-I0 *_
1.0E+03 2.21E-07 7.10E-08 1.35E-08 7 45E-09 6 05E-09 3 17E-09' 2.91E-I0'*
2.0E+03 ].96E-07 7.73E-08 ].56E-08 7 53E-09 6 04E-09 3 16E-09" 2.86E-I0 *_
4.0E+03 1.64E-07 8.02E-08 2.04E-08 7.94E-09 6 04Ei09 3 ]4E-09' 2.85E-I0"*
7.0E+03 1.34E-07 7.67E-08 2.59E-08 9.12E-09 6 14E-09 3 lIE-09 2.94E-I0'*
1.0E+04 1.14E-07 7.14E-08 2,90E-08 1.06E-08 6 44E-09 3 08E-09 3.08E-I0'*
2.0E+04 7,50E-08 5.52E-08 3.08E-08 1.44E-08 8 16E-09 3 06E-09 3.61E-I0 *_
Accu acy_ * - Possible Error Greater Than 10% '
• * - Possible Error Greater Than ],00%
Notes; For Chebyshev fits of the above rate coefficients it is necessary to use the following parameters.
Emi n = 1.0E+00 eV, Ema × = 2.0E+04 eV
Chebyshev Fittinq Parameters for Rate Coefficients
Li
Energy
(eV/amu) AO A1 A2 A3 A4 A5 A6
I0000. -3.09481E+01 -4.64901E-01 -2.95]08E-01 -].33838E-01 -3.59323E-02 -1.29218E-03 8.76916E-04
20000. -3.31581E+0] 9.29024E-02 -3.27874E-02 -9.34862E-02 -7.42714E-02 -2.98862E-02 -6.36610E-04
40000. -3.59040E+01 4.30313E-01 2.62445E-01 8.26693E-02 -2.56]18E-02 -5.35625E-02 -3.78019E-02
70000. -3.72045E401 2.09566E-01 1.66816E-01 1.08374E-01 5.50349E-02 1.81051E-02 -2.94289E-03
i00000. -3.77748E+01 7.11403E-02 6.19800E-02 5.19417E-02 3.83027E-02 2.39693E-02 ].32084E-02
200000. -3.9135]E+01 -2.54412E-02 -9.95070E-03 -2.34861E-03 -2.74660E-04 3.660_9E-04 9.29558E-04
500000. -4.38736E+01 5.64031E-02 4.45512E-02 3.82771E-02 3.08448E-02 1.91863E-02 5.93228E-03t
See appendix for Chebyshev fit details.
•2
A.-43
I. + H* .-...'-,H + Li*
Beam - Maxwelliar,
A-44
Double E1eot_on Capture Cross Sections for _
li+ 4. ll- -> li" + II_r
Energy Veloclty Cross Sect ion
(eV/ainu) (ota/s) (cre 2)
5,9E+01 1.07E+07 9.98E-17
6,4E+01 I,lIE+07 I.02E-16
6,9E+01 ],15E+07 8.45E-17
7.4E+01 I.]9E+07 5.63 E-17
8,0E+OI ].24E+07 3.965-17
8.1 E+01 1.25E+07 3.95E-17
8.4E+OI i.27E+07 4.63E-17
8.9E_01 I.33E+07 6.]IE-17
9.4E+0] i,35E+07 7.54E-17
9.9E+0] i.38E+07 8.72E-17
i. OE+02 i _39E+07 8.82E-17
] .]E+02 1.46E407 6.84E-17
].2E+02 1,52E+07 4.70E-17
I.3E+02 I.58E+07 4,23E-17
]_4E+02 i.64_I107 4.84E-37
],5E+02 1.70E+07 6.33E-17
I,6E+02 1.76E+07 7.20E-I 7
1.7 E+02 i,81E+07 6.12E-17
],8E+02 !.86E+07 4.27E-17
I 9E+02 1.91 E+07 4,10E-17
2.0[_02 I.96E+07 4.62E-17
2,5E+02 2.20E+07 8.33E-17
3.0E+02 2.41E+07 1.08E-I 6
3.5E+02 2.60E+07 1.27E-16
4,0E+02 2.78E+07 i,44E-I 6
4 -5E+02 2,95E+07 1.50E-16
4.7E+02 3.01E+07 i.51E-I 6
5.0E+02 3.|lE+07 1.50E-]6
6.0E+02 3.40E+07 i.40E-16
8,0E+02 3.93E+07 1,14E-16
8.4E+02 4,03E+07 i.07E-I 6
i, 0E+03 4.39E+07 8.79E-17
],IE+03 4.61E+07 7.48E-17
Referencesj 69, 274, 275, 276
'"u_LEr__ql'i 30%
(3) The oscillatory behaviour results from the formation of a quasl-H 2 molecule.
(2) Th_: cross sectlon as plotted is an average of that measured by Peart (Ref. 274) and
that of Brouillard et al, (Ref. 275).
(3) P]otted are the H + energies wlth the H- at rest.P 3.
(4)The interaction energy is given by Eint =_[I'- for equal masses2
For a Chebyshev flt of the above cross sections it is necessary to use the following parameters.
Eml n : 5.9E+01 eV/ainu, Ema x = 1,3E+03 eV/ainu
C_,ebvshev Fltt__,eters for Cro.',u qecl i_ms
AO A1 A_ A3 ! 4 A5 A,, A7 AB
-74.0098 ,2273"/9 .02323_0[i _.788332 -.0060451]8 .0351500 .]0]]75 -,131!693 -.0302977
'J'he fIt reFuesenl.s the above c!u_s sectJol,,d with a:1 |ms (cv.l.al :on oi 2 .')%.
q'l,e maximum deviatic_n .is 46.4% at 8..[E-101 eV/allu.
See appendix for Chebyahev fit details.
A-45
Q
H+ -h tq- -> H- + t-q+
C - " _ Energross Uectlcn vs. yl-..
lc.D,-- 16,0 ..... I I I l I'l I11 ' i ....... i 1 i:l ii1 I ' i i F/ I illX _
14.0 -
2.0 ___j__. i i f_Ll iii 1 I _ J i _ ill .1 .L_LLL.J_L_t_
1o' 1_f 1¢ Io_Energy (eV/am u)
0
A-46
Mutual Nc:ubralization Cross Sect._ollS [or /
H+ 4. ll- -> H + II
Energy Ve]oclty Cross section
(sV/amu) (cre/s) (cre2)
2 0E-OI 6.21E+05 ] .69E-]3
4 0E-OI 8.79E+05 9.09}:-]4
7 0E-0I I,]6E+06 5,74E-14
1 0E+00 1.39E+06 4.27E-14
2 0E+00 1.96E+06 2,40E-14
4 0E+00 2.78 [':+06 I, 40E-14
7 0E+00 3.68E+06 9.21E-15
10E+OI 4.39E+06 7.36E-15
2 0E+01 6.21E+06 6,53}I-15
4 0E401 8.79E+06 7.11E-15
7 0E+01 I.]6E+07 8,20E-15
1 0E+02 1 39E+07 B.80E-15
2 0E+02 ] 96E+07 1 06E-]4
4.0E+02 2 78E+07 1 30F,-14
7.0E+02 3 68E+07 i 39E-14
1.0E+03 4 39E+07 1 38E-14
2.0E+03 6 21E+07 ] 17E-14
4.0E+03 8 79E+07 7 54E-15
4.8E+03 9 62E+07 6 36E-15
References: 63, 64, 65, 66, 67, 68, 69, 280
Ac___curacy: E > 20 eV/a,_u - 20%; E < 20 eV/ainu - factor 2 (see notes)
Notes: (i) Measurements made in the 1970's showed structure in the cross section curve in the
energy range of 40 - 700 eV/ainu. More recent measurements (Ref. 67 and 68) show no
evidence of structure and the cross sections are approximately a factor of 2 less than
those reported in Refs. 63-66 for energies less than 400 eV.
(2) Mosley (Ref. 63) found a sharp rise in the cross section for energies less than 30
eV/amu. Irt the region of overlap, with the most recent papers, Mosely was a factor of
two greater. Thus, the data of Mosely have been reduced by approximately a factor of
two which more nearly coincides with the theoretical data of Re[. 280.
(3) The data below i0 eV/ainu should be used with cautJ•on.
(4) Plotted is the II+ e1_ergy with II- at rest.
(5) The interaction energy is given by Eint=EH+/2.
(6) See Dolder's review (Ref. 69) for a d_scuss]on of this reaction.
For a Chebyshev fit of the above cross sections it is necessary tc, use the following parameters.
Eml n = 2,0E-01 eV/ainu, Ema x : 4.8E+03 eV/ainu
Chebyshev Fittirlg Parameters for Cross Sections
AO Al A2 A3 A4 A5 A6 A7 A8
-63.]439 -1.23277 .753504 -.408901 -.276190 .038]6]3 .0408940 -.04239]4 .00269073
The fit represents the above cross sect lens with an rms deviation of 2.4%.
The maximum deviation is 5.8% at 1.0E+01 eV/ainu.
See appendix for Chebyshev fit details.
A-47
0
H+ + H-->H + Pi
Cross _ect.lon vs, Energy
.10-1_[_ 1 1 iililll "f T-T'FT'IIII' I-rrTTTITi I I llrTl'q----'q--T"fqTITZ_ ,-" --4
Ii 10-'3-,-"" -- --
('It_ -" _
c-© -
'._
(D
(/_ ._
©L_ .,..-------__,, Recornrrlended
- - ...... Chebyshev Fit
--
10-_5--__._L___,I .,._LL_L__-L_L_,_Z_____J_Z__U__._._L.L_.U_UlCr' 10o 10' 10_ 1(3:' 1(:)"
Er,erg y ,(eV/clrnLi)
Q
A-4
0Si|III 0[' the l_lleetrOl] CaptUt'o and Ionlzatlon Cre, lie Seclt.lollt+ for
II + .I Ilo + -> [(II .I- 11o2"!') + (II + .I llPd2'I + e')l
EnErgy VElocllty Cros_ Seat Jen
(EV/ainu) (om/s) (ew2)
3,3E+03 7 98E+07 7,43E-20
4,0['I+03 8 7L_E+07 ],04E-19
7,0E+03 ] 16E+08 3,62E-19
1,0E+04 1 39E+08 9,89E-19
2,0E.i.04 I 961.':+08 1,00B-17
4,0E4.04 2 78_,+0B 2,31E-17
7,0E+04 3 68E+08 2,55E-17
],0E+05 4 39E+08 2,39E-17
2,0E+05 6 2lE.108 1,38E'17
4°0E+05 8 7lllq+08 6°84E-18
5°2E+05 ] 00E+09 4,82E-18
Referenuesl 69, 73, 75, 76, 77, 81, 277, 278, 279
ACCLlraa_ 20%
NotEsl (i) PlottEd are II+ EnErgiEs with tIIe lie'I'partlc_es at restEll+
(2) The Interaotlon EnErgy iU gh'en by Elllt = i:-2-5'
For a Chebyshev flt oi! the abOVE cross sectlons it is nECESsary to USE the fo]1owlng parameters.
Eml n = 3,3E+03 eV/ainu, Ema x = 5,2E405 EV/ainu
ChebyshEv Fittincj ParamEters for Cross Sections
A0 Al A2 A3 A4 A5 A6 A7 A8
-80.8329 2.22908 .-1,,82091-,0490[_94 ,341964 -.160988 -,0383566 ,0'746090 -.0322523
The fit represents the.above cross sections with an rms deviation of 4.3%,
The maxin_um dEViation is 9.2% at 1,0E-104 eV/atoLl,
See appEi_dix for Chebyshev fit details,
A-49
@
t1+ + I--le" -, .".-,('(',t--I-t- He__') + (H+ -t- He ;_+ -t- e i)i)
( ,.--,,, 4
Cross :::,ectlor-_vs, Ener-gy
10- 18---'----T--I" I i i i i-r]----T----T--FT-FFI i.... r- ....1--r--r-rq'Tq::
10-17 ,- \X -
._Z \\ .,,
O(- //
U - /® 2 -
O Reconlmended
(..P Data
10-i_- - - ..... Chebyst,ev Fit
I (] 2c_____L.___L_L_LLLLLI___I___J--_L.LLLL.LL i L.J__LLL_LJ_
1(._ l(J' ld 10_
Energy (eV/clmu,_
@
A.-50
_tJtlln oi! the l+L1t*,c++Lron Capture al|el IolllzaLJoll Rate (+'+oet+PJcJent_t llot:
II+ '1 llo I -> I(II +llo 2'+) .I (II .t .I. llt+2+_. + _-)I
NaxwollJan - Maxwe111an Rate CoellJclm_t[+ (cm3/s)
tl ,t.
'l'emp, Equal ll_J + 'I'emp, (eV)
(eV) 'l'_mp, 500, 750. ID{)0, 2500. 5000. 10000, 20000.
2 01+H.02 5,59E-17 1,11E-15 5,53[,',-15 1,7tJ_3-14 5 491!',-13 4 801,3-.12 4.151':-11 3.1(}I,_'-10
4 013+02 3,71E-14 5,08E-14 1.001'l-]3 ].74[,1-13 ] 350-12 7 551+J-]2 5 281_-11 3,421_-10
7 0E+02 7,08_3-13 5,49E-_3 7,52l';-13 9,961.':-].3 3 491!,-12 l 35E-I] 7 31E-II 3,93E-10
1 01,I+03 2,B3E-12 1,92_:-12 2.35PJ-]2 2,I13E-12 7 15F:-]2 2 22E-II 9 75B-11 4.461','-10
2 01_+03 3,]91:3-1] i0821'i-i] 2,01E-II 2,221+3-11 3 '17E-ll 7 69E-11 2 O_]E-),O 6.41E-10
4 0E+03 2,790-]0 ]+62E-]0 1,691!:-+10 ],76E-10 2 25E-10 3 ]BE-10 5 41E-10 1.08I_-09
7 01_J+03 1,021.+;-09 6,66E-10 6.79E"'10 6.921!:-]0 7 72E-I0 9 ]0E-10 ] 201-'3-09 1,78_+-09
i 0E+04 1,90E-09 1,34E-09 1.361'i-09 1.37E-09 ] 46g-09 ] 6]E-()9 ] 90E-,09 2.470-09
2 01':.104 4,311::-09 3,510-09 3,521_-09 3,53E-09 3 60E-09 3 711!;-09 3 921_3-09 4,31E-09
Notesl l;'orCllubyshev fits of the abovt? rate coefficients Jt Jt] necessary to use tile foJ.lowlncl p_iraltteters.
grain m 2,0L,_N02 eV, Ema x = 2,0E+04 eV
C_li_v ' PiLtinq Paramete[p, let Rate Coefl_icients
lle-t
'I'elllp. 0(eV) AO Al A2 A3 A4 A5 A6
500. -5 ]3885E+01 7.38050E.100 -1 ]7079E+00 6.70967E-02 -1,42287E-01 3.79377[+_-02 5 35545E-02
750, -5 05826E-I01 6.7373(<EI00 -8 ]0583E-01 -8,730940-02 ,-9,219441_-02 3,]78771!'-02 4 715271_:-02
1000, -4 99515E401 6,248991+H00 -5 58489E-01 -].+J2760E-O] -6.61605E-02 3.20490_:-02 4 02355E-02
2500, -4 77567E+01 4,6B5560.i00 6 566661!+-02 -3,344201++'-0]-3.908041_:-02 4.270661!+-02 i 48636E.*02
5000. -4 593640+0] 3.571_11_+00 2 6B644B-01 -2.7920£1E-01 -4,4310}]E-02 _.196}J5E-02 6 39440E-03
10000,-4 382S21,:I0] 2.4149Bg+00 3 24673E-01 +,I.50289_:-01 -4.79414E-02 9.61266E-03 5 766321':-03
20000. -4 16749E+01 ].36451g.I00 2 92509B-01 -4.417251_-02 -3,60762E-02 -3.52436_:-03 2 65593E-03
l,]qua] Temp. -5 180520+01 8,42203[,l+00-2 ]D]9]l+:.lO0 5,09552E-01 -3.497260-01 ],505960-0] ] ]148]g-02
See appen(lJ× for Chebyshev fit details.
H" -t-- t-le+ -,.*.,((tri -t..t-te_+) + (H+ -k hie2* -t- e-))4
Mcl>,welli,]rq--M,_qxwellior-i
A-5_
Tot:al l,]]ectron Capture Rate C(_eff_cleuts for O
l-le t + H t -> ((H + He 2t ) + (li t -I" l.te lt + e'))
Beam - Maxwelllan Rate Coefficients (uill_/s)
H . TelIlp, lie _ Elle igy ( eV/a.lUtl )(sV) i0000, 20000, 40000, 70000, 100000. 200000. 5(I0000,
1,0[_+00 1.42_,-i0 1,95E-09 6 39E-09 9 3]E-09 9,56_]-09 8,57E-09 4,98N-092,0F,+O0 1.43_,-.i0 1,941!I-O9 6 3961-09 9 31E-09 9,56_-09 8,57E-09 4,98E=094.0_+00 1.43E-I0 1,94E-09 6 3flF,-O9 9 31E-09 9,55E-09 8,56E-09 4.98_-O97,0E+O0 1.44E-I0 1,93F_-09 6 37E-O9 9 31E-09 9,55E-09 8,5617]-09 4.98E-091,0E+O] 1.45E-I0 1.92E-09 6 36_-09 9 30E'09 9,55E-09 8,56E-O9 4.98E-092,0E+OI 1.47E-]0 1.91E-09 6 34E-09 9 29E-09 9,55E-09 8,551_-09 4,98E-094,0E+OI 1,53E-I0 ],90E-O9 6 31F,-09 9 27E-09 9,54E-09 8.55E-09 4,98E-097,0E+OI 1.60E-IO 1.89_-09 6 29[_-O9 9 25E-O9 9,53E-O9 8,54E-09 4,94E-O9I,OE+O2 1,68E-10 1,89E-09 6 27E-09 9 23E-09 9,53E-09 8,53E-09 4.87E--092.0E+02 i.94E-I0 1.90E-09 6 22_]-09 9 19P]-09 9,51E-09 8,52E-09 4,59E-094.0E+02 2,53E-i0 1.95E-09 6 18[r,-09 9 13E-09 9,49[_-O9 8,49_,-09 4.2OFJ-09'7,01!:+02 3.5OE-10 2,06E-09 6 15E-O9 9,07E-09 9.46E-09 8,47E-09 3.88F_-09'
I.OE+O3 4,49E-I0 2,17E-09 6 ]61!:-O9 9,02[_-09 9 44E-09 8.45E-09 3,691_-09'2,0E+03 7,69E-I0 2,52E-09 6 19E-09 8,90E-09 9 36E-09 8.39E,-09 3,40_-09'4.0E+03 ].37E-09 3.11E-09 6 29E-09 8.70E-09 9 23[_-09 8.32E-09 3.18E-O9'7,0E+O3 2.18E-09 3.79E-09 6 44E-09 8,49E-09 9 05F_-O9 8,23E-O9 3.05E-09'I,OE-IO4 2.88E-09 4.33E-09 6 571_-09 8,34E-09 8 89E-O9 8,161_-O9 2.99E-O9*2,0E+04 4,61E-09 5,54E-09 6 931B-09 8,06E-09 8 48E-09 7,9OE-09 2.9OE-O9'
Aacuracyl _' - Possible Error (][eater Thai] 10%** - Possible Error (]reatei: Tharl 100%
Notesl For Chebyshev fits of the above rate coeff_iclents it is necessary to use
the following parmueters. _&
El/lin = I,OE+OO eV, Enlax = 2.0E+O4 eV
Chebyshev Fittinq ,par_ueters for Rate Coefficients
He+Ellsrgy(eV/alnu) AO A1 A2 A3 A4 A5 A6
10000, -43,1609 1,70961 ,748336 .0779426 -,IO9478 -,O550219 ,OO9OO97720000, -39,6126 ,447496 ' ,287036 ,O983789 -.00499014 -,O233174 -,0097589840000, -37,7344 ,0172991 .O327260 .O232302 ,00718786 6,985132E-O5 -,0011939270000, -37,0628 -,0628379 -.031750b -.0103654 -,00206175 4,B54519E-O4 ,OO112569100000, -36.9842 -.0440273 -,0277108 -,0140155 -,O0593012 -.,00104524 -1.575483E-O4200000, -37,1894 -,0312141 -,0170352 -,00"270730 -,00339568 -,00158336 -7.883493E-O4500000. -38.6322 -,298865 -,095_539 .O317736 ,0]55560 -,00369627 -.0132072
See appendix for Chebyshev fit details
A-53
O ,, ,
He* + H+ ->((H + He2*) + (H+ -I- tile2* +e-))
Beorn - Maxwellian
....... Chebyshev Fit
I 'I I'
A-54
Electron Capture C_oss Sections for
H + + lie+ -> H + 11e2+ '"
Energy Velocity Cross Section
(eV/amu) (cm/s) (cm 2)
].8E+03 5_89E+07 5.84E-22
2.0E+03 6.21E+07 1.55E-21
4.0E+03 B.79E+07 8.84E-20
7.0E+03 1.16E+08 4.91E-19
1.0E+04 1.39E+08 1.40E-18
2.0E+04 1.96E+08 I.]7E-17
4.0E+04 2.78E+08 2.46E-17
4.4E+04 2.91E+08 2.48E-17
5.6E+04 3.29E+08 2.35E-17
7.0E+04 3.68E+08 1.92E-17
].0E+05 4.39E+08 1.20E-17
2.0E+05 6.21E+08 4.06E-18
2.4E+05 6.80E+08 3.06E-18
References: 69, 71, 73, 74, 75, 76, 77, 78, 79, 80
Accuracy: E < ixl04 eV/amu - factor 2; Ixl04 eV/amu < E < 2.2xi05 eV/amu - 25%
Notes.____:(i) At energies less than ixl04 eV/amu the assumpt on was made that the electron capture
cross section (,c)is equal tothe total cross section (ml,). _c: H+ + He+-> H + He2+;
aT_ H + + He + -> [(H + He +) 4 (H+ + He 2+ + e-)].
(2) Data below 3x103 eV/amu rely on theory of references 71, 79, and 80.
(3) Plotted is the H + energy with He + at rest.. EH+
(4) Tile interaction energy is given by Ein t = 1.2----5'
For a Chebyshev fit of the above cross sections it is necessary to use the following parameters.
Emi n = 1.8E+03 eV/amu, Ema x = 2.4E+05 eV/amu
Cheb_shev Fitting Parameters for Cross Sections
AO Al A2 A3 A4 A5 A6 A7 A8
-83.539] 3.94447 -2.70255 .0791317 -.0544615 .290337 -.133801 -.0294272 .0518279
The fit represents the above cross sections with an rms deviation of 2.4%.
The maximum deviation is 3.8% at 4.0E+04 eV/amu.
See appendix for Chebyshev fit details.
A-55
H+ + He+ ->Pl + He2+
Cross Section vs. Energy
A-56
Electron CaptUre Rate Coefficients for
H+ + 'lle + -> li + He 2+
Maxwelllan - Maxwellian Rate Coefficients (cm3/s)
H+
Temp. Equal lie+ Temp. (.eV)
(eV) Temp. 200. 750. 1000. 2500. 5000. 10000. 20000.
1.0E+02 1.84E-19 2.17E-18 1.20E-15 4.99E-15 3.22E-13 4.38E-12 4.62E-II 3.50E-10
2.0E+02 3.92E-16 3,92E-16 9.86E-15 ,2.52E-14 5.84E-13 5,73E-12 5.24E-II 3.68E-I0
4.0E+02 4.67E-14 2.52E-14 1.13E-13 I._9E-13 1.48E-12 9.25E-12 6.64E-II 4.05E-10
7.0E+02 7.57E-13 3.7BE-13 B.O5E-13 1.0BE-12 _ 4.07E-12 1.69E-II 9.13E-II 4.62E-I0
1.0E+03 3.26E-12 1.63E-12 2.67E-12 3,26E-12 8.74E-12 2.81E-11 1.21E-I0 5.22E-I0
2.0E+03 4.04E-II 2.02E-II 2.54E-II 2.81E-II 4.77E-II 9.59E-]I 2.51E'I0 7.37E-I0
4.0E+03 3.33E-10 1.87E-I0 2.06E-I0 2.14E-10 2.71E-I0 3.77E-I0 6.27E-I0 1.20E-09
7.0E+03 1.14E-09 7.48E-I0 7.79E'10 7.93E-I0 8.80E-I0 1.03E-09 1.32E-09 1.91E-09
1.0E+04 2.02E-09 1.46E-09 1.49E-09 1.50E-09 1.59E-.09 1,74E-09 2.02E-09 2.53E-09
2.0E+04 3.87E-09 3.34E-09 3.35E-09 3.36E-09 3.41E-09 3.49E-09 3.63E-09 3.87E-09
Notes: For Chebyshev fits of the above rate coefficients it is necessary to use the following parameters.
Eml n = 1.0E+02 eV, Ema x = 2.0E+04 eV
Chebyshev Fitting Parameters for Rate Coefficients
lie+ O
Temp.
(eV) AO A1 A2 A3 A4 A5 A6
200. -5.56691E+01 1.03931E+01 -2.17666E+00 2.00410E-01 -I,29725E.01 -1.82527E-02 4.7!659E-02
750. -5.24322E+01 7.77856E+00 -7.52983E-01 -3.38100E-01 -3.27433E-03 -1.92121E-02 3.80958E-02
1000. -5.15600E+01 7.11555E+00 -4.59118E-01 -4.02692E-01 -1.26409E-02 -3.27140E-03 3.15657E-02
2500. -4.86136E+01 5.03638E+00 2.33_60E-01 -4.36889E-01 -7.67903E-02 3.44015E-02 1.99228E-02
5000. -4.63267E+01 3.63467E+00 4.33629E-01 -3.18641E-01 -I.01089E-01 2.48311E-02 1.64483E-02
10000. -4.39403E+01 2.34146E+00 4.31460E-01 -1.58490E-01 -8.81424E-02 -4.91624E-04 1.03754E-02
20000. -4.16815E+01 1.25619E+00 3.21917E-01-4.30200E-02 -5.44652E-02 -1.22828E-02 2.56368E-03
Equal Temp. -5.56573E+01 I.I1221E+01 -3.07961E+00 6.63079E-01 -3.65584E-01 9.91144E-02 ].99414E-02
See appendix for Chebyshev fit details.
A-,57
bl+ + He+ -> tt + He2+
A-58
AElectron Capture Cross Sections for
v
}12+ + H2 -> H 2 + }12+ H2 + + H -> H 2 + H+ H2 + + He -> H2 + He +
Energy Cross _ection Energy Cross _ection Energy Cross _ectioneV/amu cm- eV/amu om- eV/amu cm-
2.0E+00 1.22E-15 5.0E+01 8.00E-16 1.2E+03 1.39E-18
4.0E+00 1.12E-15 7.0E+01 0.36E-16 2.0E+03 1.50E-187.0E+00 1.06E-15 1.0E+02 8.75E-16 4.0E+03 1.64E-18
1.0E+01 1.01E-15 2.0E+02 9.54E-16 7.0E+03 1.73E-IS2.0E+01 9.21E-16 4.0E+02 1.02E-15 8.0E+03 1.82E-18
4.0E+01 7.83E,16 7.0E+02 1.07FP-15 9.0E+03 2.18E-188.0E+01 6.06E-16 1.0E+03 1.09E-15 1.0E+04 2.68E-18
1.0E+02 5.64E-16 2.0E+03 1.02E-15 1.55+04 5.45E-182.0E+02 4.95E-16 3.5E+03 8.96E-16 2.0E+04 7.26E-183.0E+02 4.89E-16 5.0E+03 7.23E-16 2.4E+04 7.49E-186.0E+02 4.96E,168.0E+02 5.28EI161.0E+03 5.39E-162.0E+03 5.49E-16
3.0E+03 5.26E-165.0E+03 4.01E-168.0E+03 3.86E-161.0E+04 3.39E-162.0E+04 2.04E-163.0E+04 1.26E-165.0E+04 4.58E-176.0E+04 2.72E-178.0E+04 1.15E-17i.0E+056.43E-18
Re fe re__.___nc es_____z,.+"2_+_2._3,39_2_3,82,2o8,210,211,212,213,214,215,216,217,218,219,220H_ + + He - 82
__H2 + + I! - 30% E < lxl03 eV/amu; 20% E > 1x103 eV/amuH_+ + H 2-, 30%
Hl + + He - unknown
ot_p._: (i) At energies less than 1.5x103 eV/amu the cross sections were determined by measurlng fm&the slow ion current produced in the collisions. The cross section was calculated
assuming that H_+ ions formed in ionizing collisions were negligible. _tlmer et al.(Ref. 213) found the ratio of H+/_2 + produced to be .024 at 7.5xi eV/amu andincreased monotonically to .2 at 25x10J eV/amu.
(2) A proportional counter was used in many experiments at energies greater than ixl03eV/amu to measure H 2 formed in the collision.
(3) lt is well known that the II + electron c.... _ + apture cross sections are dependent on the
vIbratlonal levels of the Incident H 2 ion. see the following set of data for themagnitude of thl_ effect which increases as the energy decreases.
fou :mh3_(41 Kaqp_s _t al. (Ref. 228) i0__ _ rate constants at thermal energies to be6.4xi0 -'_u cma/s for H2+ + H and 5x s for D2+ + D.
(5) Electron capture data for II2+ in He are very scarce. The data presented here shouldbe used with caution.
For Chebyshev fits of the above cross sections it Is necessary to use the following parameters.
[,11"+_++ H2_ _min = 2.0E+00 eV/amu, Em_x = 1.0E+05 eV/amuL_2+ + H: Eml n = 5.0E+01 eV/amu, Ems x = 5.0E+03 eV/amu"2 + He_ Eml n = 1.2E+03 eV/amu, Ems x = 2.4E+04 eV/emc
Chebvshey Fitting Parameters for Cross Sections
A0 A1 A2 A3 A4 A5 A6 A7 A8H2+ + H2z -71.4572 -1.88878 -.906965 -.676593 -.388666 -.0528444 .0283239 -.0386419 _00767518
H2+ + H: -69.2642 .0203046 -.153359 -.0596508 -.0175975 -.00448389 -.00355258 -.00672273 -.00592839
H2 + + He_ -81.0697 .916248 .310573 .0729101 -.120222 -.148642 .0679087
The fit represents the H + + _ cross section with an rms deviation of 3.8%.The maximum deviation is2 7. at 8.IE+04 eV/amu.
The fit represents the H2+ + H cross section with an rms deviation of 0.1%.The maximum deviation is 0.2% at 7.0E+02 eV/amu.
The fit represents the H2+ + He cross section with an rms deviation of 2.0%.The maximum deviation is 4.0% at 8.0E+03 eV/amu,
See appendix for Chebyshev fit details.
A-59
+,
t-t_ + H, kl_,He -> H_
Cross ection vs. Energy
"iV 14_____T__.T_IIF_- lillll I I i IFFN_IJli I--T I llrll i '-T--F-TTTTTTI
+
- _- H_ + H2--
x - H_* + H
'_--_" ,_ : v- pi.,++ He"-..._,
- "_.._ _
O /.,....,,
1"4
E - "\ -& _ \ -
c-O _'_ 10-1 _C)
OO
(/') -
(/') ._
o
U
10,-17 _-
- Recommended
__ Dclta
..... Chebyshev Fitqo-J ---! I 11 t.uIL__-i__LJ_J.J_LU.L___.LJ__J.J_iJJIL_J__L_LII!!d --L_LJ.J:4..U.
10o 10' 102 IE_ 104 10sEnergy (eV,,/an-1u)
ii
, , A-60 '
A
Electron Capture Cross Sections for IV
{{24(\' _ 0,1,2,3) + II2 -> I{2
(\, = O) (_, = ]) ,(_, = 2) (v - 3)
Energy CroSoSm_eCtlon Energy Cros, _eotion Energy Cross _eotio,] Energy CroB,] _ectlo,eV/ainu eV/amu cln_ eV/ainu am- eV/ainu cm
4,0E+00 7.65E-16 4 0E.00 1,20E'15 4.0E+00 1 22E-15 4.0E+00 i ]0E-15
5.0E+00 7.7BE-16 6 0E+00 . 1,35E-15 6.0E.t.O0 i ]4E-15 7.5E+00 1 09E-15
6 0E+00 7,90E-16 8 0E+00 ].liE-15 7,5E+00 1 10E-15 1.0E+01 1 05E'15
7 7E+00 8.05E-16 1 5E+01 1.05E-.15 1.51!:+01 1 04E-15 Io5E+01 9 92E-161 0E+01 B.03E-16 2 5E+01 9,97E-16 2.5E+01 9 98E-16 3,0E+01 8 95E-16
1 5E+01 8.04E-16 4 0E+01 ,9.54E-16 4.0E+01 9 56E-16 6.0E+01 7 98E"16
2 OE+'Ol 8.03E-16 6 OE+OI 9.16E-16 7.0E+01 9 1'lE-16 7.5E+01 7 65E-16
4 OE+OI 8.09E-16 9 OE.I'OI 8.72E-16 7.5E+01 9 03E-16 1,5E+02 7 36E-16
6 0E+01 8.07E'-16 i 5E-I'02 8.09E-16 1.0E+02 8 55E-16 2.0E+02 7 20E-16
7 5E+01 8.09E-16 2 0E.02 7.74E-16 2,0E+02 7 45E-16 4.0E+02 6 75E-169 0E+01 7.86E-16 3 0E+02 7,62E-16 5.0E+02 5 97E-16 5.0E+02 6 59E'-161 5E+02 7 .19E-16 5,0F+02 7.43E-16 ,2 0E+02 6.83E-163 0E+02 6.98E-16
4 0E+02 7.11E-16,
5.0E+02 7.20E-16
__gfet'e_ges: 221, 222, 223, 224, 225, 226, 227, 295
Ac o u rac.g.y_]unkl_own
_hLg__e_ (I) These experimental data are taken from Campbell et al. (Ref. 221). For further
information see theoretlcal references 222 - 227 and experimental measurements of Liaoet al. (Ref. 295).
For Chebyshev fits of the above cross sections it is necessary to use the following parameters.
(_ = 0) Eml n = 4.0E+00 eV/ainu, Ema x = 5.0E+02 eV/amu(v = i) _Emln 4.0E+00 eV/ainu, E _. 5.0E+02 eV/atoll
(v = 2) Eml n 4.0E+00 eV/ainu, E maxmax = 5.0E+02 eV/amu
(v = 3) Eml n 4.0E+00 eV/ainu, Emax : 5,0E+02 eV/ainu
Chebvsllev F!t'tln q Parameters for Cross Sections
A0 AI A2 A3 A4 A5 A6 A7 A8
(v = 0) -69.6245 -.0593713 -.0380137 .0269366 .0238283 .0156238 -,00842422 -.0146446 -.00321688
(v = I) -69.2068 -.245756 .00730004 .0108746 .0127040 .00132443 -.00641668 -.00611834 -.00633415
(\, = 2) -69.2536 -.288634 -,0220048 -.0199150 2.45200E-04 -.0241700 -.0316741 -.0245964 -.0170459
(v = 3) -69.3794 -.283633 .0144526 .0213835 -.0200482 -.00269142 --.00368054 .00893694 -5.08689E-04
The fit represents the %,=0 cross section with an rms deviation of 0.6%.
The maximum deviation is 0.9% at 2.0E402 eV/ainu.
The fit represents the v=l cross section wit|| an rms deviation of 0.]%.
'Pilemaximum deviation is 0.2% at 2.0E+02 eV/ainu.
The fit represents the v=2 cross sect ion with an rms deviation of 0.1%.
The maximum deviation is 0.2% at 4.0E+01 eV/amu.
The fit represents the _=3 cross section with an rms deviatlon of 0.3%,The maximum deviation is 0.7% at 7.5E+01 eV/ainu.
See appendix for Chebyshev fit details.
O
A-61
0
t--I.,+(1,,-0,1,2,3) + Pl:, -> t--I_,
t
Crc__oo ':-,ectl01_v_',_.Ener-gy
'0•-- 13,0 _ r i • _,_,_,i-----1---'T--F"T'TT'rTT------T---T'-T--r-'FTTT×
...... Ctlebyshev Fit
5,0 .... L_.__I ....i: I I I !_LL._J_.-_L-J-J-I.J I L_._L.._LJ._L-LL
1o0 Io' Io_ lc.)"Energy (eVA:lrnuI
0
A-62
_leotron CaptUre Cross Seotlons for
l.le4' + II -> lie + 114.
Energy Velocity Cross Seotlon
(eV/amu) (om/e) (ore2)
2,5B+02 2,20E+07 1,54_-17
4,0E+02 2,78E+07 2,39B-17
7,0E+02 3,68E+07 3,99E-17
1,0E+03 4,39E+07 4.74B-17
2.0E+03 6,21E+07 5.57E-17
4,0E+03 8,79E+07 9.08_-17
7.0E+03 1,16E408 1,71E-16 _
1.0E+04 1,39E+08 2.33_-16
2,0E+04 1,96E+08 2,42B-16
4.0E+04 2,78E+08 1,00B-16
7.0E+04 3.68E+08 2.97_-17
1.0E+05 4.39_+08 1.29_'17
2.0E+05 6,21E+08 1.01E'18
4,0E+05 8,78E+08 7.94B-20
7.0E+05 1.16E+09 2.46_-21
7, 22, 59, 60, 61
Aoourac_ E < 600 eV/amu - unknown; E > 600 eV - 30%
Note__./:The lowest experimental measurement was at an energy of 500 eV/amu. Data was
extrapolated to 250 eV/amu by using the theoretical results of Ref. 61,
For a Chebyshev fit of the above cross sections it is necessary to Use the following parameters.
Eml n = 2,5E+02 eV/amu, Emax = 7.0E+05 eV/amu
C_hebyshev Fitting Parameters for Cross Seotlons
A0 A1 A2 A3 A4 A5 A6 A7 A8
-79.2449 -3.43445 -3.38701 -.953151 .0800233 .153935 -.198503 -.126958 ,0492936
The fit represents the above cross sections with an rms deviation of 6.7%.
The maximum deviation is 15,8% at 2.0E+05 8V/amu.
See appendix for Chebysilev fit details.
A-6]
He+ -t- t--t....> I--te -t- I--I+
Cross ii;ection vs. Energy
IO'5• _--"--i -t _ i / _i q_--q--'T-TI I rn] ' _ i: __ Fr1-q---q---r-r-rn-r_
1OY__ / -_
_-- /,.,.../'-_
'1017_, , _
_ _-"
_ -©
'_ l(j _=_.(1) -
_ 203
0 Reconlmended
U 10-1g _Doto
- ' Chebyshev Fit
•10-2=
ld lo:' lc¢ ld lo_Energ y (eV/or-nu)
01
A-64
AElootroll Capture Rate Coc)fflulonts for
lle'l4 II-> lie ,.I_ II+
Maxwe]11an - Maxwo111an Rate Co_fflolents (om3/s)
Ilo +
Temp, EqUal I.I T.emp, (eV)
(eV) 'i'emp, i0. I00, i000. 2500, 5000, i0000, 20000,
7.01_+01 7.00E-I] 1.60E-13 I 51E-I0 2,97E-09 9 16E-09 i 8BIq-O8 2 75E-08 2,77E-08
I.OE+02 1,74E-10 1,05E-12 1 74E-I0 3.00E-09 9 20E-09 I 88E-08 2 75E-00 2,77E-08
2.0E+02 5,93E-I0 1,89E-II 2 54E-10 3.0BE-09 9 31E-09 1 89E-08 2 75E-08 2,77E-08
4.0E+02 1.37E-09 !,29E-I0 4 23E-I0 3,25E-09 9 53E-09 I 91E-0B 2 75E-08 2.77E-08
7 0E+02 2050E-09 3,71E-I0 6 761._-i0 3.52E-09 ' 9 86E-09 1 93E-08 2 76E-08 2,77E-08
1 0E+03 3.79E-09 6.26E-I0 9 1BE-10 3,79E-09 ] 02E-00 1 95E-08 2 77E-08 2.77E-08
2 0E+03 9,08E-09 1,40E-09 i 6"/E,'09 4,76E-09 1 13E'08 2 02E-08 2 78E-08 2.76E-08
4 0E+03 I.BBE-0B 2,95E-09 3 25E-09 6.87E-09 i 34E-08 2 15E-08 2,81E-'08 2,74E-08
7 0E+03 2.63E-08 5,83E-09 6 21E-09 1,02E-08 1 63E-08 2 32E-0B 2,84E-08 2,72E-08
I 0E+04 2,06E-08 9.13E-09 9 53E-09 ].34E-08 i 88E-08 2 46E-08 2.86E-08 2,69E-08
2.0E+04 2.59E-08 1.BeE-OB ] 91R-08 2,15E-08 2 46E-08 2 75E-08 2.88E-08 2.59E-08
Notesz For Chebyshev fits of the above rate ooefficients it is neoessary to USe the following parameters.
Eml n = 7,0E+01 eV, Ema x = 2.0E404 eV
C_ebyshev Fitting Parameters for Rate Coefficients _&II
TeHLp,
(eV) AO AI A2 A3 A4 A5 A6
i0. -4.44012E+01 5,33316E+UO -1.31634E+00 5,53831E-01 -I.05230E-01 -4,75481E-02 -6,48771E-03
i00 -4.08648E+01 2,48428E+00 2.58050E-01 -3.12250E-02 9.54007E-04 -3.30158E-02 -2.12794E-02
i000 -3.79160E+01 9.81592E-01 3.54607E-01 2,81517E-02-3.71282E-02 -1.95845E-02 --3.45087E-03
2500 -3,63706E+01 4,76956E-01 1.86293E-01 2.58640E-02 -1.33869E-02 -9,40073E-03 -2.40891E-03
5000 -3.53362E+01 1.79870E-01 7.40800E-02 1.32222E-02 -3.81465E-03 -3.86405E-03 -1.31950E-03
i0000 -3.47840E+01 2,52895E-02 8.72489E-03 -3.06100E-04 -2.09262E-03 -1.25992E-03 -3.74090E-04
20000 -3.48330E+01 -2.63999E-02 -1.50886E-02 -6.64467E-03 -2,39705E-03 -7,47129E-04 -1.92495E-04
Equal Temp -3.92825E+01 2.95989E+00 -6.50284E-01 -6.36867E-02 -I,59695E-01 6.25401E-02 2.55537E-02
See appendix for Chebyshev fit details.
®
t-ie" ,-t- H ---'> t-Ie -f- t--I+
lx,loxwelliar_-.- Ma×welian
A-6(;
Electron Capture Rate Coefficlonts for IFl + lie + -> lie + 11"F
Beam - Maxwellian Rate Coefftoiellts (em3/s)d
,IIe +
Temp, II Energy (eV/alnU)
(eV) i0000, 20000, 40000, 70000. lO0000, 200000, 500000,
1.0E+00 3.19E-0B 4,74E-08 2.77E-0B 1,09E-08 5.66E'09 6,28E-10 1,95E-II**
2.0E+00 3,23E-08 4.74E-08 2,77E-08 1.09E-08 5.66E-09 6.27E-I0 1,95E-I]**
4.0E+00 3.22E-08 4.73E-08 2.77E-08 1.09E-08 5.65E-09 6,27E-I0 1,95E-II**
7.0E+00 3.22E-08 4,72E-08 2,77E-0B ].09E-08 5,65E-09 6,27E-]0 1,95E-II_*
1,0E+01 3,21E-08 4.71E-08 2.77E-08 1,09E-08 5.65E-09 6,27E-10 1.95E-II**
2.0E+0] 3.21E,08 4.70E-08 2.76E-08 1.09E-08 5.64E-09 6.27E-I0 1.95E-I]**
4.0E+01 3.]9E-08 4,68E,-08 2.76E-08 1.09E-08 5.63E-09 6,28E-I0 1.95E-ii**
70E+01 3. ]8E-08 4.65E-08 2,75E-08 1.09E-08 5.62E-09 6.28E-]0 I ,95E-II**
1.0E+02 3,17E,-08 4,63E-08 2,74E_-08 ] _09E-08 5.61E-09 6.28E-I0 1,95E-II**
2 0E+02 3,16E-08 4,58E-08 2,73E-08 ],09E-08 5,59E-09 6,29E-I0 i, 96E-II**
4 0E+02 3.14E-08 4.51E-08 2,72E-08 1,09E-08 , 5,56E-09 6.30E-I0 I,96E-II**
7 OE+02 3.12E-08 4.44E-08 2,70E.-08 1.09E-08 5.54E-09 6.32E-I0 i. 97E-II**
l OE+03 3.12E-08 4,38E-08 2,68E-08 1.09E-08 5_ 52E-09 6.34E-I0 ], 98E'I]*
2 0E+03 3.12E-08 4,24E-08 2,65E-08 l. 10E-0B 5,50E-09 6,41E-10 2,01E-II*
4 0E+03 3, ]5E_.08 4,04E-08 2.62E-08 1,11E-08 5,51E-09 6,55E-]0 2,07E-11'
7 0E+03 3.17E-08 3,82E-08 2,57E-08 i. 13E-08 5,56E-09 6,77E-I0 2,17E-II*
1,0E+04 3,18E-08 3.65E-.08 2.53E-08 1.15E-08 5,63E-09 7,01E-10 2.26E-II* O2.0E+04 3,13E-08 3,26E-08 2,37E-08 1,18E-08 5.92E-09 7.89E-I0 2,54E-II*
Aoouracys * - Possible Error Greater [l'harl 10%
• * - Possible Error Greater Than 100%
Notesl For Chebyshev fits of tile above rate ooefficients it _s n_cessary to use the following parameters.
Eml n = 1.0E+00 eV, Ema x = 2.0E+04 eV
(_hebvshev F..i_eter s for., Rate Coeff!o_kgnt_.sH
Energy
(eV/amu) AO A1 A2 A3 A4 A5 A6
10000. -3.45301E+01 ,.1.16460E-02 2.95116E-03 6.60447E-03 -4.30159E-03 -3.33439E-03 -4.15571E-03
20000. -3,39259E+01 -I.54811E-01 -'7,B9802E-02 -3,03904E-02 -9.78923E-03 -2.83585E-03 -6.35026E-04
40000. -3.48770E+01 -5.98881E-02 -3.03031E-02 -1.35966E-02 -7.00807E-03 -4.08339E-03 -2.34824E-03
70000. -3.66351E+01 2.84585E-02 2.06398E-02 1.05841E-02 3.32277E-03 -4.79714E-05 -9.38437E-04
100000. -3.79874E+01 2.72710E-03 1.55802E-02 ].57294E-02 9.39045E-03 3.99108E-03 1.23."31E-03
200000. -4.22957E+01 7. 45856E-02 5.41]15E-02 3.2318]E-02 i. 66050E-02 6.94819E-03 2.78,156E-Q3
500000. -4,92176E+01 9.14498E-02 6.40861E-02 3.57259E-02 ].57066E-02 5,]3868E-03 8.46885E-04
See appendix for Chebysh_v fit details.
A-67
H + He* >He + H*
BeQm -- Me×weiion
710- _ I ' '__"I , , ,,,,l,l i ,, l,,,,F , ',,,IIi,l , I Jlll,i
- - H Energy[- ,,.
- _ (eV/arnu)
---'-----v A --10000.
x --20000.
10-8 <__ __ _- - v --4-0000.T __-----49 -,,'--_.
,p "-\ - - _ --70000.
_E -t) • -- 100000
c m --200000.Q) 9'_ 10-LE-- _/IB(u _- _ [] 500000.0
tDRecommended(19
+-' ---- Data0CK
10-1 - - Chebyshev Fit--
--
--
i0-_I _ i i,,,,,I , , , ,JJl,l. 4#-_.-I I,,,,,I I I I II[LL
i00 ld lot 103 104. 10sHe_'Te.mp. (..V)
, L(
_=2
_
=
_
=
A - 6 H
ABlsctron Capture Cross Sections for I
}le + ,t II2 -> He
Energy Velocity C_oss Section
(eV/amu) (cm/s) i_m2)
2.4E-03 6.81E+04 1.65E-18
7.0E-03 1.16E+05 1.20E-18
1.0E-02 1.39E+05 1.07E-18
4.0E-02 2.78E+05 6.66E-19
1.0E-01 4.39E+05 4.35E-19
4.0E-01 8.79E+05 1.89E-19
7.0E-OI ].16E+06 9.93E-20
1.0E+O0 1.39E+06 5.21E-20
].3E+O0 1.58E+06 4.40E-20
I.SE+00 1.70E+06 5.70E-20
3.0E+00 2.41E+06 2.15E-19
4.0E+00 2.78E+06 2.4]E-19
7.0E+O0 3.68E+06 2.65E-19
1.0E+01 4.39E+06 2.77E-19
4.0E+01 8.79E+06 5.03E-19
7.0E+01 I.]6E+07 1.13E-18
1.0E+02 1.39E+07 1.88E-18
4.0E+02 2.78E+07 I.]8E-17
7.0E+02 3.68E+07 2,46E-17
1.0E+03 4.39E+07 3.77E-17
4.0E+03 8.79E+07 1.42E-16
7.0E+03 1.16E+08 2.09E-16
1.0E+04 1.39E+08 2o42E-16
].6E+04 1.76E+08 2.69E-16
4.0E+04 2.78E+08 1.54E-16 U7.0E+04 3.70E+08 6.41E-17
].0E+05 4.39E+08 2.84E-17
4.0E405 8.78E+08 2.15E-19
7.0E+05 ].16E+09 1.35E-20
References! 7, 22, 82, 91,96, 97, 98, 99, I00, 101, 102, 103, 104, 105, 106, i07
_ccuracy: E < 2x103 eV/amu - unknown; E > 2x103 eV/amu - 20%
Notes= (i) The data between 40 - 2000 eV/amu have been interpolated
(2) The data of Moran and Conrads (Ref_ 107) are essentially independent of energy in
the 250 - 800 eV/amu region and are approximately a factor of I0 above the values shown.
(3) The low energy data ( E < 2x103 eV/amu) of Stedeford and Hasted(Ref. 82) are 1 to
2 orders of magnitude greater than the extrapolated data.
(4) The data below 2x103 eV/amu have large uncertainties
(5) In the experiments cited the He+ metastable state population is dependent on the ion
source used and the opera_tlng parameters of the source. As the metastable populationincreases the total cross section increases.
tor a Chebyshev fit of the above cross sections it is necessary to use the following parameters.
Eml n = 2.4E-03 eV/amu, Emsx = 7.0E+05 eV/amu
Che.q_he_sbevFitting Parameters for Cross Sections
AO AI A2 A3 A4 A5 A6 A7 A8
-81.9486 .720256 -.856412 -3.13728 -1.68226 .0267213 .0474764 3.15823E-03 .164787
The fit represents the above c_oss sections with an rms deviation of 34.8%.
The l,_aximumdeviation is 132.4% at 1.3E+00 eV/amu.
See appendix for Chebyshev fit details.
=
A-69
He+ + H2 ->l--le
_ °
Cross oectlonvs.Energy
A-7 0
Electron Capture Cross Sections for
He+ + lle -> He + He +
Energy Velocity Cross Section
eV/amu) (cm/s) (cm 2 )
4.0E-02 2,78E+05 3.32E-15
7.0E-02 3.68E+05 3.12E-15
1.0E-01 4.39E+05 2.97E'15
2.0E-01 6.21E+05 2.85E-15
4,0E-01 8.79E+05 2.64E-15
7.0E-01 1.16E+06 2,43E-15
1.0E+00 1.39E+06 2.31E-]5
2.0E+00 1.96E+06 2.i0E-15
4.0E+00 2.78E+06 1.96E-i5
7.0E+00 3.68E+06 1 83E-15
1.0E+01 4.39E+06 1.75E-15
2,0E+01 6.21E+06 1.54E-15
4.0E+01 8.79E+06 1.39E-15
7.0E+01 1.16E+07 1.31E-15
1.0E+02 1.39E+07 1.26E-15
2.0E+02 1.96E+07 1.lIE-15
4.0E+02 2.78E+07 9.87E-16
7.0E+02 3.68E+07 8.56E-16
1.0E+03 4.39E+07 7.92E-16
2.0E+03 6.21E+07 6.48E-16 ,_/
4.0E+03 8.79E+07 5.26E-i6 _W
7.0E+03 1.16E+08 4.22E-16
1.0E+04 1.39E+08 3.60E-16
2.0E+04 1.96E+08 2.36E-16
4.0E+04 2.78E+08 1.28E-16
7.0E+04 3.68E+08 5.58E-17
1.0E+05 4.39E+08 2.68E-17
2.0E+05 6.21E+08 5.49E-18
4.0E+05 8.78E+08 4.12E-19
5.3E+05 1.01E+09 1.08E-19
References: 91, 96, 97, 98, 99, 103, 104, 108, 109, Ii0, i]i, 112, 113, 114, 115, 116, 117,
118, 119, 120, 390, 397
J
Accuracy: 20% throughout the energy range
For a Chebyshev fit of the above cross sections it is necessary to use the following parameters.
Emi n = 4.0E-02 eV/amu, Ema x = 5.3E+05 eV/amu
Chebyshev Fittinq Parameters for Cross Sections
AO AI A2 A3 A4 A5 A6 A7 A8
-71.6915 -3.72702 -1.97026 -1.16040 -.605858 -.259050 -.0892322 -.0165873 9.75783E-03
The fit represents the above cross sections with an rms deviation of 2.4%.
The maximum deviation is 9.2% at 1.0E+05 eV/amu.
See appendix for Chebyshev fit details.
A-7]
+He -t- He -.," tqe + I-let
Cross Section vs, Energy
10-1_- _l l,_lUl I I i_mlr-'l--rrr_F-Tl 11roll I ,'rllu,I rrlTn111_-TnTml i i i,u_
10-15_ -'---_... __- "-_,... -_
- ,,,,N
E 10-'6 -
- t0
(/3
(/) 17cn 10- -O : Recornrnended
U - Data
...... Chebyshev Fit
10-_ _
10-I_-i iiiiiiiii illlllll_iiiiI ii iii!iiii LIIIJJJJ_.J_J_LLLI_IIII IIIIIIIII U
10.-2, 10-' 100 10' 102 103 104 10s 106Energy (eV/am u)
0
A-72
@Electron Capture Rate Coefficients for
lle+ + He -> }le + He +
Maxwellian - Maxwellian Rate Coefficisnts (cm3/s)
/
He+ /
Temp. Equal / lie Temp. (eV)
(eV) Temp. 1', I00. 500. 1000. 5000, i0000, 20000.
1.0E_00 2.66E-09 2.66E-09 1.12E-08 1,97E-08 2.44E-08 3.68E-08 4,]8E-08 4.51E-08
2.0E+00 3.45E-09 3,10E-09 ].]3E-08 1,97E-08 2.44E-08 3.68E, 0_ 4.18E-08 4.51E-08
4.0E+00 4,49E-09 3,75E-09 1,13E-08 1.97E-08 2.44E-08 3.68E-08 4,18E-08 4.51E-08
7.0E+00 5,54E-09 4.49E-'09 ],15E-08 1,97E-08 2.44E-08 3.68E,-08 4018E-08 4.51E-08
1,0E+01 6.30E-09 5.06E-09 1,16E-08 1.98E-08 2.44E-08 3,68E-08 4,18E-08 4.51E-08
2.0E+01 8.06E-09 6.42E-09 1,19E-08 1,99E-08 2.45E-08 3.68E-08 4.18E--08 4.51E-08
4.0E+01 1.03E-08 8.]3E-09 1.26E-08 2,0]E-08 2.47E-08 3.68E-08 4,18E-08 4.51E-08
7.0E+01 ].26E-08 9.87E-09 1,35E-08 2.05E-08 2.49E-08 3,69E-08 4,18E-08 4.51E-_8
1.0E+02 1.43E-08 1.12E-08 1.43E-08 2,08E-08 2.51E-08 3.69E-08 4.18E-08 4.51E-08
2.0E+02 ].82E-08 1.44E-08 1.65E-08 2.19E-08 2,57E-08 3.71E-08 4.19E-08 4.51E-08
4.0E+02 2.28E-08 1.83E-08 1,96E-08 2,36E-08 2.69E-08 3.74E-08 4,20E-08 4.51E-08
7.0E+02 2.69E-08 2.19E-08 2,28E-08 2.57E-08 2,83E-08 3.78E-08 4,22E-08 4.52EM08
1.0E+03 2.96E-08 2,44E-0B 2.51E-08 2.74E-0B 2.96E-08 3.82E-08 4.24E-08 4.52E-08
2.0E+03 3.50E-08 2.96E-08 2.99E-08 3.13E-08 3,27E-08 3.93E-08 4.29E-08 4.53E-08
4.0E+03 4.03E-08 3.50E-08 3,52E-08 3,59E-08 3.68E-08 4.11E-'08 4.37E-08 4.54E-08
7.0E+03 4.37E-08 3.93E-08 3.94E-08 3,98E-08 4.03E-08 4.29E-08 4.46E-08 4.55E-08
1.0E+04 4.51E-08 4,18E-08 4,18E-08 4.21E-08 4.24E-08 4,40E-08 4.51E-08 4.54E-08
2.0E+04 4.47E-08 4.51E-08 4,51E-0B 4,51E-0B 4.52E-08 4.55E-08 4.54E-08 4.47E-08
Notes: For Chebyshev fits of the above rate coefficients it is necessary to use the following parameters.
Emi n = 1.0E+00 eV, Ema x = 2.0E+04 eV
Chebyshev Fittin_ Parameters for R_te Coefficients
He
Temp.
(eV) A0 A1 A2 A3 A4 A5 A6
I. -3.65091E+01 1.50347E+00 -7,73477E-02 -8.34424E-02 -7.59297E-04 -3,17776E-03 2.46929E-03
i00. -3,55092E+01 7.61944E-01 1,84506E-01 -6.99606E.02 -4 58282E-02 5.01278E-03 6.02365E-03
500. -3.49239E+01 4.30514E-01 1.66682E-01 -1.76952E-03 -3 514441_:.-02 -].39113E-02 1.27578E-03
lO00. -3,46672E+01 3.07854E-01 1.38199E-0l 1.53048E-02 _2 27026E:,,,_92-1.52299E-02 -2.87864E-03
5000. -3.41193E+01 9.72499E-02 5,39119E-02 1,55767E-02 J_2 97046E-.03 -6.16891E-03 -3.80972E-03
10000. -3.39337E+01 3,94479E-02 2,21217E-02 6.22476E-03 -I 7_I04_E-03 -3.26193E-03 -2.26998E-03
20000. -3.38270E+01 1,35988E-03 -9,13724E-04 -2.77809E-03 -3 01978E-0[_-2,17733E-03 -1,25142E-03
Equal Temp. -3.62362E+01 1.48422Ee00 -1.94700E-01 -6.90443E-02 -i 94257E-02 -1.35547E-03 -2.79202E-03
See appendix for Chebyshev fit details.
A-73
4r.
t--le+ + I-le---> I--le .-t-.I--le
Ix,4clxwelliarnMaxwel!ian
71O- I _ I I I I III I _"_I171_1 t _ I _I _II1 _ ]--FFI-ITIT_T--T"T-'IT]'TI
bte l-e mp.
(eV)
- A --1.
- v -- 500.
"-_ _. , : - _ --looo,
0 8o • - 5000.
c@ a_ _ -- , • --I0000.'o 10- -
Lm - , []--20000.@0
O Recommendedqp-,-, --Datao
....... Chebyshev Fit'
Equal Femp.
1_-_-9 j_UaZ___L____L_L-Z_.;Ji,,l,__u_u-/</
100 ld 10_ 10_ 10_ 10_He+ Temp. (eV)
A-74
eElectron CaptUre Rate Coeffieients [or
He + He + -> }le + lie +
Beam- Maxwellian Rate Coefficients (cln3/s)
ile+
Temp. He Energy (eV/amu)
(eV) i0000. 20000. 40000. 70000. i00000. 200000, 400000.
1.0E+00 5.00E'08 4.63E-08 3.55E-08 2.05E-08 1.18E-08 3.41E-09' 3 61E-_0**
2.0E+00 5.00E-08 4.63E-08 3.55E-08 2.05E-08 i. 18E-08 3.40E-09' 3 62E-I0'*
4.0E+O0 5;00E-08 4.63E-08 3,55E-08 2.05E-08 1.18E-08 3.40E-09 * 3 61E-10**
7.0E+00 4.99E-08 4,63E-08 3.55E-08 2.05E-08 1.18E-08 3,40E-09' 3 61E-10**
1.0E+OI 4.99E-08 4,63E-08 3.55E-08 2.05E-08 i. 18E-08 3.40E-09' 3 61E-10**
2.0E+01 4.99F-08 4 62E-08 3.54E-08 2.05E-08 1.18E-08 3.40E-09' 3 61E-10**
4,0E+01 4.99E-08 4 62E-08 3.54E-08 2.04E-08 I,]8E-08 3 39E-09' 3.61E-I0 *_
7.0E+01 4,98E-08 4 61E-08 3,53E-08 2.04E-08 1.18E-08 3 39_,09' 3.61E-I0'*
1.0E+02 4.9BE-0B 4 61E-08 3.53E-08 2.04E-08 1.18E-08 3 38E-09' 3.60E-I0'*
2.0E+02 4.97E-08 4 60E-08 3.51E-08 2.03E-0B 1.17E-08 3 37E-09' 3.60E-I0'*
4.0E+02 4.95E-08 4 58E-08 3.50E-08 2,03E,,08 I,]7E.-08 3 36E-09' 3.60E-I0'*
7.0E+02 4.94E-08 4 57E-08 3.48E-08 2.02E-08 1.17E-08 3 34E-09' 3 59E-I0'*
1.0E+03 4.93E-08 4 55E-08 3.47E-08 2.02E-08 I.]8E-08 3 33E-09 3 59E-I0'*
2.0E+03 4.89E-08 4 52E-08 3.43E-08 2.01E-08 1.18E-08 3 31E-09 3 60E-10**
4.0E+03 4.83E-08 4 46E--08 3,38E-08 2,00E-08 ].IBE-0B 3 30E-09 3 62E-I0'*
7.0E+03 4,75E-08 4 39E-08 3.32E-08 1.99E-08 1.19E-08 3 29E-09 3 67E-I0'*
1.0E+04 4.6BE-08 4 31E-08 3.28E-08 1.98E-08 1.20E-08 3 30E-09 3 72E-I0'*
2.0E+04 4 48E-08 4 09E-08 3.13E-08 1.96E-08 1.22E-08 3 37E-09 3 91E-10*
Accuracy: * - Possible Error Greater Than 10%
• * - Possible Error Greater Than 100%
Notes: For Chebyshev fits of the above rate coefficients it is necessary to use the following parameters.
Eml n = 1.0E+00 eV, Ema x = 2.0E+04 eV
_hebyshev Fittinq Par_me_ Coefficients
He
Energy
(eV/amu) AO A1 A2 A3 A4 A5 A6
I0000 -3.36725E+01 -4.07805E-02 -2.43723E-02 -].21532E-02 -5.34881E-03 -2.01573E-03 -5 49929E-04
20000 -3.38300E+01 -4.55632E-02 -2.69923E-02 -1.37596E-02-6 60783E-03 -3.00454E-03 -i 25225E-03
40000 -3.43690E+01 -5.00191E-02 -2.61460E-02 -I.10247E-02 -4 45099E-03 -].92372E-03 -9 15345E-04
70000 -3.54336E+01 -2,00865E-02 -7.82001E-03 -2.03461E-03 -7 58265E-04 -7.02792E-04 -6 07996E-04
i00000 -3.65032E+01 1.22086E-02 1.00798E-02 5.919_4E-03 2 ]5183E-03 3.37849E-04 -2 72081E-04
200000 -3.90194E+01 -1.48944E-02 8.12695E-04 5.76317E-03 5 00317E-03 2.]9384E-03 1 07961E-03
400000 -4.34614E+01 2,08264E-02 2.00251E-02 1.46660E-02 7 48524E-03 3.55071E-03 7 ]6357E-04
See appendix for Chebyshev fit details.
0
He + He+ ->He + t-le+
Beclrn M .J_<,w@licin
1O- 7 I-'-r--T-FrT1Trl----T--r7-TTTllT-'-I-q-r'TT'r1Tr--T-T-FFTTrlT---T-r-I-I_ _ He E.nergy
- (eV/a rn u)_
n --I0000,_"--"---------_,_/
,< _--20000,
v -- 40000,
" - ' - _< -- 70000,
_E -o - - • -- 100 00 0-..._..,
rL'_ _ -I[] .... 200000,,-- }- ........... 4_
(...) -
_'- [] -- '$00000®C) ....
UQ) R eco rli rFIe rided
o 10-9 _ _ ------Dato
- - - Ctlebysllev P t
_. _ -
] O- 10__---.L__L..I-LU_LLI_..L.L i IJl iii __.i.__L_LiJ.JJil____i__L_LLLLLLL__.J__L_i_LLLLL
lo0 lO' ld lC):' icr lo'He+ Temp. (eV'.;)
Q
A-76
Elt_ct'.t'Ol_ Capture Cros_ Sections for /
lle "i. .i l+,i -> llo .I- [,i '+
Energy Velocity Cross+ Section
, (eV/alllU) (aln/t.]) (till2)
6,4E+01 ], liE+07 7.80E-I 6
1 .0E+02 1.39E.107 i. 53 E-] 5
2.0E+02 ].961+:+07 + 3.27E-]5
5,0E+02 3. ] IE+07 5.25E-15
8.0E+02 3.93E+07 5,61E-]5
I, 0E+03 4.39E407 5.60E-]5
2.0E+03 6.21E+07 5. ]2E-]5
4 0E+03 8.79E+07 4.17E-15
7 0E+03 ],16E+08 2.93E-15
1 0E+04 1,39E+08 1,76E-15
2,0E++04 ].96E+08 3.26E:16
2 5E+04 2.20E+08 1.33E-16
3 0E+04 2.41E+08 6.37E-17
4 0E+04 2.78E+08 4.]7E-17
5 0E'I'04 3.11E+08 3,42E-17
7.0E+04 3.68E+08 2.60E-17
]. 0E+05 4.39E+08 2.00E-17
Referencesz 230, 231, 232, 233, 234, 242
Acc.u racy : 30% @
__ For electron capture cross sections of Li + and Li 2+ in }le see references 249, 250, 251,254.
For a Chebyshev fit of the above cross sections it is necessary to use the following parameters.
Emi n = 6.4E+01 eV/amu, Ema x = 1.0E+05 eV/amu
Cheb_shev Fittln_ Parameters for Cross Sections
AO Al A2 A3 A4 A5 A6 A7 A8
-69.9420 -2.]7479 -1.90237 .}53408 .309985 .316010 .0848497 -.118385 -.140948
The fit represents the above cross sections withan rms deviation of 8.8%. +
The maximum deviation is 26.5% at 3.0E+04 eV/amu.
See appendix for Ci]ebyshev fit details.
A-77
0
He+ + Li->Ple + Li +
Cross Section vsoEnergy
'10-_ rr
,,, , ,, q '
A- 7U
Electron Capture l_ate CoefEiclents fo_
5i + lie + -> lie + Li +i
B,_am - _laxwellian Rate Coefficients (om3/s)
He +
Temp. [,i Energy (eV/ainU)
(eV) i0000. 20000. 30000. 40000, 60000, 80000, i00000,
!.OE+00 2.44E-07 6,38E-08' 1,54E-.08'* 1.16E-08_* 1,00E-08'* 9,26E-09'* 4,39E-09'*
2,0E+00 2,44E-07 6,38E-08' ],54E-08'* I_16E-08.* 1,00E-08.* 9,26E-09'* 4.39E-09'*
4,0E+00 2,43E-07 6,37E-08' 1,55E-08'* 1,16E-08'* 1.00_-08'* 9,26E-09'* 4.39E-09'*
7,0E+00 2,43E-07 6,35E-08' 1,55E-08'* I_16E-08,* 1 00E-08 *_ 9,26E-09'* 4.39E-09'*
1,0E+01 2,42E-07 6.35E-08' 1,55E-08'* 1,16E-08.* 1 00E-08** 9.26E-09 *_ 4,39E-09'*
2 0E+01 2,42E-07 6,32E-08' 1,56E-08'* 1.16E-08'* i 00E-08'* 9,26E-09'* 4,38E-09 **
4 0E+01 2 40E.-07 6,30E-08' 1,58E-08'* 1.16E-08'* 1 00E-08** 9,26E-09'* 4.38E-09. "
7 0E+01 2 39E-07 6.27E-08' 1,59E-U8** 1.17E-08'* 1 00E-08** 9,26E-09'* 4.38E-09'*
1 0E+02 2 38E-07 6,25E_08' 1.60E-08'* 1,17E-08w* 100E..08** 9,26E-09'* 4.37E-09'*
2 0E,_02 2 361::-07 6.22E-08 & 1.64E-08'* 1.17E-08'* 1 00E-08** 9,26E-09'* 4,36E-09'*
4 0E+02 2 341_:-07 6.19E-08' 1,70E-08'* 1.18E-08'* 1 00E-08** 9,26E-09'* 4.35E-09'*
70E+02 2 3]_-07 6,19E-08' 1,77E-08' 1.19E-08.* ].00E-08** 9,26E-09'* 4,34E-09'*
1.0E+03 2 2_,E-07 6.22E-08' 1,83E-08' 1,19E-08'* 1,00E-08** 9,24E-09'* 4.33E-09'*
2,0E+03 2,2]E-07 6,38E-08" 2.03E-08' i 22E-08 ** 1.00E-08** 9,09E-09'* 4,30E-09'*
4.0E.t03 2,0',E-07 6,77E-08' 2,36E-08' ].31E-08'* 1.01E-08** 8,59E-09'* 4.26E-09'*
7.0E+03 ],93E-07 7,22E-08 2.78E-08' 1.48E-08' 1.01E-08** 7,97E-09'* 4.22E-09'*
1.0E+04 1.80E.07 7,48E-08 3.14E_-08 * 1.66E-08' 1.01E-08** 7,54E-09'* 4.]8E-09'*
2,0E+04 1.50E-07 7.63E-08 3.93E-08' 2.22E-08' 1,08E-08 *_ 6,91E-09'* 4.]3E-09'*
Accuracy_ * -Possible Error Greater Than 10%
• * - Possible Error Greater Than 100%
Notes: For Chebyshev fits of the above rate coefficients lt is necessary to use the following parameters.
Eml n = 1.0E+00 eV, Emc x = 2.0E+04 eV
Ch___ebyshev Fitting Parameters for Rate CoefficientsLl
Energy
(eV/amu) A0 AI A2 A3 A4 A5 A6
10000 -3.06784E+01 -1.83367E-01 -l.08562E-0t -5.42037E-02 -2.28601E-.02 -6.74194E-03 -2.90887E-04
20000 -3,30630E+01 7.50860E-02 6.65545E-02 2.87114E-0_ -2.24836E-03 -1.23958E-02 -I,01177E-02
30000 -3.54800E+01 4.01173E-0] 2.16479E-01 7.71491E-02 1.07563E-02 -8.06147E,-03 -8.04622E-03
40000 -3.62976E+01 2.]8893E-01 1.57718E-01 9.39441E-02 4.47005E-02 ].42990E-02 -8.03805E-04
60000 --3.68192E+01 1.63206E-02 1,40921E-02 ].21589E-02 9.29880E-03 6.22735E-03 4,24079E-03
80000 -3,71186E+0]-I.09657E-01 -8,05414E-02 -4.26549E-02 -1.26465E-02 3,1826]E-03 7,94923E-03
100000. -3.85227E+01 -2.71037E-02 -].31775E-02 -4.13455E-03 -5.05274E-04 3.90860E-04 4,43525E-04
See appendix for Chebyshev fit details,
0
Li + He+ ->He + L.i+
Beam-- Ivlaxwellicln
10-9 1i m.u_o° ld ld _8 ld 18
He+ Temp. (eV)
Q
A- [10
A£]loctron CaptUre Cross ,_;eations for W
lie + ,t lie + -> tie + tie 2+
l;nergy . Velocity Cross Section
( eV/ainu ) (cm/s), (cre2 )
1.5_+04 1 70E+08 1,95E-18
2.bB+04 1 96F:+08 3.25E-18
3.0E+04 2 41E+08 6.28_-18
4 0E+04 2 7_E+08 9.44E-18
50E+04 3 11E+08 1.228--17
6 0E+04 3 40E+08 1 45E-17
7 0E+04 3 68_+08 I 648-17
90E+04 4.17E+08 1 _(JE-17
i 0E+05 4.39E+08 1 90_-17
1 5E._05 5.38E+08 1 73E-17
2 0E+05 6.21E+08 i 428-17
2 38+05 6.66E+08 I 24E-17
References= 69, 277, 278, 283, 284
Accura?._j 20%,_.-..-_..
Note....__/=(l) Good agreement of the experimental data exists with the theoretical data of Ref.284.
0For a Chebyshev fit of the above cross sectlon9 lt is necessary to use the following parameters,
Eml n = 1.5E+04 eV/amu, Ema x = 2.3E+05 eV/amu
Cheb_he_-P-A/-_I_ete_s _gr Cross Sec_tIQn_
A0 A1 A2 A3 A4 A5 A6 A7 A8
-78.6559 .981266 -,533866 -.0667013 .0133417 .00898626 .00154609 .00128923 -.00693562
The fit represents the above cross sections with an rms deviation of 0.3%.
The maximum deviation is 0,6% at 1,0E+05 eV/amu.
See appendix for Chebyshev fit details.
A-81
+ _ He2+He+ + He > He +
Cross Section vsoFner-gy
10-'_ ] I I I T-T--T-TI I [ r _ _ _ RF-
n
c0 17(..; /k./
(./') -
(]') -
[./')0 - - Recommended
U - --Data
- ' Chebyshev Fit
I0 -II ..... I I L. I I I I li I I I ,I,,, i i ii
io• 1o_ 1o_Energy (.eV/am l.l)
A-82
Electron Capture Rate Coefficients for @
He + + He + -> He + He 2+
Maxwel]ian - Maxweliian Rate Coefficients (cm3/s)
lie+
Temp. Equal He + Temp. (eV)
(eV) Temp. 10000. 12000. 14000. 16000, 18000. 20000, 25000.
4.0E+03 8,29E-13 2.06E-II 3.60E-II 5_61E-II 8.08E-II 1.10E-10 1.43E-I0 2.40E-10
6.0E+03 9.94E-12 3.60E-II 5.61E-II 8.08E-II 1.10E-10 1.43E-I0 1.79E-I0 2.85E-I0
8.0E+03 3.60E-II 5.61E-II 8.08E-II 1.10E-10 1.43E-10 1,79E-10 2.19E-I0 3.32E-I0
1.0E+04 8.08E-II 8.08E-II 1.10E-10 1.43E-I0 1.79E-I0 2.19E-I0 2.62E-I0 3.81E-10
1.2E+04 1.43E-I0 1.10E-10 1.43E-I0 1.79E-I0 2.]9E-I0 2.62E-I0 3.08E-I0 4.33E-I0
1.4E+04 2.19E-I0 1.43E-I0 1.79E-I0 2.19E-10 2.62E-I0 3.08E-I0 3.56E-I0 4.87E-I0
1.6E+04 3.08E-I0 1.79E-I0 2.19E-i0 2.62E-10 3.08E-I0 3.56E-I0 4,07E-I0 5.42E-I0
1.8E+04 4.07E-I0 2.19E-I0 2.62E-I0 3.08E-I0 3.56E-I0 4.07E-I0 4.60E-I0 5.99E-I0
2.0E+04 5.14E-I0 2.62E-10 3.08E-I0 3.56E-I0 4,07E-I0 4.60E-10 5.14E-I0 6.58E-I0
2.2E+04 6.28E-I0 3.08E-10 3.56E-10 4.07E-10 4.60E-I0 5.14E-10 5.71E-I0 7.18E-10
2.4E+04 7.49E-I0 3.56E-10 4.07E-I0 4.60E-10 5.14E-I0 5.71E-I0 6.28E-I0 7,80E-10
Notes: For Chebyshev fits of the above rat_ coefficients it is necessary to use the following parameters.
Emi n = 4.0E+03 eV_ Ema x = 2.4E+04 eV
Chebyshev Fittinq Parameters for Rate Coefficients @
He +
Temp.
(eV) AO AI A2 A3 A4 A5 A6
10000. -4.64541E+01 1.43962E+00 4,630300-02 -1.49060E-02 -2.30149E-04 2.44855E-04 -4.28539E-05
12000. -4,57963E+01 1.22412E+00 6.31757E-02 -i.13559E-02 -6.21329E-04 1,52187E-04 1.97060E-04
14000. -4.52461E+01 1.05998E+00 7.17125E-02 -8,34828E-03 -9.77820E-04 2.30920E-04 -9,51457E-06
16000. -4.47759E+01 9.31470E-01 7.53759E-02 -5.93773E-03 -I,18832E-03 1.95011E-04 -1.89337E-04
18000.-4.43672E+01 8.285_8E-01 7.61027E-02 -4,06263E-03 -1.22968E-03 -1.52699E-05 -1.37761E--04
20000. -4.40069E+01 7,44390E-01 7.51176E-02 -2.63629E-03 -I.17745E-03 -2.47636E-04 7.54863E-05
25000. -4.32601E+01 5.B8552E-01 7.03846E-02 -1.20370E-04 -I.13108E-03 1.84062E-04 -1.45794E.-04
Equal Temp. -4.76973E+01 3.30679E+00 -5.53811E-01 9.53225E-02 -1.30960E-02 6,76109E-04 1.60674E-04
Se_ appendix for Chebyshev fit details.
=
A-83
He* + I-fie*--> He -t- I---te_*
Maxwellian- Mclxwellion
A-84
A
Partial and Total Electron Capture Cross Sections for Q
He 2+ + He + -> He + 4 He 2+
(Part ial) (Total)
}le+ Energy Cross _ection He + Energy Cross _ectioneV/ainu cre- eV/ainu cm
7.0E+00 3.04E-17 8 5E+00 3.39E-16
1.0E+01 4.02E--17 1 0E+01 4.09E-16
1.5E+01 7.57E-17 1 5E+0] 6.01E-16
2.0E+01 2.00E-16 2 0E+01 6.99E-162.5E+01 2.98E-]6 4 0E+0] 7.77E-16
3.0E+01 3.48E-16 7 0E+01 7.80E-16
4.0E+01 4.04E-16 ] 0E+02 7.66E-16
6.0E401 4.45E-16 2 0E+02 7.16E-16
7.0E+01 4.55E-16 4 0E+02 6.64E-16
1.0E+02 . 4.79E-16 7 0E+02 6.13E-162,0E+02 4.84E-16 1.0E+03 5.75E-16
4.0E+02 4.64E-16 2.0E+03 5.01E-16
7.0E+02 4.38E-16 4.0E+03 4.30E-16
1.0E+03 4.19E-16 7.0E+03 3.76E-162.0E+03 3.76E-16 1.0E+04 3.23E-16
4.0E+03 3.28E-16 2.0E+04 2.03E-16
7.0E+03 2.83E-16 4.0E+04 1.01E-16
1.0E+04_ 2.52E-16 7.0E+04 4.50E-171.6E+04 2.07E-16 1.0E+05 2.65E-17
1.5E+05 1.33E-17
2.0E+05 6.34E-18
2.5E+05 2.83E-183.0E+05 ].27E-18
References: 69, 288, 391, 392, 393
Accuracy: unknownJ
Notes: _ In O
+(i the measurements a problem arises from the mutual repulsion between the He + andHe . The repulsion results in scattering with some of the ions not reaching thedetector which has a finite acceptance angle. These measurements are termed partialcross sections.
(2) The total cross section data____$_h from theoretical values in _ef. 28_ and 391. Thetheoretlcal data has been joined a smooth curve between 6x10 J and i0 eV/amu.(3) For this simple one electron, resonant system, the theoretical data should beaccurate to within 20%.
FOr Chebyshev fits of £he above cross sections it _s necessary to use the following parameters.
(Partial) Emi n = 7.lE+00 eV/amu, Ema x = 1.6E+04 eV/amu
(Total) Emi n 8.5E+00 eV/amu, Ema x 3.0E+05 eV/amu
Chebyshev Fittinq Parameters for Cross Sections
AO Al A2 A3 A4 A5 A6 A7 AB
(Partial) -72.2134 .725003 -1.00558 .400]48 -.150634 -.0556029 .119500 -.118086 .0830868
(Total) -72.8308 -2.29484 -1.54555 -.441776 -.328931 -.00327441 -.0709033 -.0333345 -.0595299
The fit represents the partial cross section with an rms deviation of 7.4%.The maximum deviation is 25.2% at I.SE+0I eV/amu.
The fit represents the total cross section with an rms deviation of 2.8%.The maximum deviation is 5.6% at 7.0E+04 eV/amu.
See appendix for Ch(,byshev fit details.
• -
A-85
®
He_+ + He+ ->Ht; + + He_+
Cross Sectionvs. Energy
....... _I_ ........... _I IIIL,
A-86
@Single Electron Capture Cross Sections for
He 2+ + H--> _He+ + H
lle+ + H- i> He + i|
He 2+ _ II" lie+ + |l-
Energy Cross Section Energy Cross Section
eV/ainu cm 2 eV/ainu cm 2
k
4.7E-01 1.82E-13 4.2E+01 3.03E-14
5.0E-01 1.71E-I_ 5.0E+01 2.18E-146.0E-01 1.52E-13 6.0E+01 1.83E-148.0E-01 1.30E-13 7.0E+01 1.66E-14
1.0E+00 I_I'7E-13 8.0E+O! 1.56E-142.0E+00 8.90E-14 1.0E+02 1.46E-14
3.0E+00 7.78E-14 1.5E+02 1.40E-144.0E+00 7.i3E-14 2.0E+02 1.37E-146.0E+00 6.44E-14 3.0E+02 1.32E-148.0E+00 6.01E-14 4.0E+02 1.30E-141.0E+01 5.79E-14 5.0E+02 1.28E,142.0E+01 5.31E-14 7.0E+02 1.24E-14
3.0E+01 5.08E-14 1.0E+03 1.19E-145.0E+01 4.77E-14 2.0E+03 9.78E-158.0E+01 4.55E-14 3.0E+03 7.89E-151.0E+02 4.43E-14 4.0E+03 6.06E-15
2.0E+02 4.12E-14 ' 5.0E+03 4.40E-154.0E+02 3.73E-14 7.0E+03 2.43E-157.0E+02 3.44E-14 7.7E+03 2.01E-151.OEr03 3.22E-.142.0E+03 2.79E-143.0E+03 2.50E-14
References: (He + 4 H-) 68, 292, 293, 394 ; (He 2+ + H-) 69, 290, 291, 294
Accuracy: (He+ + H-) - 20%; (He2. + H-) - 40% i
Notes: (i) In the energy region of overlap, the He 2+ + H- cross sections of Terao et al (re|.
290, 291) are consistently greater than those of the Dolder and Peart group (re|. 69,
294).E
(2) The measurements indicate some structure in the cross sections for both the He+ and
He 2+ reactions. This oscillation has been smoothed out in the data presented here. L
For Chebyshev fits of the above cross sections it is necessary to use the following Parameters.
(He 2+ + H-) Eml n = 4.7E-01 eV/amu, Ema x = 3.0E+03 eV/amu
(}le+ + H-) Eml n = 4.2E+01 eV/ainu, Ema x = 7.7E+03 eV/ainu
=
Cheb__yshev Fitting Parameters for Cross Sections
AO AI A2 A2 A4 A5 A6 A7 A8
(He 2+ + H-) -61.0067 -.855510 .155087 -.126012 .0124474 -6.60133E-04 -4.30771E-04 -.00636246 .00615254
(He+ + H-) _ -64.4915 -.959186 -.269411 -.331423 -.00745857 -.0611579 .0257220 -.00396428 .0113568
The fit represents the He 2"_ + H- cross section with an rms deviation of 0.4%.
The maximum de_/iation is 0.8% at 5.0E-01 eV/ainu.
The fit represents the Ee + _ H- cross sect:ion w_th an rms d_.v[al],,n of 0.6%.
The maxlmum deviation is ].2% at ].0El02 eV/_,i,u.
See appendix for Chebyshev fit detal]s. @ _
A-87
Heq+ 4- H- ->He (q-D+ + H (q-1,2)
Cross Section VSoEnergy
Chebyshev Fit10-12
10-1 100 ld 102 10s 104Energy (eV/am@
0
A-88
Electron Capture Cross Sections for
He 2+ + H -> He + + H +_
Energy Velocity Cross Section
(eV/amu) (cm/s) (em 2)
7.0E+01 ].16E+07 ].25E-20
1.0E+02 1.39E+07 2.2OE-19
2 0E+02 1.96E+07 3.10E-18
4.0E+02 2.78E+07 1.90E-17
5.0E+02 3.:IIE+07 3,24E-17
7'0E+02 3.68E+07 8.67E-17
1.0E+03 4.39E+07 1.87E-16
2.0E+03 6.21E,07 5,96E-16
4.0E+03 8.79E+07 9.74E-16
7.0E+03 1.16E+08 1.18E--15
1.0E+04 1.39E+08 1.22E-15
2.0E+04 1.96E+08 1.09E-15
4.0E+04 2.78E+08 5.28E-]6
7.0E+04 3.68E+08 1.59E-16
1.0E+05 4.39E+08 5.23E-17
2.0E+05 6.2]E+08 4.63E-18
4.0E+05 8.78E+08 2.64E-19
5.0E+05 9.82E+08 I.]5E-19
QReferences_5, 7, 21, 22, 23, 24,' 25, 57, 58
Accuracy: He 2+ E < 600 eV/amu - unknown; He 2+ E _ 600 eV/amu - 20%
(i) At energies less than 2 keV/amu the rest!its of Fite et al. (Ref. 5) and Nutt et
al. (Ref. 23) diverge by as much as a factor of iO. This is believed to be due to
the fact that the results reported by Fite et al. were obtained by measuring the slow ions
produced in the collision, and are less reliable than those of Nutt et al at low energies.
(2) No experimental data exist below 500 eV/amu. Cross sections below 500 eV/amu were
taken from calculations of Ref. 57 and 58 using multi-state close coupling methods.
For a Chebyshev fit of the above cross sections it is necessary to use the following parameters.
Eml n = 7.0E+01 eV/ainu, Ema x = 5.0E+05 eV/ainu
Chebyshev Fitting Parameters for Cross Section_ r
_0 Al A2 A3 A4 A5 A6 A7 A8
-78.3976 .773499 -5.]2346 -.125575 -.232331 .26]3]7 -.0479652 .]89434 -.138708 _
The _it represents the above cro_ sections with an rms deviation of 3.9%.
The maximum deviation is 7.6% at 5._0E+02 eV/amu.
See appendix for Chebyshev fit details.
A-89
He_+ + H--.'> He+ -t- H+
ct_C'+ICross .___.,,onvso FZrlergyi
lO-14------T"_',l,l,lll , _ I,l,lll I_ I ,1,,,11 -l-_'rl11111 _--rTT'r_
10-__
", Z
10-I__
O ..., _ _-
010-17="
(I.)(_ _
O0'
LO Reco,-nmended
U 10-18_ "---- Dato
Chebyshev Fit,
i0--_9 _ _
10 -2( ..... 1 i lJliill _ 1 l iilllll l l llillll i t ili'llll J i lill'll
ld, lo: _o_ lo" lo_ lo_Energy (eV/a m u)
II
A-90
Electron Capture Rate Coefficients foe O
He 2+ + H -> He + + H +
Ma×we]fian - Maxwellian Rate Coefficients (cm3/s)
He2+
TemP. Equal }I Temp. (eV)
(eV) Temp. i0. i00. 500. I000. 5000. 100D0. 20000.
2.0E+01 6.28E-13 4.12E-14 1.22E-I0 7.36E-09 2.36E-08 1.14E-07 1,47E-07 1.42E-07
4.0E+01 1.04E-II 2,09E-13 1.42E-I0 7.50E.-09 2.38E-0B ].14E-07 1.47E-07 1.42E-07
7.0E+01 6.86E-II 9.71E-13 1.74E-I0 7.72E-09 2.40E-08 I,]4E-07 1.47E-07 1,42E-07
1.0E+02 2.10E-10 2.70E-12 2.10E-10 7.94E-09 2.43E-08 ].14E-07 1.47E-07 1.42E-D7
2.0E+02 i. 49E-09 i. 97E-II 3.63E-ID 8.68E-09 2.51E-08 1.14E-07 1.47E-07 1.42E-07
4.0E+02 7.21E-09 1.42E-I0 8.23E-I0 1.02E-D8 2.68E-08 ].15E-07 1.47E-07 1.42E-07
7.0E+02 i. 92E-08 6.63E-ID I. 89F-09 1.26E-08 2.93E-D8 ]. 16E-07 i. 47E-07 i. 42E-07
1.0E+03 3.18E-08 1.65E.-09 3.37E-09 1.50E-08 3.18E-D8 ].17E-07 1.47E-07 1.42E-07
2.0E-103 6.80E-08 7.50E-09 1,02E-08 2.34E-0B 3.99E-08 I.]_E-07 1.48E-07 1.41E-07
4.0E+03 !.13E-07 2.3BE-08 2,68E-08 3.99E-08 5.48E-08 ].25E-OY 1.49E-07 1.40E-07
7.0E+03 1.43E-07 4.78E-08 5.05E-08 6.16E-08 7.40E-08 1,31E-07 1.49E-07 1.39E-07
1.0E+04 1.50E-07 6.83E-08 7.05E-D8 7.97E-08 8,98E-08 1.36E-07 1.50E-D7 1.37E-07
2.0E+04 1.32E-07 1.14E-07 1.15E-07 1,19E-07 1.25E-07 1.47E-07 1.49E-07 1.32E-D7
Notes: For ChebysheV fits of the above rate coefficients it is necessary to use the following parameters.
Emi n = 2.0E+01 eV, Ema x = 2.0E+04 eV O
.Chebyshev Fittill 9 Parameters for Rate CoefficientsH
Temp.
(eV) AO AI A2 A3 A4 A5 A6
i0 -4.49742E+01 7.78326E+00 -1.00928E+00 -3.95746E-01 8.29111E-02 3.18952E-02 5.49793E-03
i00 -3.94867E+01 3.76780E+00 4.07631E-01 -4.05432E-01 -7.75944E-02 6.09541E-02 1.07817E-02
500 -3.54181E+01 1.44543E+00 4.43041E-01 -3.74033E-02 -7.53578E-02 -1.52405E-02 7.25877E-03
i000 -3.40218E+01 8.22262E-01 3.]9564E-01 2.78648E-02 -3.66721E-02 -1.86208E-02 -1.77688E-03
5000 -3.18356E+01 1.16105E-01 5,74535E-02 1.52669E-02 -].09084E-03 -3.2@086E-03 -1,76834E-03
I0000 -3.14549E+01 I.]2080E-02 3.75806E-03 -I,00216E-03 -2.02657E-03 -1.36406E-03 -6.16274E-04
20000 -3.15643E+01 -2.69513E-02 -1.69052E-02 -8.31717E-03 -3.31404E-03 -I.08242E-03 -2.94451E-04
Equal Temp, -3.99202E+01 6.04131E+00 -1.99447E+00 9.39512E-02 1.34081E-02 -1.22695E-02 -2.34071E-02
See appendix for Chebyshev fit details.
• •
A-91
i
He_* + H-> He* + H*
M(" # ':_xwellimn- Maxwe,ian
^-9_
, •Electron Capture RaEe Coefficients for
II + lle2+ -> He + + H +
Beam - Maxwellian Rate Coefficients (cm3/s)
He 2+
Temp. H Energy (eV/amu)
(eV) I0000, 20000. 4O0O0. 70O00. 100000. 200000. 4OO0O0.
1.0E+00 1 69E-07 2 14E-07 1.46E-07 5,84E-08 2.30E-08 2.88E-09' 2.32E-I0'*
2.0E+00 1,69E-07 2 14E-07 1.46E-07 5.83E-08 2.30E-08 2.87E-09' 2.32E-I0'*
4.0E+00 1,69E-07 2 13E-07 1.46E-07 5.83E-08 2.30E-08 2.87E-09' 2.32E'I0'*
7.0E+00 1.69E-07 2 13E-07 1.46E-07 5.83E-08 2.30E-08 2,87E-09' 2.32E-I0 *_
1.0E+01 1 69E-07 2 13E-07 1.46E-07 5.82E-08 2.30E_08 2.87E-09" 2.32E-I0'*
2,0E+01 1 69E-07 2 12E-07 1.46E-07 5.82E-08 2.29E-08 2 87E-09' 2;32E-i0'*
4.0E+01 1 69E-07 2 12E-07 1.45E-07 5.81E-08 2.29E-08 2.87E-09' 2,32E-I0 *_
7,0E+01 1 69E-07 2 lIE-07 1.45E-07 5.80E-08 2.29E-08 2.87E-09' 2.32E-I0'*
1,0E.02 1 68E-07 2.10E-07 1.44E-07 5 79E-08 2.29E-08 2.87E-.09' 2.32E-I0_*
2.0E+02 i 68E-07 2.09E-07 1.44E-07 5,77E-08 2.29E-08 2.87E-09' 2.33E-I0'*
4,0E+02 1 68E-07 2.07E-07 1.42E-07 5.75E-08 2.30E-08 2.87E-09' 2.33E-I0"*
7.0E+02 1 68E-07 2.04E-07 1.41E-07 5.73E-08 2.30E-08 2.87E-.09" 2.34E-I0'*
1,0E+03 1,67E-07 2.03E-07 1.40E-07 5.72E-08 2.31E-08 2.87E-09" 2.35E-I0'*
2.0E+03 1.67E-07 1 98E-07 1.38E-07 5.71E-08 2.34E-08 2.89E-09" 2.37E-I0'*
4.0E+03 1.67E-07 1.92E-07 1.35E-07 5.74E-08 2.40E-08 2.94E-09 2.41E-I0'*
7.0E+03 1,66E-07 1.84E-07 1.32E_07 5,79E-08 2.48E-08 3 02E-09 2.46E-I0'*
1.0E+04 1.65E-07 1.78E-07 1.29E-07 5.85E-08 2.56E-08 3.10E-09 2.50E-I0'* I
2.0E+04 1,61E-07 1,62E-07 ].20E-07 5.95E-08 2.79E-08 3.45E-U9 2.65E.-I0'* '_
Accuracy: * - Possible Error Greater Than 10%
• * - Possible Error Greater Than 100%
Notes: For Chebyshev fits of the above rate coefficients it is necessary to use the following parameters.
Emi n = i.0E+00 eV, Ema x 2.0E+04 eV
Cbebyshev Fitting Parameters for Rate Coefficients
H
Energy
(eV/amu) AO AI A2 A3 A4 A5 A6
10000. -3.12062E+01 -1.74693E-02 -8.09939E+03 -4.73707E-03 -3.77313E-03 -2.52573E-03 -I.15127E-03
20000. -3.08555E+01 -I.09982E-01 -5.81296E-02 -2,43325E-02 -9.22165E-03 -3,45740E-03 -1,26420E-03
40000. -3.15751E+01 -7.97019E-02 -4.01409E-02 -1.65010E-02 -6.97466E-03 -3.39246E-03 -1.78170E-03
70000. -3.33202E+01 3.45964E-04 1.03619E-02 9,]6031E-03 3.80511E-03 1.91641E-04 -I,02574E-03
i00000. -3.51051E+01 6.70775E'-02 4.92944E-02 2.76338E-02 1,12857E-02 2.98288E-03 1.23487E-05
200000. -3.92776E+01 5.41764E-02 4.43066E-02 2.88380E-02 1,56821E-02 6.68430E-03 2.77948E-03
400000. -4.43133E+01 4.82448E-02 3.15762E-02 1.67996E-02 7.00532E-03 2.7556_E-03 5. _4833E-04
See appendix for Chebyshev fit details.
Q
A-93
O
H + He_* ->He* + H*
,,
,,
Beam - MQxwelliGn
i0 6 _ 1 I I I IIIIJ 1 I I IIIliJ " 1 I' '1 IlillJ '1 I' I IIIIIJ I, I I I II1_
- - H Energy
- - (eV/o m u)
-- 10000."_
x --20000.
10-7_ _ _l i v 40000._ ' X -
, (J_ --
":'-. - - _ --70000.
O _E - _ -o ) • -- 100000.
Cqp m --200000'o 10-8 - - 'o-_
_- - [] --400000.OU -
_.-4_ Recommendedo _Data
El/
10-9 _Chebyshev Fit
4
!
,,,,,,, , J iJiJill i i iliill,I i i ili]ld l 1 I lllll
100. 10' 10_ 103 10" 10sHe2+ Temp. (eV)
Q
A-94
Electron Capture Cross Sections for
He 2+ + H 2 -> He +
Energy Velocity Cross Section
(eV/amu) (cm/s) (cm2)
1.4E_02 1.64E+07 3.70E-17
1.7E+02 1.81E+07 5.83E-17
2.0E+02 1.96E+07 7.31E-17
2.6E+02 2.24E+07 8.77E-17
4.0E+02 2.78E+07 1.07E-16
7.0E+02 3,68E+07 1.32E-16
1.0E+03 4.39E+07 1.52E-16
2.0E+03 6.21E+07 2.20E_16 _
4.0E+03 8.79E+07 4.12E-16
7.0E403 1.16E+08 6.41E-16
1.0E+04 1,39E+08 8.01E-16
2.0E+04 1.96E+08 1.07E-15
4.0E+04 2.78E+08 7.23E-16
7.0E+04 3.68E+08 3.13E-16
1.0E+05 4.39E+08 1.39E-16
2.0E+05 6.21E+08 1.46E-17
4.0E+05 8.78E+08 1.02E-18
7.0E+05 1.16E+09 9.04E-20
1.0E+06 !.39E+09 1.63E-20
References: 7, 22, 23 24, 90, 91, 92 93, 94, 95, !01, 142
Accuracy.: 20%
For a Chebyshev fit of the above cross sections it is necessary to use the following parameters.
Emi n = 1.4E+02 eV/amu, Ema x = 1.0E+06 eV/amu
Chebyshev Fitting Parameters for Cross Sections
AO AI A2 A3 A4 A5 A6 A7 A8
-76.3856 -3.05275 -3.46462 -1.13751 .0656712 .340604 -.0614851 -.0248706 -.0398477
The fit represents £he above cross sections with an rms deviation of 2.2%.
The maximum deviation is 4.1% at 2.0E+03 eV/amu.
See appendix for Chebyshev fit details.
r
A-95
Q
Pie2+ + H2 -> He+
Cross Section vs. Energy
10 -14" ,
I i I I i lllr I i I r-lllll I i i i i Jill l '-i i i llli_-
'
10-,5_
i'
10-16IN '
E
C
o 10_17LP
b0O0O0
0 Recommended
U 10-18. _Data
...... Chebyshev Fit
lO-'g_=-
4rC 2( i i i,li,lii i i i i iilll I I I llilll ! I i i illl1%/
102 103 104 10s 06Energy (cV/amu)
®
A-96
Double Electron Capture Cross Sections for
He 2+ + H 2 -> He + 2H +
Energy Velocity Cross Section
(eV/amu ) (cm/s) (cm 2 )
3.qE+02 2.41E+07 3.68E-17
4.6E+02 2.78E+07 6.05E-17
5.6E+02 3.29E+07 7.02E-17
7.0E+02 3.68E+07 6.63E-17
1.0E+03 4.39E+D7 4.70E-17
2.0E+03 6.21E+07 1.34E-17
2.7E+03 7.22E+07 1.20E-17
4.0E+03 8.79E+07 1.56E-17
7.0E+03 1.16E+08 2.75E-17
1.0E+04 1.39E+08 3.74E-17
2.0E+04 ].96E+08 5.51E-17
2.3E+04 2.11E+08 5.71E-17
4.0E+04 2.78E+08 3.84E-17
7.0E+04 3.68E+08 9.91E-18
1.0E+05 4.39E+08 3,33E-18
2.0E+05 6.21E+08 1.62E..19
3.7E+05 8.45E+08 3°88E-21
References: '7, 22, 27, 90, 91, 92, 93, 94, 95
Accuracqy_[ E < 2.5xi03 eV/amu - unknown; 2.5xi03 eV/amu < E < ixlO 5 eV/amu - 40%; E > ixl05 Q
eV/amu - 50%
I For a Chebyshev fit of the above cross sections it is necessary to use the following parameters.
Eml n = 3.0E+02 eV/amu, Ema x = 3.7E+05 eV/amu
Chebvshev Fittinq Parameters for Cross Sections
AO AI A2 A3 A4 A5 A6 A7 A8
-79.5999 -3.55036 -2.20554 -1.45406 -.357248 .498461 -.146918 -.0680202 .0918861
The fit represents the above cross sections with an rms deviation of 6,8%.
The maximum deviation is 12.8% at 2.0E+03 eV/amu.
See appendix for Chebyshev fit details.
A-9"7
' , He_+ + H2 ->He + 2H+
Cross Section vs. Energy
10_16- , v i llvlt I J" t _vvvll I I t' t'vl,vvv I i li vIn_
10-'__
lE 10-1__
0 - .
Q) - .
(1)
m 10- -,0 , : : Recommended
U " . _- Datam
m ,,,4
,
Chebyshev Fit
ld 2'_5
t
,i0-2_..... , , i i i l lll i i i ! i i ill i I i i i i l.ll i i,. i i ,
ld 103 ' 10' 10_ 106Energy (eV/om u)
A-98
AElectron Capture CL'oss Sections for I
lie 2+ + Ilo -> tle + 4, lie +
Energy Veloelty Cross Section
(eV/amu) (am/s) (cm 2)
2.4E-04 2.15E+04 1.19E-18
4.0E-04 2.78E+04 9.33E-19
1.08-03 4.39E+04 5.95E-19
4.0E-03 8.79E+04 3,01E-19
].0E-02 1.39E+05 1,90E-19
4.0E-02 2.78E+05 8.18E-20
].0E-01 4.39E+05 5.26E-20
4.0E-01 8.79E+05 3.05E-20
7.0E-01 1,16E+06 2.54E-20
1.0E+00 1.39E+06 2.29E-20
1.6E+00 1.76E+06 2.21E-20
4.0E+00 2.78E+06 3°66E-20
].0E+01 4.39E+06 ].07E-19
4.0E+01 8.79E+06 5.]5E-19
1.0E+02 ].39E+07 1.44E-18
4.0E+02 2.78E+07 6.58E-18
1.0E+03 4.39E407 1.75E.-17
4.0E+03 8.79E+07 6.42E-17
1.0E+04 1.39E+08 1.52E-16
q.OE+04 1.96E+08 2.72E-16
4.0E+04 2.78E+08 3.03E-16
7.0E+04 3.68E+08 1.89E-16
1.0E+05 4.39E+08 1.lIE-16
4.0E+05 8.7BE+De 3.94E-18 U7.0E+05 1.16E+09 3.61E-19
1.0E+06 1.39E+09 6.99E-20
2.0E+06 1.96E+09 3.33E-21
References: 90, 91, 92, 94, 97, 117, 140, 141, 142, 143, 144, 145, 146, 147, 148, 149, 265,266, 282
Accurac___! E < 250 _V/amu - see notes; E > 250 eV/amu - 20%
Nots..___s! (1) The data for energies less than 250 eV/amu have been obtained using the theoretical
results of Cohen and Bardsley (Ref. 149). From 250 eV/amu the data have been
extrapolated down to 2.5 eV/amu to Join smoothly with the theoretical results.
(2) Johnson et al. (Ref. 265) have measured the rate coefficient to be 4.8xi0 -14 cm3/sat a temperature of 30D K.
(3) Theoretlcal values of the rate coefficient of Bardsley et al. (Ref. 266) are:
T:100 K, k-4.43x10 -14 cm3/s; 300 K, 4.24xi0 -14 cm3/s; 600 K, 4.02xi0 -14 om3/s; I000 K,3.79xi0 "14 cm3/s; 3000 Z, 3.25x10 "14 cm3/s.
For a Chebyshev fit of the above cross sections lt is necessary to use the following parameters.
Eml n = 2.4E-04 eV/amu, Ema x = 2.0E+06 eV/amu
Chebyshev Fitting Parameters for Cross Sections
A0 1 AI A2 A3 A4 A5 A6 A7 AB
-83.5447 .75842] -.673803 -3.68088 -2.02719 -.148166 .023795] -.0738396 .243993
The fit represents the above cross sections with an rms deviation of ]9.9%.
The maximum deviation is 52.7% at 2.0E+00 eV/amu.
See appendix for Chebyshev fit details. _
A-99
He_'+ + He-> He+ +. He+
Cross Section vs, Energy-15
10 _'_lm_q _'_mlll i11m,l' I1_m111IIImq'-T11_ilq lrlml_l I1m'__ tilm.I ll_ul,1 IT_
,&10-16
xi _10-1__ _
/..._ .
I'N
E ,
f_':© _
o 10-1 - ',k,,, ' /,,/,
0 - Recommerlded
u ld._ -- Det.q=.
: ',X, ,f/\ ..,
- , ...... Ctlebyshev Fit
10-_-
- 110-21 ,J_,u_l JiiuJil l lJu,d i llllllll i itllllll II.LI_L_I_LI]IiHIlilliJill i LL_]]uLJ_LL]J]_il ililliiJ
0-2 02lo-4lo-'1 1rs' tc)° lo' 1 1o_ lo4 lo_ lo_ lo"/"Energy (eV, arnu)
0
A-100
AElectron Capture Rate Coefficients for ' 1
Ile 2+ -I lie -> He + 4 11_ 4
Maxwellian - Maxwellian Rate Coefflclents (cm3/s)
lie24
Temp. Equal He Temp. (eV)
(eV) Temp. I. i00. 500. i000. 5000. lO000. 20000.
1.0E+00 3 05S-ld 3.05E-14 5.38E-12 7.10E-I] 2.]2E-]0 2.25E-09 6.04E-09 1,55E-08
2.0E+00 4 41E-14 3.61E-14 5.46E-12 7.13E-ll 2,]2E-]0 2.25E-09 6.04E-09 ].55E-08
4.0E+00 9 66E-14 5.44E-14 5.64E-12 7.]7E-II 2.13E-I0 2.25E-09 6.04E-09 i 55E-08
7.0E+00 2 21E-13 9.66E-14 5.90E-12 7.24E-II 2.]4E-]0 2.25E-09 6.05E-09 I 55E-08
1.0E+01 3 88E-13 ].53E-13 6 17E-12 7.31E-11 2,15E-I0 2.26E-09 6.05E-09 ] 55E-08
2.0E+01 I ]9E-12 4.20E-13 7 lIE-12 7.54E-II 2.18E-I0 2.2613-09 6.06E-09 ] 55E-08
4.0E401 3 68E-12 1.24E-12 9 ]2E-12 8.01E-II 2.25E-I0 2,27E-09 6,07E-09 i 55E-08
7.0E+01 9 12E-12 3.03E-12 i 25E-II 8.74E-]] 2.35E_]0 2.29E-09 6.]0E-09 i 55E-08
1.0E+02 1,62E-II 5.38E-12 1 62E-II 9.48E-ii 2.45E-I0 2.31E-09 6.]3E-09 ] 56E-08
2,0E+02 4 94E-II 1.63E-11 3 lIE-li 1.21E-10 2,79E-I0 2.38E-09 6.21E-09 ] 57E-08
4,0E+02 1 50E-I0 4.96E-II 7 08E-II 1,80E.-I0 3.52E-I0 2.51E-09 6,38E-09 1,59E-08
7,0E+02 3 52E-10 1.21E-J0 I 50E-10 2.79E-I0 4,71E-]0 2.71E-09 6.64E-09 1.61E-08
1.0E+03 5 98E-I0 2.]2E-I0 2.45E-10 3,91E-I0 5 98E-10 2.92E-09 6.91E-09 1,64E-08
2.0E+03 1 63E-09 5.98E-I0 6.42E-10 8.28E-10 ] 08E-09 3.64E-09 7.80E-09 1,74E-08
4.0E403 4 40E-09 1.63E-09 1.69E-09 1,93E-09 2 25E-09 5.20E-09 9.66E-09 1,93E-08
7.0E+03 9 66E-09 3.64E-09 3.71E-09 4,01E-09 4 40E-09 7.80E-09 ].25E-08 2.21E-08
1.0E+04 1 55E-08 6.04E-09 6.13E-09 6,47E-09 6 91E-09 1.06E-08 1.55E-08 2,48E-08 I
2.0E+04 3 2BE-OB 1.55E-08 1.56E-08 1,59E-08 I 64E-08 2.03E-08 2.48E-08 3.28E-08
Notes: For Chebyshev fits of the above rate coefficients it Is necessary to use the following parameters.
Eml n = 1,0E+00 eV, Ema_( = 2.0E404 eV
Chebyshev Fit_!ng Parameters for Rate Coefficients
lle
Temp.
(eV) A0 Al A2 A3 A4 A5 A6
i. -5 01963E+01 6.98068E+00 4.23808E-01 -3.99615E-01 ].34075E-01 -2 04534E-02 -6.31634E-03
i00. -4 61698E+01 4,0933BE+00 1.25172E+00 -1.33442E-01 -1.61511E-01 2 93643E-02 3.24079E-02
500. -4 34226E+01 2.58703E+00 I 14624E+00 1.66058E-01 -I.03603E-01 -4 97857E-02 9.07394E-03
i000. -4 20905E-fOl I.gB401E+O0 1 O0005E+00 2.44794E-01 -4.33832E-02 -.5 53954E-02 -I.]1309E-02
5000. -3 8780lE+01 8,87534E-01 5 45829E-0] 2.27039E-01 4.75018E-02 -] 20021E-02 -].64614E-02
I0000. -3 72149E+01 5.46062E-01 3 51272E-01 ].61982E-01 4,68205E-02 I 2917]E,-03 -8.]3292E-03
20000. -3 56466E+0l 2,80620E-01 ] 85802E-01 9.16706E-02 3.15681E-02 5.20354E-03 -2.25604E--03
Equal Temp. -4 86572E+01 7.31907E+00 4 09101E--02 -2.9899lE-01 1.03426E-01 -6.77656E-02 6.42732E-03k
See appendix for Chebyshev fit detaiis.
A-IOI
He_* -t- He-.>He* + He*
Maxwellian- Moxwellian
10-_ Equal 1"emp.
10-"100 ld 102 ld ld lOs
t--le_+ Temp. (eV,')
0
A-lO2
AElectron Capture _Rate Coefficients for
He + He 2+ -> He l + llel_
Beam Maxwellian Rate coefficient_ (cm3/s)
He2+ _.
Temp, He Energy (eV/ainu)
(eV) i0000, 20000, 40000, 70000, i00000. 200000, 500000,
1.0E+00 2.50E-08 5,92E-08 8.41E-08 6,94E-08 4,87E-08 1.84E-08 1,49E-09
2.0E+00 2,]5E-08 5,40E-08 8,40E.-08 6.94E-08 4,87E-08 ].84E-.0B 1.49E-09
4,0E+00 2,11E-08 5_33E-08 8,40Ei08 6,94E-08 4,87E.-08 1.84E-08 1,49E-09
7,0E_00 2.ilE-08 5,33E-08 8.39E-O8 6,93E'08 4.87E-08 1,84E-08 1,49E--09
1.0E+0! 2 lIE-08 5,33E-08 8.39E-08 6,93E-08 4,87E-08 1,83E-08 i 49E-09
2,0E+0] 2 lIE-08 5,32E-08 8,38E-08 6,92E-08 4,87E-08 1,83E-08 i 49E-09
4.0E+01 2 I]E-08 5,31E--08 8.36E-0@ 6,92E_08 4,86E-08 1,83E-08 i 49E-09
7.0E+01 2 lIE-08 5.30E-08 8.34E-08 6,91E_-08 4,86E-08 1.83E-08 i 49E-09
1,0E+02 2 ]2E-08 5.30E-08 8,33E-08 6,90E-08 4.86E-08 1,83E-08 1 49E-09
2.0E+02 2 13E-08 5 29E-08 8.29E-08 6.88E-08 4.85E-08 1.82E-08 1 49E-09
4.0E+02 2 ]5E-08 5.28E-08 8.23E-08 5.85E-08 4.84E-08 1.82E_08 1 50E-09
7,0E+02 2 19E-08 5,27E-08 8.18E-08 6,82E-08 4,84E-08 1,81E-08 1 50E-09
1.0E403 2_22E-08 5.28E-08 8.13E-08 6,80E-08 4.83E-08 1,81E-08 1 50E-09
2.0E+03 2.35E-08 5.31E-08 8.01E-08 6 74E-08 4.82E-08 1.80E-08 ] 51E-09
4.0E+03 2,60E-08 5.38E-08 7.84E-08 6.66E-08 4.80E-08 1.79E-08 1 53E-09
7.0E+03 2.93E-08 5.47E-08 7.63E-08 6.56E-08 4.78E-08 1.78E-08 1 56E-09
1.0E+04 3.22E-08 5.55E-08 7.47E-08 6.47E-08 4.76E-08 1,78E-08 I 58E-09 A
2,0E+04 3.96E-08 5.70E-08 7.03E-08 6 ]9E-08 4,68E-08 1.79E-08 i 67E-09
Notesz For Chebyshev fit_ of the above rate coefficients it is necessary to use the following parameters.
Eml n = 1,0E+00 eV, Ema x = 2.0E+04 eV
Chebyshev Fittinq_Parameters_fo r Rate Coefficients
He
Energy
(eV/amu) AO AI A2 A3 A4 A5 A6
10000 -3,50304E+01 2,06181E-01 1,92296E-0] 4.564]IE-02 4 15838E-02 -1.64172E-02 5.89475E-03
20000 -3.34502E+0] -1.69065E-03 4,25743E--02 -4,85577E-03 1,65855E-02 -1.02931E-02 4.96346E-03
40000 -3.26729E+01 -7.16579E-02 -3.83983E-02 -1.62201E-02 -5.97032E-03 -].96773E-03 -5,29171E-04
70000 -3.30216E+01 -4.42089E-02 -2.40130E-02 -1.09682E-02-4,88645E-03 -2,28859E-03 -I,09577E-03
100000 -3.36938E+01 -1,54667E-02 -7,60687E-03 -3,31747E-03 -],90471E-03 -].15086E-03 -7.19346E-04
200000 -3,56481E+01 -1.62738E-02 -3.50236E-03 1,528]IE-03 2.39339E-03 ].00308E-03 6.34282E-04
500000. -4,06040E+01 3,82554E-02 2.68882E-02 1,51307E-02 6,78931E-03 2.33434E.-03 4.95076E-04
See appendix for Chebyshev fit details.
A-103
He + He2* --> i-le* + He+
Beam - Maxwellian
....... Chebyshev Fit
i ,L
A-104
, QDouble Elect_on Capture Cross Sections for
He 2+ + }le -> He + He2+
Energy Velocity Cross Section
(eV/an_u) (orals) (_m2)
7.0E+00 3.68E+06 4.62E-16
1.0E+01 4.39E+06 4.48E--16
2.0E+01 6.21E+06 4.10E-16
4.0E+01 8.79E+06 3.B3E-16
7.0E+01 1.16E+07 3.58E-16
1.0E+02 1.39E+07 3.44E-16
2.0E+02 1.96E+07 3.19E-16
4.0E+02 2.7BE+07 2,88E-16
7.0E+02 3.68E+07 : 2.62E-16
1.0E403 4.39E+07 2.44E-16
2 0E+03 6.21E+07 2.10E-16
4 0E+03 8.79E+07 1.73E-16
7 0E+03 1.16E+OB 1.46E-16
i 0E+04 1.39E+0B 1.29E-16
2 0E+04 1.96E+08 9.68E-17
4 0E+04 2.78E+08 6.08E-17
7 0E+04 3.68E+08 2.73E-17
1.0E+05 4.39E+08 9.83E-18
Z.0E+05 6.21E+08 6.36E-19
ID4.0E+05 8.78E+08 2.09E-20
Rgferenc@sj 90, 91, 92, 94, 140, 144, 145, 148, 150, 151, 152, 153, 282
Accuracyz 20% throughout the energy range
o_ (i) The data below 100 eV/amu are theoretical data of reference 153 (FergL1son and
Molseiwitsch).
For a Chebyshev fit of the above cross sections it is necessary to use the following parameters.
Emi n _ 7.0E+00 eV/amu, Emax = 4.0E+05 eV/amu
Chgbyshev Fitting ParameteIs for Cross Sections
A0 AI A2 A3 A4 A5 A6 A7 A8
-75.3410 -3.70255 -2.16467 -1.23660 -.590825 -.179613 .0396927 .102768 .0774058
The fit represents the above cross sections w].th an rms deviation of 3.2%.
The maximum deviation is 6.8% at 2.0E+04 eV/amu.
See appendix for Chebyshev fit details.
O
A-105
0
He_+ + He ->He + I-le_+
Cross Section vs° Ener-cjy
-151,J I I IIIIII i ' I--I']IIIII I I I IIIIIII 'I 'Tqliliil" I'I IIIIII i I -I 11117:[
_ -
10-16_
/-%
_IE 10-'7 - ,
(D(jr) --
(/) 18"lC)--
0 = Recommended%,_U _" Data
Chebyshev Fit
10-,__
10 -2' __.I I llllill J i l lllul i I i lli._J___.l_.L_Lllli|l ii .Lilllll II l ilm
lO0 ld 1U lO_ lo_ lO_ lo_Energy (eV/Q m LI)
®
A-lO6
ADouble Electron CaptUre Rate Coefflaients for
1t6 2+ + He _> }le + H_ 2"_
Maxwellian - Ma_wellian Rate Coefficients (cm3/s)
He 2+
Temp. Equal He _'emp, (eV)
(eV) Temp. ]. 100. 500. i000. 5000. i0000. 20000.
2.0E+00 5.21E-12 5.68E-13 2.92E-09 5.58E-09 7, 14E-09 I.]7E-08 1 38E-08 1.57E-08
4.0E+00 1.36E-I0 1.94E-I] 2,94E-09 5.58E-09 7.15E-09 i. 17E-[,8 ] 38E-08 ].57E-08
7.0E+00 5.25E-I0 l .36E-I0 2.98E-09 5,60E-09 7.16E-09 i. 17E-08 1 38E-08 1.57E-08
i. 0E+01 8.99E-I0 3.22E-I0 3.02E-09 5.61E-09 7.16E-09 I. 17E-08 1 38E_08 1.57E-08
2.0E+01 1.73E-09 9.54E-I0 3.14E-09 5.65E-09 7.19E-09 i. 17E-08 1 38E-08 1.57E-08
4.0E+01 2.60E-09 1.76E-09 3.36E-09 5.73E-09 7.24E-09 I. 17E-08 1 38E-08 1.57E-08
7.0E+01 3.36E-09 2.45E-09 3.65E-09 5.84E-09 7.31E-09 1.17E-08 1.38E-08 1.57E-08
i. 0E+02 3.90E-09 2.90E-09 3.90E-09 5.95E-09 7.38E-09 i, 17E-08 1.38E-08 i. 57E-08
2.0E+02 5.12E-09 3.91E-09 4.58E-09 6.30E-09 7.60E-09 1.]8E-08 1.39E-08 1.57E-08
4.0E+02 6.60E-09 5.12E-09 5.57E-09 6.88E-09 8.00E-09 1,19E-08 3.39E-08 1.58E-08
7.0E+02 8.00E-09 6.30E-09 6.60E-09 7.60E-09 8.52E-09 1.21E-08 1.40E-08 1,58E-08
1.0E+03 8.97E-09 7.14E-09 7.38E-09 8.18E-09 8.57E-09 1.22E-03 i. 41E.-08 1.58E-08
2.0E+03 1,10E-08 8.97E-09 9.10E-09 9.60E-09 i. 01E-08 1.27E-08 i, 43E-08 1,60E-08
4.0E+03 1.31E-OB 1.10E-08 1.]lE-D8 ].14E-08 1.17E-0fl 1.35E-08 1.48E-08 1.61E-08
7.0E+03 1.48E-08 1.27E-08 1.28E-08 1.29E-08 1.31E-08 1.43E_08 1.53E-08 1.64E-08
I.OE+04 1.57E-08 1.38E-08 ].38E-08 1.39E-08 i. 41E-08 1.50E-08 1.57E-08 1.66E-08
2.0E+04 1.69E-08 1.57F,-08 1.57E-08 1.58E-08 i. 58E-08 1.62E-08 1.66E-08 1.69E-08 Q
Notes= For Chebyshev fits of the above rate coefficients it is necessary to use the following parameters.
Eml n = 2.0E+00 eV, Ema x = 2.0E+04 eV
Che_h____shev Fittinq Parameters for Rate C_eff_cientsHe
Temp.
(eV) AO A1 A2 A3 A4 A5 A6
i. -4.15949E+01 4.05943E+00 -1.86222E+00 9.53695E-01-4,31628E-01 1.13605E-01 1.67894E-03
I00. -3.79435E+01 9.09167E-01 ].91522E-01 -7.51345_-02 -3.33315E-02 9.43860E-03 3,83286E-03
500. -3.72996E+01 5.30896E-01 ].95295E-01 ,2.21372E-'03 -3.37015E-02-9.19923E-03 3.89947E-03
i000, -3.70111E+01 3.90475E-01 1,68883E-01 1.91542E-02 -2.]9861E-02 -1.21205E-02 -Io71700E-04
5000. -3.63583E+01 1.43130E-01 8.03033E-02 2.65227E-02 7,89255E-04 -4.74954E-03 -3.10575E-03
i0000. -3.61072E+01 7.57604E_02 4.50781E-02 1.73388E-02 2.65954E-03 -1.73029E-,03 -1.75170E-03
20000. -3.59012E+01 2.91780E-02 1,75429E-,02 6.74273E'-03 9.12966E-04 -9.12778E-04 -9,71523E-04
Equal Temp. -4.01576E+01 3.11099E+00 -1.35722E+00 7.35133E-01 -4.32956E-01 1.86361E-01 -6.65206E-02
See appendix for Chebyshev fit details.
A-107 '
He2* -t- He ->He + He_*
r
Mexwellion Moxwellion ,
10-7 - i I I i ilil I I I I I illl I i i I lilil I i I' I 1-TTll I I 1 I 11114"
- - He Temp.--
(eV)
10-" - _} _ A --1.X
- _ , : x -- 100. ,
-- X
- ,,/_j/f - v --500.lf_, /
10-9-- // - _-looo.
m Z//E - _-
s _ / / _ • -_ooo.@ lo / m -- 10000o 10- : / : '
//L_.
t m --20000.
8 /I/ Recommended
o 10-" / I _ _Data
'[ ..... Chebyshev Fit
10-1_
= Equal Temp.
'i0-' ' ' "_10o 10' 102 103 104 105
He_+ Temp. (eV)
II
A-lO8
iDouble Electron Capture Rate Coefficients for
He + He 2+ -> He + He 2+
Beam - Maxwellian Rate Coefficients (cm3/s)
He2+
Temp. He Energy (eV/amu)t
(eV) 16000. 20000. 40000. 70000. i00000. 200000. 400000.
1.0E+00 1.79E-08 1.90E-08 1.69E-08 1.00E-08 4.31E-09 3.95E-I0" 9.21E-12 _*
2.0E+00 1.79E-08 1.90E-08 1.69E-08 1.00E-08 4.31E-09 3.95E-I0" 9o22E--12'*
4.0E+00 1.79E-08 1.90E-08 1.69E-08 1.00E-08 4.3lE-09 3.95E-10' 9.24E-12'*
7,0E+00 1.79E-08 1.90E-08 1.68E-08 9.99E-09 4.31E-09 3.94E-I0 * 9.26E-12'*
1.0E+01 1.79E-08 1.90E-08 1.68E-08 9.99E-09 4.31E-09 3.94E-I0" 9.28E-12'*
2.0E+01 1.79E-08 1.90E-08 1.68E-08 9.97E-09 4.30E-09 3.94E-10" 9.32E-12'*
4.0E+01 1.79E-08 1.90E-08 1.68E-08 9.94E-09 4.29E-09 3.94E-I0" 9.39E-12 _*
7.0E+01 1.79E-08 1.89E-08 1.67E-08 9.91E-09 4.29E-09 3.93E-I0" 9.45E-12 _*
1.0E+02 1.79E,-08 1.89E-08 1.67E-08 9.89E-09 4.28E-09 3.93E-I0' 9_51E-12'*
2,0E+02 1.79E-08 1.89E-08 1.66E-08 9.83E-09 4.27E-09 3.93E-I0" 9_65E-12'*
4.0E+02 1.79E-08 1.88E-08 1.65E-08 9.76E-09 4.26E-09 3.93E-10" 9.86E-12'*l
7.0E.02 1.79E-08 1.88E-08 1.64E-08 9.68E-09 4.26E-09 3.93E-10" 1.01E-II *_
1.0E403 1.78E-08 1.87E-08 1.63E-08 9.63E-09 4.26E-09 3.94E i0" 1.03E-II**
2.0E+03 1.78E-08 1.86E-08 1.61E-08 9.50E-09 4.28E-09 3_97E-I0" 1.0BE-II**
4.0E403 1.78E-08 1.84E-08 1.58E-08 9.34E-09 4.34E-09 4.06E-I0" 1.17E-II**
7.0E+03 1.77E-08 1.81E-08 1.54E-08 9.20E-09 4 42E-09 4.21E-10" 1.28E-II**
g1.0E+04 1.76E-08 1.79E-08 i.51E-08 9.08E-09 4.49E-09 4.39E-!0 1.38E-II**
2.0E+04 1.74E-08 1.71E-08 1.42E-08 8.74E-09 4.65E-09 5.07E-I0 1.71E-II**
Accuracy: * - Possible Error Greater Than 10%
• * - Possible Error Greater Than 100%
Notes: For Chebyshev fits of the above rate coefficients it is necessary to use the following parameters.
Eml n = 1.0E+00 eV, Ema x = 2.0E+04 eV
Chebyshev Fittinq Parameters for Rate Coefficients
He
Energy
(eV/amu) A0 A1 A2 A3 A4 A5 A6
i0000. -3.56880E+01 -I.04856E-02 -6.22291E-03 -3.54221E-03 -2.04547E-03 -i.06539E-03 -4.43802E-04
20000. -3.56043E+01 '3o86901E-02 -2.24247E-02 -I.12950E-02 -5.53082E-03 -2.66314E-03 -1.23198E-03
40000. -3.58798E+01 -6.74672E-02 -3.60384E-02 -1.56499E-02 -6.43318E-03 -2.74207E-03 -1.24709E-03
70000. -3.69171E+01 -5.93014E-02 -2.54553E-02 -7.53787E-03 -2.21925E-03-1.22692E-03 -8.87276E-04
i00000. -3.85034E+01 2_31019E-02 2.39390E-02 1.48606E-02 4.98011E-03 -1.80325E-05 -1.31207E-03
200000. -4.32277E+01 7.43187E-02 6.13383E-02 4.01508E-02 2.17045E-02 9.21588E-03 3.71392E-03
400000. -5.05148E+01 2.45518E-01 1.33039E-01 5.66724E-02 2.09008E-02 7.13076E-03 2.41652E-03
See appendix for Chebyshev fit details.
Q
A-lO9
He + He2+ ->He + He_+
' 6
Beom - Moxwellaon
10-71 ,, iiIiiil i ,fill;If I I ,IIIIII ii l'III,lI i I"'IFTTI'_
F - He Energy
- - (eV/amu)
" . _ " A -- 10000.
10-8 " _ _ x --20000.__
[ ___-----e -- v --40000._
"_ - _< --70000.
u 10 .... •-100000-- --
c::: - _ - '- m --200000.
O
- - [] '= 400000.(1)0u 10-" _- --.
¢) : : Recommended_- - ---_o '_',__u-
r_ -
_
Chebyshev Fit
1(_-1:2 i I l iltl,I l J i llllll l 1 Ill,Iii I _ l lJJul_ r I l lllll/v
100 10' 102 103 104 10sHe2+ Temp. (eV)
O
A-IlO
h
Electron Capture Cross Se0tlons for O
Ile2+ + Li -> He + + Li +
Energy Velocity Cross Section
(eV/amu) (cm/s) (cm 2 )
1.0E+02 i 39E+07 4.22E-I =I o w
2.0E+02 1.96E+07 6.95E_-15
4.0E+02 2.78E+07 9.64E-15
7.0E+02 3.68E+07 1.lIE-14
1.0E+03 4.39E+07 1.15E-14
2.0E+03 6.21E.07 I.]4E-14
4.0E+03 8.79E+07 1.06E-14
7.0E+03 1.16E+08 9.25E-15
1.0E+04 1.39E+08 7.39E-15
1.5E+04 1.70E+08 4.51E-15
2.0E+04 1.96E+08 2.24E-15
3.0E+04 2.41E+08 6.70E-16
5.0E+04 3.ilE+08 2.11E-16
7.0E+04 3.68E+08 1.43E-16
!o0E+05 4.39E+08 9.57E-17
1.5E+05 5.38E+08 5.79E-17
2.0E+05 6.21E+08 3.82E-17
2.5E+05 6.94E+08 2.32E-17
3.0E+05 7.61E+08 1.38E-17
4.0E+05 8.78E+08 5.17E-18
5.0E+05 9.82E+08 2.26E-18
5.9E+05 1.07E+09 1.21E-18
References: 230, 231, 232_ 234, 241, 242, 244, 246
Accura_ E < 2x105 eV/amu - 30%; E > 2x105 eV/amu - 40%
Notes: (i) For data of the sum of the single and double (total) cross sections see Kadota et al
references 243 and 245.
(2) For the electron capture cross sections for Li + , Li 2+ + He see references 249, 250,
251, and 254.
For a Chebyshev fit of the above Cross sections it is necessary to use the following parameters.
Eml n = 1.0E+02 eV/amu, Ema x = 5.9E+05 eV/amu
C_hebvshev Fittinq Parameters for Cross Sections
A0 Al A2 A3 A4 A5 A6 A7 A8
-69.9969 -3.86583 -2.]8937 .0319758 .0613388 -.163069 -.271234 -.111623 .204819
The fit represents the above cross sections with an rms deviation of 11.0%.
The maximum d_viation is 22.5% at 5.0E+04 eV/amu.
See appendix for Chebyshev fit details.
O
A-,,I 11
t-te"_+ + Li->He + + Li+
Cross Section vs. Energy
]_o13_- l i I III,Ill i I i )ili)l I i i li)Iii ) i l't-rTT_
10-__ .-._". __. - - - _-_:., ._r>-""" _ _
0 _E
_ 10-_5- _,LP - \_ -(D
03 ,_r-,-16LO ,,, -- \ _
0 )" - ,x,,, - Recommended_- - .x -
U _ "X,,X _ ----Data_X
\ -Chebyshev Fit
10-'7
\-18 \lO , 1 llllllI I I I IIIIIl I I II11111 _ I i III'Iii
10_ 103 104. t0s 10_Energy (eV/omu)
0
A-112
ilbElectron CaptUre Rate Coefficients for
LI + He2+ -> He+ + Li +
Beam - Maxwelllan Rate Coefficients (cmB/s)
He2+
Temp. Li Energy (eV/amU)
(eV) i0000. 20000. 40000. 70000. 100000. 200000. 500000.
IIOE+00 1,02E-06 4,40E-07 9.71E-08 5.26E-08 4.20E-08' 2,37E-08" 2,20E-D9**
2.0E+00 1.02E-06 4.39E-07 9.71E-08 5.26E-08 4.20E-08' 2.37E.-08' 2.23E-09'*
4.0E+00 1,02E-06 4.39E-07 9.71E-08 5.26E-08 4.20E,-08" 2.37E-08' 2.22E-09"*
7.0E+00 1.02E-06 4.39E-07 9.71E-08 5.26E-08 4.20E-08' 2_37_E-08' 2.22E-09'*
1.0E+01 1.02E-06 4.39E-07 9.71E-00 5.26E-08 4.20E-08' 2.37E-08' 2.22E-09"*
2.0E+01 1.02E-06 4.38E-07 9.71E-08 5.26E-08 4.20E-08' 2.37E-08' 2.22E-09'*
4.0E+01 1.02E-06 4,38E-07 9,72E-08 5.26E-08 4.20E-08' 2.37E-08' 2.22E-09"*
7.0E+01 1.01E-06 4.37E-07 9.72E-08 5.26E-08 4.20E-08' 2.36E-08" 2.22E-09"*
1.0E+02 1.OIE-06 4.37E-07 9.72E-08 5.26E-08 4.20E-08 2.36E-OB* 2.22E-09"*
2.0E+02 1.00E-06 4.37E-07 9.74E'08 5.26E-08 4.20E-08 2.36E-D8* 2.22E-09"*
4.0E+02 9.93E-07 4.39E-07 9.76E-08 5.26E-08 4.20E-08 2,35E-08' 2.22E-09"*
7_0E+02 9.81E-07 4.41E-07 9.81E-08 5.26E-.08 4.19E-08 2.34E-08' 2.22E-09'*
1.0E+03 9;69E-07 4.42E-07 9.86E-08 5.26E-08 4,19E-08 2.34E-08' 2,2BE-09'*
2.0E+03 9.35E-07 4.45E-07 1.01E-07 5.27E-08 4.19E 08 2,33E-08' 2.24E-09"*
4.0E+03 8.74E-07 4.45E-07 1.06E-07 5.29E-08 4.18E-08 2.31E-08' 2.25E-09"*
7.0E+03 8.03E-07 4.38E-07 1,16E-07 5.36E-08 4.18E-08 2.30E-08' 2.26E-09'*1.0E+04
7.48E-07 4.29E-07 1.25E-07 5.46E-08 4;18E-08 2.28E-08 2.26E-09'*
2.0E+04 6.25E-07 3.94E-07 1.48E-07 5.95E-08 4.21E-08 2.25E-08 2.28E-09'*
Accuracy: * - Possible Error Greater Than 10%
•* - Possible Error Greater Than 100%
Notes: For Chebyshev fits of the above rate coefficients it is necessary to use the following parameters.
Emin = 1.0E+00 eV, Ema x = 2.0E+04 eV
Chebyshev Fittinq Parameters for Rate Coefficients
Li
Energy
(eV/amu) A0 A1 A2 A3 A4 A5 A6
10000. -2.78062E+01 -1.87483E-01-I.15766E-01-5.63757E-02 -2.07864E-02 -4.18092E-03 1.20353E-03
20000. -2.93011E+01 -2,38001E-02 -2.23600E-02 -2.23853E-02 -1.68257E-02 -8.26641E-03 -2.16146E-03
40000. -3.21294E+01 1.47297E-01 1.06505E-01 5.96604E-02 2.42461E-02 4.76111E-03 -3.24711E-03
70000. -3.34880E+01 3.30410E-02 2.70085E-02 2.03864E-02 1.35662E-02 7.66428E-03 3.81877E-03
100000. -3o39729E+01 -1.63250E-03 3.97915E-04 1.54890E-03 1.48096E-03 1.08056E-03 6.82015E-04
200000. -3.51439E+01 -2.29742E-02 -1.03372E-02 -3.67071E-03 -8.35726E-04 -5.21814E-04 -6.93460E-05
500000. -3.98397E+01 1.28943E-02 5.77153E-03 3.54906E-03 -I.13575E-03 6.68011E-04 -9.25001E-04
See appendix for Chebyshev fit details.
@
A-113
Li + He2+ ->He + + Li+
Beom - Mclxwellan
0-9 ____J, I 1 11111
lo0 lo' lo_ lo_ lo_ ldHe2+ Temp. (eV)
0
A-114
Double Electron Capture Cross Sectlons for 0
lie 2+ + Lt-> Fie 't Li 2+
Energy Velocity Cross Section
(eV/ainu ) (oln/s ) (ota2)
6,1E+03 1,08E+08 9.12E-18
7,0E+03 1,16E+08 1.30E.-17
9.0E+03 1.32E.F08 2.39E,-17
1.0E+04 1,39E+0fl 2 99E-17
1.5E+04 1.70E+08 4.44E-17
2,0E+04 1.96E+08 4,03E-17
3.0E+04 2.41E+08 2.66E-17
5,0E+04 3,11E+08 1,42E-17
7.0E+04 3.68E+08 9.17E-18
1.0E+05 4.39E+08 5.86E-18
].5E+05 5.38E+08 3.12E-18
2,0E405 6.21E+08 1.17E-18
2.5E+05 6.94E+08 3.16E-19
3.0E+05 7,61E+0B 1.05E-19
4.0E+05 8.78E+08 1.62E-20
5.0E+05 9,82E+08 1.03E-20
Referenoesz 231, 232, 241, 242, 244, 246
Accuracy. l 30% O
Not_ (I) In the region (l-3x104 eV/amu) where the cross section is a maximum £he experimental
data fluctuates by a factor of ± 2. We believe that t_ie value quoted car_ be relied onto3o%.
(2) For data of the sum of the single and double electron capture see Kadota et alreferences 243 and 245.
(3) For electron capture cross seOtiolls of Li + , Li 2+ + lie see r_f_rences 249, 250, 251,and 254.
For a Chebyshev fit of the above cross sections it is necessary to use the following parameters.
Eml n = 6.1E+03 eV/ainu, Ema x = 5.0E+05 eV/ainu
Chebyshev Fittinq Parameters For Cross Sections
,
AO Al A2 A3 A4 A5 A6 A7 A8
-81.1888 -3.55493 -2,11208 -.149724 -.232101 .216608 .275776 .0980514 .0367760
The fit represents the above cross sections with an rms deviation of 3.1%.
The maximum deviation is 8,4% at 2.5E+05 eV/alnu.
See appendix for Chebyshev fit details.
He=' + Li--->l-le+ l_i='
Cr-oss"" -"'-,becvlonvs. Fnergy
'10-'_"------T--r--TTTTTT-I----'r---r--'T'-'rT-r-rn..... r---r-T--,-n-r-E_
!10-,7_ / '\\
,._t"
C2_0,__ 10-'__u(u _:
(/)
or)0 Recommended_. -
U _..... ___ '__z Data
10-__- Chebyshev Fit
iv
103 104 'IQ 1QEl-lergy (eV_JITIL.I)
@
A-I :Ifi
Double F,l_c+tron C,'tpture l_aLe,Co+_,ff_Ojellt_-j I_'+,_I,'l,J. + II_ 2tr -> llt+ + Li _'l-
L+oaln - Maxwell Jan l_ate Coeffieients (em3/s)
II m2"I,
q'omp, t.l Energy (eV/alnu)
( O V ) ' ]r00t]01 200001 400001 700001 100000. 200000. 400000.
1.0E400 4.]4E-09 7 91E-09 5+19E-09 3.37E..09 2 57E-09 7.251 10' 1.43E-II**
2.0El00 4.14_-09 7 90E-09 5.]9E-09 3.37E-09 2 57E-09 7.'25[_-10 * I+.43E-]I**
4.0E+00 4.]3E-09 7 90E-09 5..19E-09 3.37E-09 2 57E-09 7.25E-I0' 1.43E-II**
70E+O0 4.12E-09 7 89E-09 5.19E-09 3.371']-09 2 57E-09 7.24E-I0' 1.43E-II**
i 01_+01 4.12E-09 7 8|_E-09 5.]9E-09 3.37E-09 2 57E-09 7.23E-I0' 1.43E-II**
2 0E+01 4.10E109 7 87E-09 5.19E-09 3.37E-09 2 571+-09 7.22E-10' ].44E-II *_
4 OEr01 4.09E-09 7 85E-09 5.]9E-09 3.37E-09 2 575-09 7.20E-]0, 1.44E-II**
7 0El01 4.08E-09 7.83E-09 5.I_E-09 3.37E-09 2 5_E-09 7.18E-I0' I.45F]-31'*
I UE+02 4.07H-09 7.81E-09 5.]9E-09 3.37E-09 2 57E-09 7.17E-I0 1.45E-II**
2 (lE+02 4.07E-09 7.76E-09 5.19E-09 3.37E-09 2 56E-09 7 14E-10 3.47E-II**
4 OEr02 4.08E-09 7.70E-09 5.]9E-09 3.37E-09 2 56E-09 7 10E-10 1.49E-II**
7 oer02 4.13E-09 7.62E-09 5.19E-09 3138E-09 2 56E-09 7 07E-lO 1.51E-]I**
1 OEr03 4.18E-09 7.55E-09 5.]9E-09 3.38E-09 2 55E-09 7 05E-10 1.53E-II**
2 0E+03 4.31E-09 7.34E-09 5.19E-09 3.38E-09 2 55E-09 7 03E-10 1.59E-II**
4 OEr03 4.51E-09 6.99E-09 5.]9E-09 3.39E-09 2 54E-09 7 07E-I0 1.68E-II**
7 OEr03 4.68E-09 6.60E-09 5.]6E-09 3.40E-09 2 53E-09 7 16E-]0 ].81E-II**
i OE-104 4.79E-09 6.31E-09 5.11E-09 3.40E-09 2 52E-09 7 26E-10 1.93E-II *_ _&
2 OEr04 4.95E-09 5.71E-09 4.90E-09 3.40E-O9 2 50E-09 7 51E-iO 2.35E-II**
Accuracy+ * - Possible Error Greater Than 10%F
• _ - Possible Error Greater Than 100%
Notes+ For Chebyshev fits of the above rate coefflc;tents it is necessary to use the following parameters.
El,in = 1.0E+00 eV. Ema x = 2.0E+04 eV
Cheb_{shev Fittinc[ Parameters for Rate Coefficients
Li
Energy
(eV/ainu) AO AI A2 A3 A4 A5 A6
i0000. -3 85237E+01 7.92423E-02 5 63215E-02 1.72118E-02 -.5 29456E-03 -7.47819E-03 -2.52581E-03
20000. -3 74702EI01 -1.30340E-01 '-7 61020E-02-3.32737E-02-9 67526E-03 -I.]5041E-04 2.05695E-03
40000. -3 81678E+01 -].43365E-02 -i 25875E-02-1.01317E-02-6 93426E-.03 -3.91276E-03 -1.88591E-03
70000. -3 90!09E+01 4.43065E-03 2 ]0527E-03 3.09061E-04 -4 54509E-04 -5.21843E-04 -3.71172E-04
100000. -3 95717E+01 -1.18800E-02 .5 53013E-03 -2.04086E_03 -0 30113E-04 -4.87010E-04 -3.29738E-04
200000. -4 20984E-101 1.49204E-03 1 62234E-02 ].48608E-02 6 78142E-03 ].37283E-03 -7.46341E-04
400000. _4 97186E+01 ].87794E-0] i ]1341E-01 5.29149E-02 2 28786E-02 8.25402E-03 3.38953E-03
St_e appendix for Chebyshev fit details.
0
A.-I.I 'l
Li + tle :__ ...."' I'1_:_'-t" t._i_'+
i
f]::iecll ........Mc:l.'<welicll i
10-t_........ l--r FTI r1'li........ i......I- 1-II TMT........ r-T-HTMII ..... I.....l+-l++l-ITlrI....... I.....I+-I-TTIIT
.................. ,- L.i E Ii e r,j y
........... _._Z;::.::::,.._t -- (eV/o rrl u)
......................................................................................................... _ A ..... I0(+00,.+
:,( -.- 20(+)00,
V ......4 () () 0 O,
•('; I( -'-.- "" :-:..::?OOC_(.),
I+ ".... + "
c_ -- t.+._..... 10t _OOr),..
'++_ _. +
,9.2 tj+ ......2 (:)C)0 ()O,
Lp:(1.) I_1 4 C.)0 (..)_:+O,( !
(..)
(],.) [:__:<.c,m rJi e ricIe+.l
c:_ io ............... [) u t _](_]:: ilo -+ _.+..... .. "
-
,..
- "......... C:het:,y_:,ht_,',,Fit
,..
-.I I........J....l..I..+l.I.t..I.I.l.........I,..,I..,,.L..LI..LII,[..........l.._I.I..I,+LI,.LIJ.......L_I...L.t.L.IIJ_I]0•2 S
I(_' +I(..)_ Ii) lO" I(f* I()H+-:,-'+ -Ii-+lrlp,IeV"J
B. Electron Capture into LExcited States
O (* denotes rate coefficient data also)
Page
Electron Capture by H+ ............ B-2
H+ + H-> H(2s) + H_ , ....... , , B-2*
H + + H-> H(2p) + H+ , , , , ...... B-8*
H+ + H_, -> H(2s) , , , ......... B-14
H + + H2 > H(2p) .... , ........ B-14
H + + H2 -> H(Lyman-,, Total) ., , , .... B-16
H+ + H 2 -> H(Balmer-_,) , , . , , .... B-18
H+ + H 2 -> H(Balmer-B) . ....... B-18
H° + H 2 -> H(3s) , , , ........ B-20
H+ + H2 -> H(3p) ............ B-20
H+ + H 2 -> H(3d) ........... B-20
H+ + He-> H(2s). He' ........ B-22'
H + + He -> H(2p) + He + . ....... B-28'
H + + He-> H(Balmer-,,) + He' , ..... B-34'
H + + He -> H(3s)+ He' , ........ B-40*
H + + He -> H(3p) + He' _ , , , , ..... B-46"
H+ + He -> H(3d) + He + . ........ B-52'
H + + Li -> H(2s) + i,i' . ........ B-58
H' + Li -> H(2p) + Li' . ........ B-58
H+ + Li -> H(3s) + Li' B 60¢ t , , , _ , 4 o
O H+ + Li -> H(3p) + Li' , ........ B-60H+ + Li -> H(3d) + Li + , , , , ..... B-60
Electron Capture by He + . , B-62• • • m • • • m
He + + H2 -> H(2]S + 2_5) ........ B-62
He + + H_ -> He(21P) ........... B-64
He° + H2 > He(31P) .... . , ..... B-64
He" + H 2 -> He(_ = 447,1 nra) . . .... B-66
He' + H2 > He(,_ = 587,6 nm) ...... B-66
He + + H2 -> He(,\ = 667,8 nra) ...... B-66
He + + }le -> He(2tS + 23S) + He' , .... B-68"
He + + He -> He(2 P) + He + . ..... B-74"
He + + He -> He(3 S) + He + . ..... B-80
He + + He -> He(3-P) + He + ....... B-80He + + He -> He(3 D)+ He + . , , , . . B-80
He + + He -> He(3 S) + Hef . ..... B.-82He 't + He -> He(3 P) + He + , ..... B-,82
He + + He -> He(3 D) + He_ ...... B-82
He + + Fie -> He(4 S) + Fie' . ..... B-84
He + + He -> He(4 P) + He '° ....... B-84
He t + tle -> He(4 D) + He' , ...... B-84
He' + He -> He(4 S) + He + , ...... B-86
i_[el+ He -> He(4 P) + He' . ...... B-86
He + + He> He(4 D) + He' , ...... B-86
He' + Li -> He(53,7 nm)+ Li' , .... B-88
O He + + Li -> He(58.4 nra) + Li ° , .... B-88
I
J
' B. (Cont'd)
Electron Capture by He 2+ • • . ...... , B-90,
He 2+ + H -> He+(2s) + H' . ....... B-90*
He 2+ + H -> He +(2p) + H+ .... , . , . B-96"
He 2+ + H-> He+(Lyman-_,) + H+ ....... B-102
He2+ + H -> He+(Lyman-_) + H' . ..... B-102
He 2+ + H -> He +(Lyman-_) + H+ ...... B-102
He 2+ + H-> He+(Balmer-_) , + H' ...... B-102
He 2+ + H -> He+(3p) + H + . ....... B-104
He 2+ + H -> He+(3s+3d)+ H + ..... . . B-104
He 2+ + H-> He+(4p) + H+ ........ B-104
He2+ + H2 -> He+(2s) . . ........ B-106
H e2+ + H2 -> He+(2p) . . . , ...... B-106He 2+ + H2 -> He+(Lyman-_) ........ B-108
He2+ + H2 -> He+(Lyman-B) , ...... B-108, q
He2+ + H2 -> He+(Lyman-_) ........ B-108
H e2+ + H2 -> He+(Balmer-a) ......... B-108
H e2+ + H2 -> He+(3p) . . . _ ...... B-110
He 2+ + H2 -> He"(3s+3d) , . , . • . , . B-II0He 2+ + H2 -> He+(4p) .... ...... B-I10
He 2+ + He -> He+(2s) + He' . ...... B-II2*
He 2: + Li -> He+(2p) + Li + ....... B-II8
He 2+ + Li -> He+(3p) + Li + . . ...... B-II8 OHe 2+ + Li -> He +(4p) + Li' . . ..... B-II8
He 2+ + Li -> He+(3s+3d) + Li + . ..... B-II8
He 2+, + Li -> He+(4s+4d) + Li + ...... B-II8
He 2+ + Li -> He+(Lyman-_) + Li' . .... B-120
He 2+ + Li -> He+(Lyman-_) + Li _' . .... B-120He 2+ + Li -> He+(Lyman-_) + Li + .... , B-120
He 2+ + Li -> He+(Balmer-_,) + Li + ..... B-122
He 2+ + Li -> He+(Balmer-_) + Li' . .... B-122He 2+ + Li -> He+(Balmer-_) + Li + . .... B-122
He 2+ + Li -> He+(Balmer-o) + Li' . .... B-122
IB-2
_leatron Capture Cross Sectlons for
}I+ + H -> H(2s) + }I.
Energy Velocity Cross Section
(eVlamu) (cmls) (cre2 i
2.0E+03 6.21E+07 1.41E-18
3.0E+03 7.61E+07 2.77E-18
4.0E+03 8.79E+07 4.59E-18
5.0E+03 9.82E+07 6.78E-18
6.0E+03 1.08E+08 8.91E,-18
7.0E+03 1.16E+08 i.]9H-17
1.0E+04 1.39E+08 1.98E-17
2.0E+04 1.96E+08 3.65E-17
4.0E+04 2.78E+08 2.17E-17
5.0E.04 3.llE+08 1.39E-17
6.0E+04 3.40E+08 9.05E-18
7.0E+04 3.68E+08 5.56E-18
1.0E+05 4.39E+08 1.93E-18
2.0E+05 6.21E+08 2.59E-19
Referencesz i, ll, 12, 13, 14, 15, 16, 70, 71, 72
Agcuracy_ Energy < 3x103 eV/amu - factor 21 3x103 eV/amu < E < ixl05 eV/amu - 30%1 E > ixl05eV/amu - 50%
(i) For energies greater than 5x103 eV/amu, the crossed beam results of references 12 A
and 14 are in good agreement with the data obtained using the tungsten oven H cell
employed in the other experimental references.
(2) No corrections were applied for cascading but the effect is believed to be no more
than 5% ....
(3) Data for energies greater than 1.2x105 eV/amu were taken from the theoretical paper
by Shakeshaft (refo 70) who computed the cross sections using time-dependent impact
parameter coupled-state equations.
(4) Cross sections in the energy range Ixl03 - 5x103 eV/amu rely on the experimental
results of Morgan et al (ref. 15) and theoretical result_ of ref. 71 and 72.
(5) Cross sections for the 2s state were found by mixing the 2s and 2p states with anelectric field.
For a Chebyshev fit of the above cross section it is necessary to use the following parameters.
Eml n = 2_0E+03 eV/amu, Emc x = 2.0E+05 eV/amu
_hebyshev Fittinq Parameters for Cros_ S_ctig_s
A0 A1 A2 A3 A4 A5 A6 A7 A8
-80.2974 -.711716 -2.02522 -.193493 .250985 .0856986 -.0237110 -.0276091 -.00357455
The fit represents the abo_,e cross sections with an rms deviation of 1.3%.
The maxilaum deviation is 2.4% at 7.0E+04 eV/ainu.
See appendix for Chebyshev fit details.
B-S
O
H+ + H-> H(2s) 4- H+
Cross Section v,s.Energy
"10-16....... ] I I I'i'IIT-[_ ' I I I' i lili I I I I I IIl'q
_ __,,. \
_ / \/ \
/ \\10-r/- t \ -
0 _ - / \ --
s : / \ :r- _ / \ _.9 / \,O - /
/
_ / \ -/
O O-18 \ RecommendedU 1 \ _ Data\
-- .... Chebyshev Fit
- \ -\ -
10-I_ ......, i i i I,llil i .... i. i i l,l_llI. J i i i ii
1o_ 1o" .io_ Io_Energy (eV/om u)
II
, B-4
AElectron Capture Rate Coefficients for
H + + H -> H(2s) + H +
Maxwellian - Maxwellian Rate Coefficients (cm3/s)
H +
Temp. Equal H Temp. (eV)
(eV) Temp. 500. i000. 2000. 4000. 7000. i0000. 20000.
1.0E+02 1.86E-14 1.48E-II 9.32E-II 4.11E-10 1.35E-09 2.66E-09 3.50E-09 4.23E-09
2.0E+02 2.59E-12 2.51E-II 1.16E-10 4.52E-I0 1.40E-09 2.70E-09 3.52E-09 4.23E-09
4.0E+02 3.83E-II 5.41E-II 1.69E-I0 5.36E-I0 ].50E-09 2.77E-09 1.57E-09 4.23E-09
7.0E+02 1.69E-I0 1.16E-10 2.63E-I0 6.70E-I0 1.65E-09 2.87E-09 3,.62E-09 4.22E-09
1.0E+03 3.72E-I0 1.98E-I0 3.72E-I0 _ 12E-10 1.79E-09 2.96E-09 3,,68E-09 4.22E-09
2.0E+03 1.30E-09 5.80E-I0 8.12E-I0 i.30E-09 2.23E-09 3.25E-09 3,83E-09 4.20E-09
4.0E+03 2.96E-09 1.55E-09 1.79E-09 2.23E-09 2.96E-09 3.68E-09 4,05E-09 4.14E-09
7,0E+03 4.05E-09 2.80E-09 2.96E-09 3.25E-09 3.68E-09 4.05E-09 4,20E-09 4.03E-D9
1.0E+04 4.23E-09 3.59E-09 3.68E-09 3.83E-09 4.05E-09 4.20E-09 4,23E-09 3.90E-09
2°0E+04 3.42E-09 4.22E-09 4,22E-09 4.20E-09 4.14E-09 4.03E-09 3.90E-09 3.42E-D9
Notes: For Chebyshev fits of the above rate coefficients it is necessary to use the following parameters.
Emi n = 1.0E+02 eV, Ema x = 2.0E+04 eV
Chebyshev Fittin@ Parameters for Rate Coefficients
0Temp.
(eV) A0 A1 A2 A3 A4 A5 A6
500. -4.38672E+01 3.12293E+00 -1.60004E-01 -3.10412E-01 -2.36074E-02 1.60083E-02 6.19524E-03
I000. -4.24130E+01 2.]4668E+00 6.37440E-02 -2.57968E-01 -5.56388E-02 1.72468E-02 8 38626E-03
2000. -4.10369E+01 1.31982E+00 1.21498E-01 -1.62370E-01 -6.16572E-02 4.43261E-03 8.17248E-03
4000. -3.98120E+01 6.46066E-01 8.59976E-02 -8.09184E-02 -4.48832E-02 -5.52064E-03 3 62665E-03
7000. -3.90771E+01 2.57541E-01 2.91176E-02 -4.35279E-02 -2.76600E-02 -6.63736E-03 5.07727E-04
]0000. -3.87811E+01 9.11341E-02 -6.21649E-03 -3.19458E-02 -1.89226E-02 -5.58779E-03 -2.28503E-04
20000,-3.86539E+01 -7.79801:i-02 -5.02818E-02 -2.49832E-02 -9.47407E-03 -2.56718E-03 -3.98810E-04
Equal Temp. "4.60750E+01 5.50322E+00 -2.23799E+00 4.38735E-01 -2.58100E-01 1.18690E-01 -1.94375E-02
See appendix for Chebyshev fit details.
B-5
' H* ,+ H ->H(2s) + H*
Maxwellian- Maxweliars
0 1' l 1 1 1 I 1111 I I I I 1 111
102 103 10' 10sH* Temp. (eV)
J
B-6
Electron Capture Rate Coefficients for O
H + H4 -> H(2s) + H 4
Beam - Maxwellian Rate Coefficients (cm3/s)
H +
Temp. H Energy (eV/amu)
(eV) I0000. 20000. 40000. 60000. 80000. i00000. 150000.
1.0E+00 2.74E-09 7.12E-09 6.01E-09" 3.07E-09' 1.47E-09"* 8.48E-I0"* 3.21E-I0"*
2.0E+00 2.74E-09 7.11E-09 6.00E--09" 3.07E-09' 1.47E-09"* 8.48E-I0'* 3.21E-I0"*
4.0E+00 2.74E-09 7.08E-09 5.99E-09" 3.07E-09' 1.47E-09' 8.48E-]0 *_ 3.21E-I0'*
7.0E+00 2.74E-09 7.05E-09 5.97E-09" 3.07E-09" 1.47E-09 * 8.48E-I0'* 3.21E-I0"*
1.0E+01 2.73E'09 7.03E-09 5.96E-09 3.06E-09 • 1.47E-09' 8.48E-]0'* 3.21E-I0'*
2.0E+01 2.73E-09 6.97E-09 5.94E-09 3,06E-09" 1.47E-09" 8.49E-I0"* 3.21E-I0',
4.0E+01 2.74E-09 6.89E-09 5.90E-09 3.05E-09' 1.47E-09" 8.50E-I0" 3.21E-I0_*
7.0E+01 2.75E-09 6.81E-09 5.86E-09 3.05E-09' 1.48E-09' 8.51E-I0" 3.21E-I0"*
1.0E+02 2.76E-09 6.75E-09 5.83E-09 3.04E-09" 1.48E-09" 8.53E-I0" 3.22E-I0'*
2.0E+02 2.82E-09 6.60E-09 5.75E-09 3,04E-09" 1.49E-09" 8.57E-I0' 3.23E-I0'*
4.0E+02 2.95E-09 6.40E-09 5.64E-09 3.04E-09 1.51E-09" 8.66E-I0" 3.25E-I0 *_
7.0E+02 3.14E-09 6.21E-09 5.52E-09 3.05E-09 1.54E-09" 8.80E-I0" 3.28E-I0'*
1.0E+03 3.30E-09 6.08E-09 5.42E-09 3.05E-09 1.57E-09" 8.94E-I0" 3.30E-I0_*
2.0E+03 3.69E-09 5.77E-09 5.14E-09 3.05E-09 1.65E-09" 9.42E-I0" 3.37E-I0'*
4.0E+03 4.10E-09 5.35E-09 4.69E-09 3.00E-09 1.75E-09" 1.03E-09' 3.52E-I0"*
7.0E+03 4.35E-09 4.90E-09 4.19E-09 2.88E-09 1,82E-09" i. 14E-09' 3.87E-I0"*
1.0E+04 4.40E-09 4.57E-09 3.82E-09 2.74E-09 i. 84E-09 i. 20E-09" 4.28E-I0" 1 1
2.0E+04 4.08E-09 3.80E-09 3.07E-09 2.35E-09 1.74E-09 1.26E-09' 5,48E-I0 _
Accuracy: * - Possible Error Greater Than 10%
•* - Possible Error Greater Than 100%
Notes: For Chebyshev fits of the above rate coefficients it is necessary to use the following parameters.
Eml n = 1.0E+00 eV, Ema x = 2.0E+04 eV
Cheb_shev Fitting Parameters for Rate Coefficients
H
Energy
(eV/amu) AO AI A2 A3 A4 A5 A6
i0000. -3.91129E+01 2.48347E-01 9.68613E-02 -2.22662E-02 -5.16334E-02 -2.86624E-02 -4.22512E-03
20000 -3.78678E+01 -2.64262E-01 -1.22968E-01 -4.41549E-02 -1.57924E-02 _6.00867E-03 -i 43873E-03
40000 -3.81878E+01 -2,65205E-01 -1.50964E-01 -6.70004E-02 -2.27907E-02 -3.96914E-03 2 12259E-03
60000 -3.92919E+01 -7.86994E-02 -5.90240E-02 -4.39866E-02 -2.75365E-02 -I.19525E-02 -2 20171E-03
80000 -4.05364E+01 1.08994E-01 4.62123E-02 -5.38404E-03 -2,37480E-02 -1.87047E-02 -8 06980E--03
100000 -4.15580E+01 1.82433E-01 1.07666E-01 3.51890E-02 -4.95054E-03 -1.53694E-02 -i 20555E-02
150000 -4.35210E+01 ].78485E-01 1.28691E-01 7.63149E-02 3.78040E-02 1.49449E-02 2 43305E-03
See appendix for Chebyshev fit details.
0
B-?
PI -I- H* ->H(2s) -t- H+
0.0
10o 10' ld ,18 104 lOsH+ Ternp. (eV:)
II
B-8
Electron Capture Cross Sections for
H + + H -> H(2p) + H +
Energy Velocity Cross Section
(e V/am u ) (cm/s) (om 2 )
6.0E+02 3.40E+07 6.05E-18
7.0E+02 3.68E+07 8.69E-18
1.0E+03 4.39E+07 1.85E-17
1.5E+03 5.38E+07 3,10E-17
2.0E+03 6.21E+D7 3.05E-17
3.05+03 7.61E+07 2.87E-17
4.0E+03 8.79E+07 2.89E-17
7.0E+03 1.16E+08 3.06E-17
].0E+04 i 39E+08 2.99E-17
2.0E+04 1 96E+08 1.79E-17
3.0E+04 _ 2 41E+08 1.01E-17
4.0E+04 2 78E+08 _ 5.83E-18
7.0E+04 3 68E+08 1.46E-18
1.0E+05 4 39E+08 6.18E-19
2.0E+05 6.21E+08 1.41E-19
2.4E+05 6.80E+08 1.00E-19
References: 17, 18, 19, 20, 70
Accuracy: E < 2x103 eV/amu - 40%; 2x103 eV/amu < E < 3x104 eV/amu - 25%; E > 3x104 eV/amu - Iunknown
Notes: (i) Thomas in ref. 20 has applied a correction to ref. 19.
(2) All cross sections have beer, normalized to either the H + + H 2 -> H(2p) + }12+ or e- +H(Is) -> e- + H(2p) cross sections.
(3) Cross sections for H impact energies greater than 3xi04 eV/amu rely on computations
of Shakeshaft (ref. 70). Data were obtained using time-dependent impact parameter
coupled-state equations.
(4) The cross section (dl) for capture into state i is determined by measuring the
emission cross section (_ij) for a transition from state i to j, correcting for any
branching from state i, and correcting for cascading from upper states.
(5) Cascading from upper states to the 2p state is less than 5%. Thus _ (2p) =
a(Lyman-u) emission cross section°4
For a Chebyshev fit of the above cross sections it is necessary to use the following parameters.
Emi n = 6.0E+02 eV/amu, Ema x = 2.4E+05 eV/amu
Chebyshev Fitting Parameters for Cross Sections
AO A1 A2 A3 A4 A5 A6 A7 A8
-79.9812 -2.30968 -1.73621 .]10265 .0489823 .217654 -.0576541 -.0617916 .0399669
The fit represents the above cross sections with an rms deviation of 2.8%.
The maximu, deviation is 5.8% at 2.0E+04 eV/amu.
See appendix for Chebyshev fit details, iV
d
1B-9
H+ + H ->H(2p) + Pl*
-t'Cross Sec.lon vs. Energy
10-'6 -I I I IIII
/10-,7 / \ _
(..)
c-el '
c.)(D
0 Rec o rn rn ended
le Datau 10-
Chebyshev Fit
lc_-19 i I llllll L__I__LJ I I 111 I 1/kJ
lo_ 18 lo_ _o_ ctEnergy (eV/am u)
0
B-10
lhElectron Capture Rate Coefficients for
1:I+ -t I1 -> l l(2p) + I1+
Maxwellian - Maxwelllall Rate Coefficients (cm3/s)
,H +
Temp. Equal H !['en_p, (eV)
(eV) Temp. 50. i000 500, ]000, 5000, I00000 20000°l
4.0E+01 5.58E-13 1.28E-12 1 45E-II 5.48E-I0 1,16E-09 2.88E-09 3,03E-09 2 47E-09
7.0E+01 1.45E-II 6,91E-12 3 22E-II 5.92E-10 1.19E-09 2.89E-09 3.03E-09 2 47E-09
1.0E+02 5.74E-ii 1.95E_11 5 74E-11 6,36E-I0 1,22E-09 2.89E-09 3,03E-09 2 46E-09
2.0E+02 3.33E-I0 1.13E-I0 1 81_-10 7,73E-I0 1,32E-09 2.91E-09 3.03E_09 2 46E-09
4,0E+02 B.99E-ID 4,11E-10 4 88E-I0 1,02E-09 1,49E-09 2,93E-09 3,02E-09 2 45E-09
7,0E+02 1,49E-09 8.38E-I0 8 99E-I0 ],32E-09 1,71E-09 2,.6E-09 3,01E-09 2 43E-09
1,0E+03 1 90E-09 1,17E-09 1 22E-09 1,56E-09 i.90E-09 2.99E-09 3,00E-09 2 41E-09
2,0E+03 2 68E-09 ].93E-09 i 96E,-09 2,17E-09 2,38E-09 3.05E-09 2,95E-09 2,36E-09
4,0E+03 3 07E-09 2.70E-09 2 71E-09 2,79E.09 2,88E-09 3.06E-09 2,84E-,09 2.25E-09
7.0E+03 2 84E-09 3,05E'-09 3 05E-09 3.06E-09 3,07E-09 2.95E-09 2,65E-09 2,09E-09
1,0E+04 2 47E-09 3,03E_09 3 03E-09 3,O2E-09 3.00E-09 _.'7_]E-09 2.47E-09 1,96E-09
2,0E+04 I 59E-09 2,47E-09 2 46E-09 2.44E-09 2,41E-09 2.19E-09 1,96E-09 1,59E-09
Notes: For Chebyshev fits of the above rate coefficients it is necessary to use the following parameters.
=Eml n = 4.0E+OI eV, Ems x 2.0E+04 eV
@Chebyshey Flttlnq Parameters for Rate Coefficients
H
Temp.
(eV) A0 AI A2 A3 A4 A5 A6
50. -4.42667E+01 3.68258E+00 -1.49113E+00 1.59924E-01 3.18208E-03 -6.21884E-02 2,01934E-02
100. -4 30926E+01 2,69099E+00 -8.96227E-01 -7.60448E-02 4,64849E-02 -4,79878E-02 6.77301E-03
500. -4 08437E+01 9.29788E-01-1.25719E-01 -I,89331E-01 -3.21599E-02 5.88363E-03 2.45244E-03
1000. -4 02252E+01 5,06698E-01 -5.16460E-02 -1.44926E-01 -4.91357E-02 2.77891E.-03 6,06624E-03
5000.'-3 93773E+01 -6.84093E-02 -8.56458E-02 -6.23155E-02-2.73651E-02 -6.00122E-03 5.77484E-04
10000. -3 94214E+01 -1.65783E-01 -1.04137E-01 -4.96524E-'02-1,77141E-02 -4,10624E-03-1.51335E-04
20000. -3 98550E+01 -1.76608E-01 -9.99144E-02 -4,14670E-02 -],28283E-02 -2.76171E.-03 -2.52981E-04
Equal Temp. -4.38515E+01 3.35460E+00 -2.04640E+00 5.49669E-01 -2,67503E-01 7,12101E-02 2,83428E-03
E
See appendix for Chebyshev fit details,
B-11
c
bl* -Jr H -->t-t(21_) + H+
Maxwellian Maxwellicln
D-12,
_:i_ctron Capture Ratu Coefficle|_ts for
11 + II"I -> H(2p) + II'I
Beam'- Maxwellian Rate CoefClo]ents (cm3/s)
ll,0.
_'emp, 11 Energy (eV/ainu)
(eV) 10000, 20000, ,40000, 60000, 80000, 100000, 20000q.
1,0E+O0 4,14E-09 3 51E-09 1,62E.,09' 7,27_:-I0' 4,16E-10'* 2,72E-10'_ 8,76E-II**
2,0E+00 4,13E-09 3 50E-09 1,62E-09' 7,27E-I0' 4,16E-I0'* 2,72E-i0'* 8,76E-11'*
4,0E+00 4,]2E-09 3 _0E-09 1.61E-,09' 7,28E-I0' 4,165-10'* 2,72E-I0'* 0_76E-II**
7,0E+00 4,11E-.09 3 49E-09 1,61E-09' 7,28E-10' 4,16E-10'* 2,72E-10'* 0,77E-II**
1,0E+0I 4,10E-09 3 49E-09 1,61E-09' 7,28_-i0' 4.16E-I0' 2,72E:-I0'* 8,77E-11'*
2.0E+01 4,08E-09 3 47E-09 1_61E-09 7,28E-I0' 4,16E-I0' 2,725-10'* 8,77E-II**
4.0E+01 4,06E-09 3 46E-09 1,61E-09 7,29E-I0' 4,16E-I0" 2,73E-I0 _* 8,78E-II**
7.0E+01 4,03E-09 3,44E.-09 1,60E-09 7,30E-I0' 4,i75-10' 2,73E-I0' 8,79E-II**
1,0E+02 4,00E-09 3.42E-09 1,60E-09 _,31E-10* 4,17E-I0' 2,73E-I0' 8,79E-II**
2,0E+02 3,94E-09 3,39E-09 1,60E-09 7,35E-I0' 4,19E-I0' 2,75E-I0' 8.81E-II**
4.0E+02 3,86E_09 3,34E-09 1,60E-09 7,42E-I0' 4,22E-I0' 2,77E-I0' 8.83E,-II**
7.0E+02 3,775-09 3.27E-09 1,60E-09 7,53E-I0' 4,27E-10 _ 2,80E-I0' 8,80E-II**
1.0E+03 3.69E-09 3.22E-09 1 60E-09 7,645-10' 4,32E-10' 2,82E-I0' 8,71E-II**q
2,0E+03 3.50E-09 3.05E-09 ],59E-09 7.95E-I0 4.49E-I0' 2.92E-i0 _ 8,40E_II^,
4.0E+03 3,23E-09 2,77E-09 1,57E-09 8,40E-I0 4.85E-10' 3,_2E-I0' 8,06H-II**
7.0E+03 2,93E-09 2.46E-09 2,50E-09 0,76E-10 5.29E-I0' 3,42E-I0' 8,00E-II**
1.0E+04 2,69E-09 2,25E-09 1,43E-09 8,80E-10 5.60E-I0' 3.69E-I0' 8.18E-II** O
2,0E.I04 2.10E-09 1,76E-09 1.23E-09 8,56E-]0 5.99E-I0 4.24E-I0' 9,59E-II**
AcoLlracyl * - Possible Error Greater Than 10%
• * - Posslble Error Greater Than 100%
Notes| For Chebyshev fits of the above rate coefficlents it is r|ecessary to use the following parameters,Eml n = I,OE+00 eV, Ema x = 2,0E+04 eV
C hebyshev Flttlnq Parameters for Rate CoefficientsH
Energy
(eV/amu) AO AI A2 A3 A4 A5 A6
10000, -3.893305+01 --2.63479E-01 -i 46563E-01 -6,61900E-02 -2 64497E-02-9.58772E-03 -3 32633E-03
20000 -3,92573E+01-2.65213E-01 -i 59204E-01 -7,45512_:-02 -2 59202_]-02 -4,4093]},:-,03 1 71443E-03
40000 -4,058065+01 -8,23737E.-02 -5 96947E-.02 -4,22268E-02 -2 58735E-02 -].17419E-02 -3 02153E.-03
60000 -4,19604E+01 9,70829_:-02 4 525991']-02 7,29529E-04 -i 726821!:-02 -],54561E-02 -7 90347E-03
00000 -4.30171E+01 ].56735E-0] 9 7782"/E-02 3,77245E--02 I 87]10E-03 -9,85709[_:-03 -9 46753E.-03
i00000 -4,30524E+01 1.71818E:-01 I 11913_:-01 5,358]7E-02 ] 64028E-02-2.0566]E-04-5 46000E-03
200000 -4,63327E+01 .'9,29799E-03 6.37363[.,I-03 2.65872E-02 3 44937E-02 2,70598E-02 ] 28430E-02
See appendix for Chebyshev flt details.
O
PI -t- I-I_ -,::."t-1(2I_) + H+
._,_,.CIIT] .... MCI:>'W@IIICIF1
'IUs'''- ----r--r-m-rml---T--m.Trrnl---T--r,_i-rrjri ..... , _ r-Frn,l , Fr-rTrE
. H Erlergy--I
- -, (eV/arnu)
e /s .... 10000,
- ""----2"--."-. ", :_.'.-- 20000,
. '-,,,.,"_ -"----.. V -- 4-0000,
-,_ 10- - - _ --6oooo,
O f:: _.t) - ._---._ ¢ B00 0 O,"..,_J ,,.,,.
/.m - m -- 10000o.
,_-,, _ -- 20000 O,
0
L.) Reco m mendedDato
o 10-I _ .-----
_- ..... Chebystnev Fit
10-_ j _ _ILU..IL.__L_LLUJ.U.L i I __ll_l ._...L..LLLU.:!_I I ._.LJ_LLLL
100 ld 10_ 103 104 10st-'1+ Temp. (eV)
II
A
I'H o(_t lotl C'ald:Ul:i_ Cre[iii _loc_t:Lolm roi Q
II t .i. 112'-',, Ilillls21,)
II (2_) ii (2p)
F_tli_i:gy Ct!still Lleol:[Oll Flllerg 7 CL'olilt _octJ.oll
oV/alliU umI eV/amu ct, 2
l ,OI_,bO3 2,641:1-I11 4,0 I.:,l(i3 1,991_-17
4 0l'1+03 5 _OIIl'l- 1II 7,014"i'03 2,3VE-I'/
70P,+03 g, 241:I-Ifi I,Obl.04 2,641.',.17
1 0[",4'04 I, 3"/Icl-I7 I,4 t'HO4 2,721':-17
2 01_+04 2,69 _I-1"/ 2, (1b_04 2,35 (,]-17
2 5bf04 2, "/9 l'l- 1"1 4, OI'H04 8,74[':-111
4 OE+04 2,21 I?,-,i7 7,0E+04 3,39E-1li
"2,0biD4 9,531;:-IB I,0FJ+O5 1,751_l-i(I ' '
1,0g+05 4,201]-1lI 1,!;t,',.F05 1,ODE-III
2,01,].I-05 ,i,24l,:-I9
Ro l_0reliooi!lll(2s) - 13, 16, 18, i£4], 122, 123, 124, 125, 126i ll(2p) - III, 122, :124, 12B
_qgura_yl _oo notes
iigfL,tL/gl (1) [,arge errorii are Uiiually allsoeial:od wit:ii moalluring elllll_tJloil 17rem oxcJtecl stateiJ to
obtaJ.n either eletJtron oapttiror dtlJ_|ocl'atlve oi exeli:atlon emllJliiOll (JroEiti iieetlons, The
cross seatlollS reported hero are elllltlllion oro,cJtl lleCtlorls liore eJ(:(JtrOll oapttlre
eolliBlorls, The tl(2s) crose llOOtiollU are di?refrained by observing tlm excited II atom in
(in eloctrle i!leld which mlxe[i the Iu state wlth the 2p state, 'Phe scatter of the dat_l
11% tile references iii a factor of 2 for ll(2s) capture and 20% for ll(2p). We ostlmate
thor tile data presented ilero ilave a aon[Ldenco level to within50%,
(2) Pot' tile aollltltonil in an electromagnetic [Jeld sulf latent to mim tile 2D and 2p, tim
I,yrnan-u emlsulon aros|i F}er:tton Ira obtained from .(211).i.(2p).
(3) 'l'he et'osts licorice (oi) Eor [:apLuro Into state 1 ;ill deter.lined by meaStlrtng tlm
emliislon erofJla ueettOll for li tran_iltlon rrom IItat, I to :t, aorreetintj for ally branohinej
from utero I and correetlncj.ror carm.adlr|g f. rom upper lltatoii.
(4) Since cascading to the lp [Irate til lotiu I:han 5% _(2p)-,(hyman-u) eml.,itllon.
Per Chebyshev fits of the above i;rofiE] _mc,'tionn Jt Iu necessary Lc) title the Eollowlng parameters.
11(2Bl lelmln ,, 2,0E+03 eV/ainu, lilnax,-, 2.01;:+05 eV/ainu
11(2l:,) l.:mtn ,. 4,0F.,403 eV/ainu, Ems x = 1,5H-t05 eV/ainu
Ch.eby_lhev l,_lt;t_lne_J Parallieto[Fi ['cir Croun SeetlonlJ
A0 Al A2 A3 A4 A5 A6 A7 AB
H(2L_) -79.7252 -,533265 -1,5610[) -,431130 ,0IIIDVD9 ,0519074 -.04"I[1876 -,D0197365
11(21)) -78,7561 -1,60375 -,734004 ,106262 ,120750 -,0254921 ,00605546 ,0276214 .034101B
_ilo [lt representii tile ll(2s) croFJI][leOtlOl_ Wltil an rllliidevlat|on oi ].3%.
The ,lax41mUlmdeviation iu 2.5% at 1,0E404 eV/ainu,
'l'ile fit represents the 11(lp) ¢'roiisIJOr,!Llon wlt:h all rms dovtal.lon (_f 1,!1%,
The lllaXlmLIlll dovLatton III '11,51 al: I,;11_:-t05 I'-_V/mllll,
90o appendix for Ctlebyt'lliev fit deta,llii,
B-.L5
H+ + PI_-'> H(2s, 2p)
Cross Section vs, Energy
10 "16 _"' r i I i i i ill i -F-1--l--i iiil " " ' i i -i r i i i-L
Chebyshev Fit10-1_-__ ..... i 1 i i l llll _.J.. i i i i i l li i i i I 1 I._LL
lo_ lo_ lo:' lo°Energy (eV/ran-iu)
B-16
0Line Hmlsslon Cross Sections of Electron Captu[e Collisions Eor
II+ + [I2 -> H(Ly_) Total
Energy Velocity Cross Seotlon
(eV/amu) (¢m/s), (am 2 ),,
B.28+01 1.26E+07 7.15E-20
i. 0E+O2 1,39E+07 i, 37E-19
2.0E+O2 1.96E+07 9.34E-19
4.08+02 2.78E+07 4.56E-18
7.0E+02 3.68E+07 1.20E-17
1.0E+03 4.39E+07 1,69E-17
1.5E+03 5.38E+07 1.97E-17
2.0E+03 6.21E+07 2.11_-17
3.0E+03 7.61E+07 2.39E-17
4.0E+03 8.79E+07 2.94E-17
7.0E+03 1.16E+08 4,30E-17
1.0E+04 1.39E+08 5.22E-17
1.4E+04 1.64E+08 5.61E-17
2.0E+04 1.96E+08 4.87E-17
4.0E+04 2.78E+08 2.97E-17
7.0E+04 3.68E+08 1.94E-17
I.OE+05 4.39E+08 1.46E-17
1.4E+05 5.20E+08 1.19E-17
References_ 124, 128, 187, 188, 193, 195, 197 O
Accuracyz 40%.... t__
Notess (i) The cross section _i for capture into state J is determined by measuring the
emission cross section (uiJ) for a transition from state i to J, correcting for any
branching from state i and correcting for cascading from upper states.
(2) The capture cross section into excited states is measured by making use of the'
Doppler shift. The total _ (L_) was determined from the total of the shifted and
unshifted radiation.
For a Chebyshev fit of the above cross sections it is necessary to use the following parameters.
Eml n = 8.2E+0i BV/amu, Emc x = 1.4E+05 eV/amu
Chebyshev Fitting Parameters for Cross Sections
AO AI A2 A3 A4 A5 A6 A7 AB
-79.2785 2.29244 -1.84261 .243522 -.i13691 .0377226 .155522 -.0201741 -.0977164
The fit represents the above cross sections with an rms deviation of 3.4%.
The maximum deviation hs 6.0% at 2.0E+04 eV/amu.
See appendix for Chebyshev fit details.
B-17
H+ + Hz -:> H(Lyman-_)Total
Cross Section vs. Energy
0 16_ ' I I I IIIIII I I I llllll I I I IIIIII I I I 1I'IIII 'I I I Illll
- _ -
\ -_,_,
10-17 / _- / _
! /_ _E -,) ' _
C2.©
10-1__L2 -(b -
(./') _
09
O
U
1_ lc"__ ' -
-- E
- Recommended--
- - Doto
..... Chebyshev FitI(_-2( I I lllllll I I IIIIIII' I li IIIIII I I I llIlll l I I,IV
10' 10_ 103 104 10s 106Energy (eV/om u)
B-18
ALine Emission Cross Sections of Electron Capture Collisions for W
H + + li2 -> H(IIa, Hp)
(Ha) (_i_)Energy C_oss Section Energy Cross Section
eV/amu cm 2 eV/amu cm 2
5.0E+02 2.44E-19 5.0E+02 4.24E-20
7.0E+02 6.10E-19 7.0E+02 9,36E-20
1.0E+03 1.13E-18 ].0E+03 1.61E-19
2.0E.03 2.13E-18 2.0E+03 3.12E-19
4.0E+03 3.11E-18 4.0E+03 4.27E-19
7.0E+03 4.17E-18 7.0E+03 4.96E-19
1.0E+04 4.95E-18 1.0E404 5.17E-19
2.0E+04 7.18E-18 2.0E+04 4.82E-19
3.0E+04 8.52E-18 4.0E+04 2.94E-19
4.0E+04 7.68E-18 7.0E+04 1.lIE-19
7.0E+04. 3.34E-18 ].0E+05 4.45E-20
1.CE+05 1.25E-18 1.5E+05 1.74E-20
2.0E+05 1.06E-19
4.0E+05 4.17E-21
References: (Ha) - 131e /133, 134, 135, 136, 137, 138, 139; (H_) - 137, 138, 139
Accuracy: See notes
Notes_ (i) Large errors are usually associated with measuring optical emission from excited
states which arise from electron capture, dissooiative or excitation collisions. The
cross sections reported here are for electron capture collisions resulting in Balmer-a A
emission (n=3->2), _=6562.79 i) and Balmer-_ emission (n=4->2, k=4861.33 Al. Errors
arise mainly from the detecter calibration which for the visible spectrum varies over [
many orders of magnitude. We can only estimate the error to be more than a factor of 2
for H a .
(2) Tne H a emission cross section is found from the following relation - o(H a) = ,(3sl +
.I18,(3p) + _(3d).
(3) Cascading from upper levels contrlbu_e no more than 5% to the measured cro_s
sections.
(4) Ha cross sections below 3x103 eV/amu were found by normalizing Hess's results (ref.
137 and 138) to other results at 3x103 eV/amu.
(5) Very little data are available for Balmer-_ (H_) emission cross sections.
(6) H p cross sections below 3x103 eV/amu were found by normalizing Hess's data (refs.
137 and 138) at 3x103 eV/amu to Hughes et al data (ref. 139).
(7) No estimate is given for errors in the H_ data.
(8) Data are available for capture in the 4s state (see refs. 130 and 132).
For Chebyshev fits of the above cross sections it is necessary to use the following parameters.
(Ha) Eml n - 5.OE+02 eV/amu, Ema x _ 4.0E+05 eV/amu
(}I_) Eml n = 5.0E+02 eV/amu, Ema x = 1.5E+05 eV/amu
Cheb_shev Fitting Parameters for Cross Sections '
A0 A1 A2 A3 A4 A5 A6 A7 A8
(Ha ) -83.9403 -1.52055 -2.66B29 -.703430 -.220654 .245822 .0371514 -.0525595 -.0727916
(H_) -86.8907 -.394318 -1.51191 -.164906 -.148036 .0816213 .0463644 .0309715 .00687359
The fit represents the (Ha) cross section with an rms deviation of 2.2%.
The maximum deviation is 5.1% at 2.0E+04 eV/amu.
The fit represents the (Hp) cross section wlth an rms deviation of 0.6%.
The maximum deviation is 1.1% at 1.0E+03 eV/amu.
See appendix for Chebyshev fit details, i
B-19
H+ + H2 -> H(H, H;)
Cross Section vs. Energy
4f'_-/i,...)'17 - 1 I I IIIII I' I I i'i Itil I " i I .I t I r'lFi I I i t llttr
f \ z_- (H_)
io-,__,/ 1 _-_Ho>: / / -, --
_ -C.)
c-O
';_ 10-19_(b _-
(._ -
r,.f) -
0
U
10-2c= =
: i -- Recommended- -Data
Chebyshev Fit10 -21 i i i ilitil i i liliiil i i lillill ,I i iliilili
ld ld 104 ld 106Energy (eV/a m u)
i
B-20
0Electron CaptUre Cross Sections for
H + + H 2 -> H(3s,3p,3d) 4. H2 +
H(3B) El(3p) H(3d)
Energy Cross Section Energy Cross Section Energy Cross Section
eV/amu cm 2' eV/amu cm 2 eV/amu cm 2
1.0E+03 3.33E-19 2.2E+03 1.1BE-18 1.4E+03 4.27E-19
2.0E+03 5.25E-19 4.0E+03 3.49E-18 2.0E+03 5.56E-19
4.0E+03 8.67E-19 5.9E+03 4.19E-18 4.0E+03 8.89E-19
7.0E+03 1.45E-18 7.0E+03 4.17E-18 7.0E+03 1.27E-18
1.0E+04 2.10E-18 1.0E+04 3.86E-18 1.0E+04 1.57E-18
2.0E+04 4.90E-18 2.0E+04 2.83E-18 1.1E+04 1.60E-18
3.2E+04 7.21E-18 3.2E+04 1.63E-18 2.0E+04 1.04E-18
4.0E+04 6.54E-18 4.0E+04 1.07E-18 4.0E+04 3.94E-19
7.0E+04 2.88E-18 7.0E+04 2.96E-19 7.0E+04 1.03E-19
1.0E+05 1.16E-18 1.0E+05 1.35E-19 1.0E+05 3.09E-20
2.0E+05 9.99E-20 1.6E+05 4.76E-20 1.4E+05 8.93E-21
3.0E+05 1.83E-20 2.0E+05 3.13E-20 2.0E+05 4.39E-21
3.4E+05 1.01E-20 3.0E+05 2.47E-21
Referencesl H(3s) 129, 130, 131, 132, 133, 134, 135; H(3p) 122, 131, 133, 134, 136; H(3d) 131,134, 136
Accuracy= See notes
Notesz (I) Large error s are usually associated with measuring optical emission from excited
states which arise either from electron capture, dissociative, or excitation collisions.
The cross sections reported here are for electron capture of the fast proton into a fast
H atom. Errors arise m alnly from absolute calibration of the detector which for the
visible spectrum varies over orders of magnitude from blue to red. We estimate the data ,_
presented to be accurate to a factor of 2.
(2) The cross section (a i ) for capture into state i is determined by measuring the
emission cross section (_lj) for a transition from state i to J, correcting for any
branching from state i and correcting for cascading from upper states.
(3) For the n=3 levels cascading is less than 5%.
For Chebyshov fits of the above cross sections lt is necessary to use the following parameters.
H(3s) Eml n = 1.0E+03 eV/amu, Ems x = 3.0E+05 eV/amu
H(3p) Emi n = 2.2E+03 eV/amu, Ema x = 3.4E+05 eV/amu
H(3d) Eml n = 1.4E+03 eV/amu, Ema x = 3_0E+05 eV/amu
Chebyshev Fittln_ Parameters for Cross Sections :
A0 A1 A2 A3 A4 A5 A6 A7 A8
H(3s) -84.0392 -.728083 -2.03457 -.860699 .0489259 .212089 .0319211 -.0748778 -.0241098
}](3p) -84.5768 -2.13107 -1.38696 .326474 .0471408 .0427739 -.0758510 -.0181499 .0430074
H(3d) -86.9132 -2.76179 -1.74766 .0813682 .392354 .101286 .0203703 .00824074 -.0805033
The flt represents the H(3s) cross section with an rms deviation of 2.3%.
The maximum deviation Is 4.0% at 7.0E+04 eV/amu.
The fit represents the H(3p) cross section with an rms deviation of 1.3%.
The maximum deviation is 2.6% at 1.6E+05 eV/amu.
The flt represents the H(3d) cross section with an rms deviation of 5.0_.
The maximum deviation Is 10.4% at 7.0E+03 eV/amu.
See appendix for Chebyshev flt details.
B-21
H+ + H_ > H(3s, 3p, 3d)
Cross Section vs. Energy
10 -2' _
- - Recommended
- _'_ - _Data
...... Chebyshev Fit10-21. 1 1 I 1 lllll 1 I 1 1 II111 ,, 1 I I I I II1
ld lO" 18 lo_Energy (eV/am u)
0
' B-22
Electron Capture Cross Sections fOr O
H + + He -> H(2s) + He +
r
Energy Velocity Cross Section
(eV/am u ) (cs/s ) (cm 2 )
2.8E+03 7.35E+07 5.!6E-20
4.0E+03 8.79E+07 1.45E-]9
7.0E+03 I_]6E+08 5.91E-19
1,0E+04 1.39E+08 1.03E-18
1.4E+04 1.64E+08 1.47E-18
2.0E+04 1.96E+D8 2.44E-18
3 0E+04 2.41E+D8 5.61E-18
4.0E+04 2.78E+08 7.74E-18
5.0E+04 3.11E+08 8.08E-18
7.0E+04 3.68E+08 6.60E_18
1.0E+05 4.39E+08 3.75E-18
2.0E+05 6.21E+08 4.23E-19
References: 16, 121, 125, 126, 183, 184, 189, 190, 191
AccUracy: 50%
Note: (i) The _(2s) cross section is found by mixing the 2s state with the 2p state by anelectric field.
QFor Chebyshev fit of the above cross sections it is necessary to use the following parameters.
Eml n = 2.8E+03 eV/alnu, Ema x = 2.0E+05 eV/amu
Chebyshev Fittinq Parameters for Cross Sections
A0 A1 A2 A3 A4 A5 A6 A7 A8
•-83.0478 1.54023 -1.55597 -.364564 -.186200 .0423931 -.0198717 -.166625 -.0726702
The fit represents the above cross sections with an rms deviation of 2.5%.
The maximum deviation is 4.2% at 5.0E+04 eV/amu.
See appendix for Chebyshev fit details.
B-23
i
H+ + He->H(2s) + He+
Cross Section vs, Ener9y,,
10-17_ 'j i i i i"1111 i r i'i iii'li i i "1 i IIIL
10 -2 _ 1 I 1 i i i iii 1 i l i i i Iii i i i L_LLIJ
103 104. i105 106Energy (eV/clm u)
ASlect['oa Capture Rate Coefficients for
li "t _, lie -> 1I(2S) + lie 't*
Maxwellian- Maxw_llian Rate Coefficients (cm3/s)
H+
Temp, Equal He Temp, (eV)
(eV) Temp, 500. i000. 2000, 4000, 7000, i0000. 20000,
2.0E+02 2.85E-16 3,73E-15 4.23E-14 4.60E-13 3.64E-12 1.48E-II 3.22E-II 1,30E-10
4.0E+02 8.08E-14 1.07E-13 3.25E-13 ].32E-]2 5.90E-12 1,89E-ll 3.78E-I] 1,40E-10
7.0E+02 1.1BE-12 9.32E-13 1.61E-12 3,64E-12 ],03E-ll 2.58E-II 4.68E-II 1,57E-I0
1,0E+03 4.16E-12 2.94E-12 4.16E-12 7,24E-12 1,58E-II 3.35E-11 5.68E-II 1.74E-]0
2.0E+03 2.70E-11 1.83E-Ii 2.11E-ll 2.70E-II 4.07E-II 6.58E-II 9.64E-I! 2.35E-.I0
4.0E+03 1.20E-10 8.03E-II 8.55E-II 9.64E-II 1.20E-10 ],59E-I0 2,03E-10 3.72E-I0
7.0E+03 3.54E-I0 2.43E-I0 2.5_E-I0 2.68E-i0 3.02E-i0 3.54E-I0 4.08E-I0 5,86E-I0
1.0E+04 6.20E-I0 4.53E-I0 4,62E-I0 4.80E-i0 5.15E-10 5.68E-I0 6.20E-I0 7,81E-I0
2.0E+04 1.2]E-09 1.04E-09 1.05E-09 1.06E-09 1,08E-09 1,lIE-09 I.]3E-09 1.21E-09
Netes_ For Chebyshev fits of the above rateJ coefficients it is necessary to use the following parameters.
Emi n = 2.0E+02 eV, Ema × = 2.0E+04 eV
Chebyshev FittinH Parameters for Rate Coefficients
tie
Temp'r @(eV) A0 A1 A2 A3 A4 A5 A6
500. -5.]5547E+01 6,12867E+00 -l,I0703E+00 1,83503E-01 -6.31506E-02 -4.18133E-02 -5.16887E-03
i000. -5.02988E+01 5,12782E+00 -5.67743E-01 -2_34476E-02 -1.29792E-02 -4.58512E-02 -5 85869E-03
2000. -4,88467E+01 4.04429E+00 -9.26042E-02 -1.42687E-01 -l.51195E-02 -3.17168E-02 -6 62145E-03
4000. -4.73254E+01 3.01860E+00 2,18123E-01.-1,57987E-0] -4.76884E-02 -1.64944E-02 -i 207]IE-03
7000. -4.60971E+01 2.29486E+00 3.28511E-01 -].26781E-01 -6.47340E-02 -I.05302E-02 4 12821E-03
i0000. -4.53140E+01 1.88943E+00 3.36913E-01 -I.00227E-01 -6.44137E-02 -9.37217E-03 4 93922E-03
20000. -4.37344E+01 1.17101E+00 2.58458E-0i -4.78379E-02 -4.40287E-02 -8.69295E-03 2 45757E-03
Equal Temp. -5.19683E+01 7.03024E+00 -1.90084E+00 5.72322E-01 -2.68910E-01 2.6638lE-02 -i ]5409E-02
See appendix for Chebyshev fit details.
I-I4. + He ->t-1(2s) + He* ,,
I_-20
E],c_ctron CapfUL'C: flare Coof[JcJ.enLu for U
ll(i.I.II"I -> iI(2_I} .I II(_IV
Bo_m .- Maxwe]J.{an Rate Coef.'l_:lcJ, ent_i ((;ill;J/n)
II +
'i'omp, , ilo Energy (oV/alIILI)
(eV) I0000, 20000, 40000, 60000, 80000, l(iO(iO0, 120000,
I,OE+O0 I 43E-],0'* 4,81E-10'* 2,14E-09' 2 46E-09' 2 ]OE-,09** 1 64E-09'* I 02E-Og_A
2,0E+00 1 431..',-10'* 4,EIIE-IO** 2,14E-09' 2 461'3-09' 2 ]OE-09** 1 64E.-09'* I 021i',-09'*
4,0E+00 1 43E-10'* 4.B2E-lO** 2,14E-09' 2, 46E-09' 2 1DE-D9** 1 64E-.09'* 1 02E-09'*
7,0E'I'00 ] 42E-10'* 4,84E-I0' 2.14E-.09' 2 46E"09 * 2 10E-09 * i 64E-09'* 1 02E-09'*
_.0E-i'0] ] 42E-10'* 4.85E-I0' 2,]3E-09' 2 46E'°09 * 2 ]0EL09 * i 63E-09'* 1 02E-09'*
,2.0E+01 ] 42E-.10'* 4.88E-I0' 2,13E-09' 2 46E.-09' 2 10E-09* 1 63E'-09' .I (}2E-09'*
4,0E+01 1 43E-I0' 4,93E-I0' 2.]2E-09' 2 46E-09' 2 ]0E-09* 1 621!:-09' 1 02E-09'*
7,0E+01 1 44E-I0' 5.00E-10' 2,11E-09' 2 46E-09' 2 10E-09' ] 61E-09* i 02E-09'*
1,0E+02 i 45E-10' 5,07E-I0' 2,11E-09' 2 46E-09' 2 10E-09' I 61E-09' 1,02E-09'*
2.0E.i.02 ] 49E-I0' 5,28E-I0' 2,09E-09' 2 46E-09' 2 10E-09* ] 59E-09' 1.03F.-09'*
4.0E+02 1 59E-I0' 5.68E-I0' 2.07E.-09' 2 45E-09' 2 09E-09' 1 57E'-09' 1,03E-09'
7.0E+02 I 77E-10' 6.23E-10' 2.05E-09' 2 42E-09' 2 08E-09' ] 56E-09' ].04E-09'
1.0E+03 1,97E-I0' 6.73E-I0' 2,03E-09' 2 39E-09' 2 06E-09' 1 54E-09' 1.05E-09'
2.0E+03 2.79E-I0' 8.12E-I0' 1,98E-09' 2 29E-'09' I 99N-09' 1 51E-09' 1.06E-09'
4.0E+03 4.63E-I0' 1.01E-09* 1,90E-09 2 ]2E-09' 1 87E-09' I 46E-09' 1,07E-09'
7,0E+03 7.1lE--10 1.19E.-09 1.81E-09 ] 92E-09' I 72E-09' ] 38E-09' 1.05E-09'
1.0E+04 9.07E-I0 1.29E-09 1,73E--09 1.78E+'09 * 1 59E-'09' 1 3.1E-09' 1,02E-09 _
2.0E+04 1.27E-.09 1.42E-09 1,54E-09 1.47E.-09" ] 31E-09' ] ]2E-09' 9,16F.-I0'
hocuraeyz * - Posslble Error Greater Than 10%
• * - Possible Error Greater q'han 100%
Notes! For Chebyshev fits of the above rate coefflclents it Is necessary to use the following pa[ameterE_,
Eml n = 1,0Ei.00 eV, Ema x = 2,0E+04 eV
C hobyshev Fitting[ Parameters for Rate Coefflcients
lle
Energy
(eV/amu) A0 A] A2 A3 A4 A5 A6
i0000, -4,41473E+01 1.00293E+00 5.77264E-01 1.69345E-01 -4 2027_E-02 -7 828191,,'-02 -4.04936E-02
20000. -4,22126E+01 5°46817E.-01 2.44571E-01 2.72848E-02 -4 37757E-02 -3 23001E-02-7.5661:_E-03
40000. -4.00821E+01 -] ,29340E~01 -7.1612}E-02 -3,33138E-02 -] 32072E-02 -4 05181E-03 -1.23221E-03
60000. -3,98602E+01 -1.91480E-01 -1,30757E-01 -6,51877E-02 -2 04843E-02 -i 38003E-03 2.]2462E-'03
80000, -4°01499E+01 -].662]IE-0] -],18429E-01 -6.40569E-,02 -2 40368E-.02 -4 53618E-03 8.86157E-04
i00000, -4,06316E+01 -1,42(]02E-0] -8.01346E-02 -4.14812E-02 -2 ]5460E-02 -9 87334E-03 -2.92063E-03
120000, -4o]_]46E+01 -].03802E-02 -2.66264E-02 -3.]3729E-02 -2 24983E-02 -1 04122E-02 -2,88295E-03
See appendix for ChObyl:tllev [:Jt de£alls.
ii
He + bl+ ->H(2s) -t- He+
O, 0 ___L__LL_LLLL___.L__LL ! I I ii! !__L.LLLLtIL_-L__LLLLLLIL_-L-L-M-LI-II
io° ld ld: io:' ld' ldH" l_ mp. (eV)
0
13-28
A_JleoLron, Capture Cross Sections fo['
H+ + lie -> 11(2p) 4, Ilo+
l_ne_gy Velocity (.'rossSoot ten
(ev/al. u) (oi,/_l ) (ota2)
7,0E+02 3,68E+07 2,02E-20
I,(iI,_+03 4,39E+07 4,40E-20
2,0E+03 6,21 E+07 2,10E-I 9
4,0E+03 8,79E+07 6,83E-19
7,0E+03 1,16E+08 1,57E-18
i,0E404 1,39 E.i00 2,32_I-18
2,0E+04 I, 96E+08 3,14E-18
3,0E+04 2,41E+08 2,88E-18
4,0E+04 2,78E+08 2,17P,-18
7,0E+04 3,60E+08 8,52E-19
i,0E+05 4,39E+08 3,93P,-19
2,0E+05 6,21E+08 3,86E-20
3,0_,+05 7,61_+08 9,74P,-21
RsferenasBl 24, 46, 125, 163, 164, 165 166, 183, 184, 185, 186, 187, 188t 245
A_oou rae,V l 30%
O._ee___! (11 If cascade la neglected o(H i,y_) = o(lI 2p), Cascade eontrlbutions are less than 5%,
(2) The CFOBB seotlonB for capture into the 2p state or I.y_ einlsslon have large
discrepancies at energies less than ixl04 eV/ainu. [Phese disorepan(;les are thought to be
due to a small amount of |I° present In the II+ beain fluting Ii,eas_rements, The arose
sec,,tlonfor e}(aJtatlon of II4 Ile -> ll(2p) Is approxIInatly 2 orc]ore of magnitude greaterthan H+ + He -> H(2p) + Ile+,
Pcr a Chebyshev fit o,[ the above areas sections it In necessary to use the fo]lowlng paraineters,P'inln= 7,0E+02 eV/alnu, Ems x = 3,0E+05 eV/ainu
Ch2b_s|iev Pitting Parameters for Cross Seotlolls
AO Al A2 A3 A4 A5 A6 A7 AB
-86.2710 -,0743636 -2.70622 -.368010 ,07439] 6 .0747662 .0195366 ,00225497 ,0337284
_'he fit represents the above cross sections with an rillsdeviation of 1,9%.
The maxlinuindeviation is 4,1% at 7,0E+04 eV/alnu,
See appendix for Chebyshev flt details,
i
13.-,2,f_
ii
H+ + Pie ->H(2p) + He+
i
(_. °Cross ectlon vs. F__nergy
.1__7. ...........I .....I"l"llltll '1 '1 1 111111 _I-I I I'I'T'I'I I i' I i IliI-L--
10-I _
li _E - -L)
C©
10-19_ _t.._eb ":'_
(/-)
0 ,- RecommendedU ---Data
10-2<_ ..: _ Chebyshev Fit
'lq 2 i 1 i i Iii.li I 1. i 1 lilil ,4_ i._i iiilil i __i i 1 iii
'ld ld 104 ;d ld, Energy (eV/mmu)
b
AElectron Capture Rate Coeffioients for
H + + lle -> H(2p) + {]s+
Maxwellian - Maxwellian Rate Coeffloients (cm3/s)
II+
_'emp. _qual [le Temp. (eV)
(eV) Tsmp. I00. i000. 2000. 4000. 7000. 30000. 20000.
4.0E+01 3.31E-18 7.92E-17 4.90E-13 2.90E-12 1.36E-II 4 lIE-II 7.62E-II I. 98E-I0
7.0E+01 1.22E-15 2.29_-15 6.69E-13 3.33E-12 1.45E-II 4 25E-II 7.77E-ii 1.99E-IO
1.0E+02 1,36E-14 1,36E-14 8.78E-13 3.79E-12 1,54E-II 4 38E-II 7,92E-II 2,00E-10
2.0E+02 2.97E-13 2.03E-13 1.79E-12 5.52E-12 3.85E-II 4 82E-II 8.41E-13 2.05E-I0
4.0E+02 2.38E-]2 1.53E-12 4.61E-12 9.89E-12 2.55E-II 5 74E-II 9.42E-II 2.13E-I0
7.0E+02 9.28E-12 6.00E-12 1.12E-II 1.85E-II 3 73E-II 7 18E-ll 1.09E-10 2.26E-I0
1.0E+03 2.02E-II 1.32E-II 2.02E-II 2.93E-Ii 5 05E.Ii 8 66E-II 1 24E-I0 2.38E-i0
2,0E+03 7.43E--II 5,i6E-ii 6,21E-II 7.43E-II _ 9 92E-II 1,37E-30 1 73E-I0 2,75E-i0
4.0E+03 1.96E-I0 1.50E-10 1.61E-10 1.73E-I0 1 96E-I0 2.28E-I0 2 57E-]0 3.34E-I0
7,0E+03 3,27E-10 2,76E-I0 2.83E-i0 2,92E-I0 3 07E-10 3,27E-I0 3 45E-]0 3,91E-I0
l,OE+04 3.98E-I0 3.57E-I0 3,62E-I0 3.66E-I0 3 75E-I0 3.87E-I0 3 98E.-I0 4.22E-I0
2.0E+04 4,33E-I0 4.38E-I0 4.39E-I0 4.39E-I0 4 39E-I0 4,38E-I0 4 38E-I0 4,33E-I0
Notess For Chebyshev fits of the above rate coefficients it is necessary to use the following parameters.
Eml n = 4.0E+0] eV, Ems x = 2.0E+04 eV
Chebyshev Fittin_ Parameters for Rate Coefficients O
'He
Temp.
(eV) AO A1 A2 A3 A4 A5 A6
i00 -5,42320E+01 7,44291E+00 -2.03521E+00 2.94202E,-01 -I.85784E-01 2,90590E-02 2.43336E-02
i000 -4,97005E+01 3,78186E+00 -7.01113E-02 -4.11509E-01-2,83920E-02 2.87633E'02 2,44756E-03
2000 -4.83079E401 2,82754E+00 1,63410E-01 -3.46227E-01 -7.46954E-02 2 85450E-02 8,40255E-03
4000 -4.69020E+01 1,95707E+00 2.50111E-01 -2.30851E-01 -9.41042E-02 9 45349E-03 1.19992E-02
7000 -4,57899E+0l 1.32780E+00 2,41351E-01 -I.38821E-01 -8.61534E-02 -'6 49649E-03 8.83775E-03
i0000 -4.51295E+01 9.78457E-01 2,08879E-01 -9,24217E-02 -7.29486E-02 -i 27985E-02 5,37477E-03
20000. -4.40453E+01 4,43773E-01 3,]2537E-01 -3.78696E-02 -4,20886E-02 -i 39142E-02 -2.7445]E-04
Equal Temp, -5.47397E+01 8,28139E+00 -2.97971E+00 8.65229E-01 -5,12815E.01 I 97141E-01 -4.18893E-02
See appendix for Chebyshev fit details.
@
B-31
H* + He->H(2p) + He*
Maxwellian- Maxwellian
B.-32
Electron Capture Rate Coefficients for OHe + H + -> H(2p) + He +
Beam - Ma×wellian Rate Coefficients (cm3/s)
H +
Temp. He Energy (eV/amu)
(eV) i0000 20000. 40000. 60000. 80000. i00000. 200000.
1.0E+00 3.21E-I0 6.15E-I0 6.02E-I0 3.75E-I0 2.51E-I0" 1.72E-I0" 2.40E-II**
2.0E+00 3.2]E-I0 6 15E-10 6.01E-ID 3.75E-I0' 2.51E-I0" 1.72E-I0, 2.40E-II**
4.0E+00 3,20E--10 6.14E-I0 6 01E-10 3.75E-I0' 2.51E,I0" 1.72E-I0" 2.40E-II**
7.0E.00 3.20E-I0 6.13E-I0 6.00E-10 3.75E-I0 2.51E-I0" 1.72E-I0, 2.40E.-II**
1.0E+01 3.19E-I0 6.12E-I0 5.99E-I0 3.75E-I0 2.51E-I0" 1.72E-I0" 2.40E-II**
2.0E+01 3.18E-I0 6.10E-10 5.98E-I0 3.75E-I0 2.51E-I0" 1.71E-10* 2.40E-II**
4.0E+01 3.18E-I0 6.08E-I0 5.96E-I0 3.75E-I0 2.51E-I0 1.71E-10* 2.40E-II**
7.0E+01 3.17E-I0 6.05E-I0 5,93E-I0 3_75E-I0 2.51E-I0 ].70E-10* 2.40E-II**
1.0E+02 3.17E-i0 6.03E-I0 5_92E-I0 3.76E-I0 2.51E-I0 1.70E-10* 2.40E-II**
2.0E+02 3,19E-I0 5.99E-I0 5.87E-I0 3.76E-]0 2.52E-I0 1.69E-I0" 2.41E-II**
4.0E+02 3.25E-I0 5.94E-I0 5.81E-I0 3.76E-I0 2.52E-I0 1.68E-10 2.43E-II**
7.0E+02 3.35E-!0 5,88E-I0 5.72E-I0 3.77E-I0 2.52E-I0 1.68E-I0 2.45E-II**
1.0E+03 3.46E-I0 5.82E-I0 5.64E-I0 3.77E-I0 2.53E-I0 1.68E-I0 2.48E-11,*
1 2.0E+03 3.75E-I0 5.64E-I0 5.41E-I0 3.75E-I0 2.53E-I0 1.68E-I0 2.56E-II*
4.0E+03 4.13E-I0 5.34E-I0 5.02E-I0 3.66E_I0 2.52E-I0 1.71E-10 2.75E-II*
7,0E+03 4.40E-I0 5.01E-10 4.58E-10 3.49E-I0 2.49E-I0 1.74E-10 3.04E-II*
1.0E+04 4.50E-I0 4.75E-I0 4.24E-I0 3.31E-I0 2.44E-I0 1.75E-I0 3.34E-II* O2.0E+04 4.33E-I0 4.12E-I0 3.51E-I0 2.83E-I0 2.22E-I0 1.71E-10 4.25E-II*
Accuracy: * - Possible Error Greater Than 10%
• * - Possible Error Greater Than 100%
Notes: For Chebyshev fits of the above rate coefficients it is necessary to use the following parameters.
Emi n = 1.0E+00 eV, Ema x = 2.0E+04 eV
C__hgbyshev Fitting Parameters for Rate CoefficientnHe
E
Energy
(eV/amu) AO A1 A2 A3 A4 A5 A6
i0000_ -4.35175E+01 ].70837E-01 8,90710E-02 3.52059E-03 -3.19243E-02 -2.56283E-02 -9.06765E-03
20000. -4.26087E+01 -1.54555E-01 -8.94632E-02 -4.26611E-02 -1.61171E-02 -3.24065E-03 7.74472E-04
40000. -4.27]12E+01 -2.07196E-01 -1.26305E-01 -5.98268E-02 -2.07064E-02 -3.39655E-03 1.43741E-03
60000. -4.34961E+01 -8.32780E-02 -6.90413E-02 -4.75586E-02 -2.57998E-02 -I,00636E-02 -1.67943E-03
80000. -4.42403E+01 -2.77368E-02 -2.78472E-02 -2.36213E-02 -1.56284E-02 -8.38900E-03 -4.20444E-03
i00000. -4.49754E+01 -4.83485E-04 1.15859E-02 4.48823E-03 -4.64650E,03 -6.95457E-03 -5.16220E-03
200000. -4.86802E+01 2.01513E-01 1.40611E-01 7.66020E-02 3.17782E-02 8.85564E-03 7.47137E-05
See appendix for Chebyshev fit details.
B-33
He + H*-> H(2p) + He*
Be<am- Moxwellion
0 9. I I I 111111 I' I I IIIill I I I III11_ .... I I I II111_ 1 I I IIIII__
- He Energy
........ (eV/amu)
- A --10000.
x -- 20000.
v --40000.
_'_ -- _ --60000.P_
E ----'_o • --80000.+-,C® lc m --100000.'o 10- --_- _ --200000.(DO
U(U - Recommended
.+..,o - --Data
rY
- Chebyshev Fit
......
lo_ lo" lo_100 10' HIO'_Temp. (eV)
B-34
ALine Emission Cross Sections of Electron Capture Collisions for W
11+ + He -> H(lla) + lle+
(
Energy Velocity Cross Section
(eV/amu ) (cm/s) (cre2 )
1.3E+03 5.01E+07 5 94E-21
2.0E+03 6.21E+07 1 62E-20
4.0E+03 8.79E+07 6 73E-20
7.0E+03 1.16E+08 2 14E-19
1.0E+04 1.39E+08 4 29E-19
2.0E+04 1.96E+08 1 45E-18
4.0E+04 2.78E+08 2.92E-18
7.1E+04 3.70E+08 1.90E-18
1.0E+05 4.39E+08 1.13E-18
2.0E+05 6.21E+08 1.74E-19
3.0E+05 7.61E+08 4.13E-20
_eferences: 122, 134, 136, 136, 156, 160, 192
Accuracy__ 40%
Notes: (i) H Balmer-a emission is H a with _=556.3 nm.
(2) Balmer-a emission is the n=3->2 transition and is equal to a(3s) + .118 _(3p) +
-(3d) where o(31) is the cross section for capture into each n=3 angular momentum state.
The factor .I18 is for the branching ratio of the 3p state, i
(3) If the cross sections from pages B-40, B-46 and B-52 are summed using this formula
then the H a cross sections are within 10-20% o_ the evaluated sums.
For a Chebyshev fit of the above cross sections it is necessary to use the following parameters.
Emi n = 1.3E+D3 eV/amu, Ema x = 3.0E+05 eV/amu
Cheb_shev Fitting P_rameters for Cross Sectlons
AO A1 A2 A3 A4 A5 A6 A7 A8
-86.7431 1.47945 -2.26092 -.605332 .0536620 .125835 -.00401562 -.0314533 -.0205645
The fit represents the above cross sections with an rms deviation of 2.4%.
The maximum deviation is 5.5% at 7.1E+04 eV/amu.
See appendix for Chebyshev fit details.
B-35
H_ + He->H(H) + He+
Cross Section vs. Energy
0 7- "'" I " I " I I I 1 II I I T I I I I 111 I I I I 1 I I,/
- "/"/_-_X -/
_: / / :::_E - /
.0 1_. / \g lo- / \ -:® // -m \ :ffl -
LO RecommendedU / Dc]to
///
10-2( /// Chebyshev Fit
/
10-21 i i I J l iJJl 1 1 ..1 l I fill I I _1 I l l,f
10s 10' 105 100Energy (eV/am u)
B-36
Line Em,lssion Rate Coefficients of El_ectron Capture 'Collisions for
H+ + He -> H(H{_) + lle +
Maxwellian - Maxwellian Rate Coefficients (cm3/s)
11+
Temp. Equal He Temp. (eV)
(eV) Temp. 100. 500 1000. 5000, 10000. 15000. 20000.
1.0E+02 4.62E-17 4.62E-17 4.63E-15 4 liE-14 2.61E-12 I. 33E-11 3.27E-II 5.90E-II
2.0E+02 8.39E-15 4.63E-15 3.00E-14 i 07E-13 3.14E-12 I. 45E-II 3.45E-ii 6.13E-II
4.0E+02 _.54E-13 8.75E-14 1.81E-13 3 53E-13 4.36E-12 1.72E-II 3.84E-II 6.61E-II
7.0E+02 8.25E-13 4.86E-13 7.01E-13 1 03E-12 6.62E-12 2.16E-II 4.46E-II 7.34E-II
1.0E+03 2.14E-12 1.27E-12 1.62E-12 2 14E-12 9.40E-12 2.64E-II 5.11E-II 8.10E-II
2.0E+03 1.21E-II 7.26E-12 8.18E-12 9 40E-12 2.24E-II 4.56E-II 7.47E-II 1.07E-10
4.0E+03 5.67E-II 3.60E-II 3_79E-11 4 O4E-II 6.25E-II 9.38E-II 1.27E-I0 i.61E-10
7.0E+03 1.54E-I0 1.08E-J0 1.10E-10 1.14E-10 1.41E-10 1.75E-10 2.07E-I0 2.38E-I0
1.0E+04 2.49E-I0 1.88E-I0 1.91E-10 !.94E-.I0 2.20E-I0 2.49E-I0 2.77E-I0 3.02E-I0
2.0E+04 4.27E-I0 3.80E-I0 3.81E-I0 3.83E-I0 3.94E-I0 4.07E-I0 4.18E-I0 4.27E-I0
Notes: For Chebyshev fits of the above rate coefficients it is necessary to use the following parameters.
Emi n = 1.0E+02 eV, Ema x = 2.0E+04 eV
Cheb_shev Fitting Parameters for Rate Coefficients AHe
Temp.
(eV) AO A1 A2 A3 A4 A5 A6
i00 -5.56271E+01 7.54225E+00 -1.58664E+00 3.76818E-01 -2.66300E-01 4_31633E-02 1.35706E-02
500 -5.35452E+01 5.80636E+00 -5.23960E'01 -1.37429E-01 -6.79972E-02 -9.79835E-03 1.77516E-02
i000 -5.22967E+01 4.84928E+00 -61.69532E-02 -2.78274E-01 -4.61871E-02 -1.88369E-03 9.07721E-03
5000 -4.89693E+01 2.71099E+00 4.02894E-01 -2.04786E-NI -8.92702E-02 1.65791E-03 8.93841E-03
i0000 -4.72849E+01 1.82717E+00 3.81313E-01 -I.07442E-01 -7.83908E-02-9.54437E-03 6.43829E-03
15000 14.62748E+01 1.34714E+00 3.25406E-01 -6.01114E-02 -6.20496E-02 -1.28087E-02 3.45512E-03
20000 -4.55796E+01 1.03752E+00 2.73271E-01 -3.47245E-02 -4.87660E-02 -1.29500E-02 1.49966E-03
Equal Temp. ,5.48859E401 7.46410E+00 -1.79561E+00 4.52870E-01 -3.47418E-01 1.03439E-01 -8.24563E-03
See appendix for Chebyshev fit details.
B-.,3"I
H* --I- He->H(H) + He*
MoxwelliGn - MclxwelliGn
B-38
Line Emission Rate Coefficients of Electron Capture Collisions fo[ _
lle + 11. -> f1([1_) + lie .
Beam - Maxwellian _te Coe_ficients (cm3/s)
H+
Temp_ Ilo E_ergy (eV/ainu)
(eV) 10000. 20000. 40000, 60000. 80000. i00000. 200000.
' 1.0E+00 5.96E-II* 2.84E-I0' 8,07E-I0' 7.33E-I0' 6.23E-I0' 4.95E-I0' 1.08E-10'*
2.0E+00 5,96E.-II* 2.84E-10' 8.06E-10' 7.33E-10' 6.23E-I0' 4,95E-10' 1,08E-10**
4.0E+00 5.96E-]I* 2.83E-I0' 8.03E-I0' 7.33E-I0' 6,23E-I0' 4.94E-10' 1,0BE-10**
7 0E+00 5.97E-II* 2.83E-I0* 8,01E-10' 7,33E-I0' 6.23E-I0' 4.94E-I0' ].08E-10**
1 0E.01 5.98E-II* 2,83E-I0' 7.99E-I0 7.33E-I0' 6,23E-I0' 4.93E-10' 1.OBE-10**
2 0E+01 6,01E-II* 2.82E-I0 7.94E-I0 7.33E-I0' 6.23E-I0' 4,92E-I0' 1.08E-10'*
4 0E+01 6.08E-II* 2.82E-I0 7.87E-I0 7.33EIi0 6.23E-I0' 4.90E-I0' I.()TE-10**
7 0E+01 6.18E-II* 2.82E-I0 7.80E'I0 7.33E-I0 6.23E-I0' 4,88E-I0' 1.07E-10 _*
1 0E+02 6.29E-II* 2.83E-I0 7.74E-I0 7.33E-10 6,23E-I0, 4.87E-I0' 1.07E-10**
2 0E+02 6.67E-II 2.85E-I0 7.60E-10 7.33E-I0 6,23E-I0 4.84E-I0' 1.07E-10**
4.0E+02 7.45E-II 2.92E-I0 7.42E-I0 7.31E-10 6.21E-I0 4.79E-I0' I°07E-10**
7.0E+02 8.65E-II 3.04E-10 7.24E-I0 7.27E-I0 6.17E-I0 4.75E-I0' 1.07E-10**
1.0E+03 9.83E-II 3.16E-I0 7.11E-10 7.22E-I0 6 12E-J0 4.72E-I0' 1.07E. 10**
2.0E+03 1.36E-10 3.52E-I0 6.80E-I0 7.02E-I0 5 97E-I0 4,64E-I0' ].09E-10*
4.0E+03 2.05E-I0 4.00E-10 6.43E-I0 6.60E-I0 5 69E-10 4.51E-10 1.12E-10*
7_0E+03 2.87E-I0 _ 4.40E-I0 6.04E-I0 6.08E-I0 5 33E-I0 4.33E-I0 ],I7E-10*
1.0E+04 3.46E-I0 4.63E-I0 5.75E-I0 5.68E-I0 5 02E-10 4.16E-I0 1.22E-I0'
2.0E+04 4.46E-I0 4.86E-I0 5.07E-I0 4.79E-I0 4 27E-I0 3.67E-I0 1.33E-I0' _
Accuracy: * - Possible Error Greater Than !0%
• * - Possible Error Greater Than 100%
Notes: For Chebyshev fits of the above rate coefficients it is necessary to use the following parameters.
Eml n = 1.0E+00 eV, Ema x = 2.0E+04 eV
C_h_heb_shev Fitting Parameters for Rate Coefficients
lle
Energy
(eV/amu) A0 AI A2 A3 A4 A5 A6
10000. -4.58848E+01 9.71807E-01 4.83279E'.01 9.ll]38E.-02 -6.12690E-02 -5.76723E-02 -l.79106E-02
20000. -4.36507E+01 2.64211E-01 1.43555E-01 2.70_21E-02 -2.48764E-02 -2.40082E-02-7.54802E-03
40000. -4.21414E+0] -2.00867E-01 -8.98633E-02 -2.87027E-02 -8.54506E-03 -3.26747E-03 -1.21561E-03
60000. -4.22369E+01 -1.51900E-01 -1.08731E-01 -5.90440E-02 -2.]9357E-02 -3.21591E-03 2.30144E-03
80000. -4.25414E+01 -1.32445E-01 -9.43661E-02 -5.17183E-02 -2.05460E-02 -5.15132E-03 -3.15003E-04
100000. -4.29896E+01 -I.]0475E-01 -6.22264E-02 -3.20171E-02 -1.65763E-02 -7.76766E-03 -2.70010E-03
200000. -4.58241E+01 7.16963E-02 5.83098E-02 3.32118E-02 1.21459E-02 1.47440E-03 -1.87694E-03
See appendix for Chebyshev fit details.
Q
13-39
He -t- H+ - > H(H ) -t- He"
Beam blaxwel ian
10-g ----m-TTrmTf----T--Fr-rlTrrr---r--rTFrTrq----rq-mmml--r-T-rTTrn
.... He Energy_, , -
.__ .. (eV/arnu)
.... _ -- 10000,
x --20000,
/ v --¢0000,®
-_. - _ -- 60000,
0 mE • -- 80000,0"-f /.El
c m -- I00000,_,:2ICF"-'----- -- - ',_u - / -_- - _ --200000,LI.."
_ .j/(1..) .---""' .O
U .... Recommended@4-' - -Data0
rY
- Chebyshev Fit'
t0-' _.,,,,1 i l iJlllJl. I._L.L.L_LLL 1 l,ll_JJll| __i__L2J.J2I
100 10' 102 ld 104 105H+ -l-ernp. (eV)
0
,,u,,_ l,i
I_.-40
I_lectron Capture Cross _lections for
I-I+ + Ilo -> 11(3_) _, Ils +
EneL gy Velocity Crofts Section
(eV/ainu ) (om/s) (ore2)
1.2E403 4 81_:.I,07 7.90r':-20
2.0 I.]+03 6 21E+07 9. 721_J.20
4,0E+03 8 79_+07 i, 39E-19
7.0E+03 l 16B+08 1,94E-19
1,0E+04 ] 39E+00 2,59E-19
2 0E+04 1 96E+00 6.57E.19
4 0E+04 2 78E+08 1.65E-10
4 4E+04 2 91E+08 1.67E-18
7 0E+04 3.60E+08 1.20P,-18
1 0E+05 4,39E.I08 7.58E-19
2 0E+05 6. 211_:+0R 1.65E-19
4 0E+05 8.78E+08 i,]0B-20
7.0E+05 1,16E.F09 1.16E-21
I. 0E+06 i. 39E+09 2.40E-22
i. 3E+06 l. 58E+09 6,65E-23
Refe encesl 20, 129, 130, 134, 154, 155, 156, 157, 158, 159, 160, 161
Accuracy.} unknown
e(1) Very few papers report absolute cross sections. The overall assessmenL og tile data
is in doubt due to the validity of the different normalization schemes.
(2) Cascade from higher states iS usually neglected and can contribute up to a 5% error
in the reported cross sections,
(3) The cross section (oi) for capture into state i is determined by measuring the
elnissjon cross section (aii ) for a transition from state i to J, correcting for any
branching and correcting for cascading from upper states. Pcr Balmer-_ emission from
the n=3 state, the cross section a(ll_)=a(3s) + .188 _(3p) + a(3d).
For a Chebysbev fit of the above cross sections it is necessary to use the following parameters.
Emin = 1.2E+03 eV/ainu, Ems x = 1.3E+06 eV/ainu
Chebyshev Pitting Parameters for Cross Sections
A0 A1 A2 A3 A4 A5 A6 A7 A8
-89.3963 -2.75333 -3,10976 -.952686 .352124 .248416 -.119805 -.0706000 .0607563
The fit represents the above cross sections with an rms deviation of 7.1%.
The n_aximum deviation is 12.3% at 7.0E+04 eV/ainu.
See appendix for Chebyshev fit details.
, _,,h,djw
1].-41
t'-I+ + He - > Pl(3s)i -J- He+
Cross _,uctlonvs. Energy
10-17E---T-q''r_ _wl " r--r-rTnTrl---q---r-r-rl ni/ ..... _-T-TqTrr__
lO-'°- . _
10-19 ..
Q /_._E -,_ -
_ 10- -£.) -(1) -(./3 -
O - Recomn-lerlded
U 1_ _ __ t)ataIV
" ..... ChebyshevFit
,10-_
_.. °-
]0- _: ____a._t__ J__ii ,_ ___U_L____X__X_L_.ad____L_t_J_LUa__10 10'_ 10_ 1()_ 10'
Energy (eV,4:lmu)
0
|
Eleutroll C_ptllr_ IlaL'u Cou_fJc_iQrlt_ t!or
II + + 11o -> 11(3_]) .1. II_f I
Maxwel.ltan - Maxwelltan Rate Coo[l:talelltB' (om3/_)
fl +
_'enlp, EClllal lie Temp, (oV)
(eV) Temp. 100, 500, 1000, 5000, 10000, 15000, 20000,
1.OB+D2 1.04B-15 1.04E-15 5.14E-14 3,76E-13 5.53E-12 1.30E-II 2.211E-II 3,55E-.II
2,0E+02 I. 02E-.13 6,14E-14 2,92E_,13 7,83E-13 6,07H-12 ] 36E-11 2,37E-11 3,67E-11
4,0E+02 1,02E-12 6.72E-13 1,14B-12 1,7BE-12 7,17E-12 1.51E-II 2,56E-II 3,90E-II
7.0E+02 2,98E-12 2.17E-12 2.71 F,-.12 3 30E-12 8,87E-12 1,73E-II 2,86E-I] 4,26E-II
1,0E+03 4,99E-12 3,78E-12 4,32E-12 4 99E-12 1,07E-II i, 97E-II 3,17E-II 4,63E-II
2.0E.103 1,23E-II 9,31E-12 9,91E-]2 1 07E-II I ,77E-] 1 2,91E-II 4,32_-I] 5,94E-II
4.0E+03 3,44E-II 2,44E-II 2,54E-II 2 66E-II 3,72E-II 5,27E-II 6,98E-II 8.78E-II
7,0E+03 B, 42E-II 5.98E-11 6.12E-II 6 29E-11 7,70E-ii 9,50E-] 1 1.]3E-10 1,30E-10
1.0E+04 1,37E-I0 1.03E-10 1,04E-IO 1 06E-10 1.20|,]-10 1.37E-I0 1,53E-10 1,68E-I0
2.0E+04 2.48E-I(J 2.17E-10 2,17E-10 2 IBE-]0 2,26E. ]0 2.34E-i0 2,42E-] 0 2,48E-I0
Notes! For Chobyshev fitB of the above rate ooofflcients it _s neoessar_, to use the followll]g paral, etors.Emir, = 1.0E+02 eV, Ema x -- 2,0E+04 eV
F__ittln_ Parameters for Rate Coeffloients
llo 0Temp.
(eV) AO A1 A2 A3 A4 A5 A6
i00. -5,37012E+01 5,51736E+00 -1.26631E+00 6,41819E-01 -2,59717E-01 -3.50690E-02 -8.79675E-04
500. -5,19390E+01 4,01666E.I00-2,93656E-01 1,47B07E-01 -7 57652E-02 -7,86568E-02 3,]9866E-03
1000. -5,09725E+01 3,25191E+00 1_17635E-01 -4,41960E-03 -5 45641E-02 -6,54437E-02 -4.41120E-03
5000. -4.89296E+01 1,94263E+00 4,86039E-01 -5,63401E-02 -8 7751OE-02 -3,17734E-02 -'1.68441E-04
i0000. -4.79520E+01 1,50755EI00 4.27186E-01 -3,56552E-02 -7 51944E-02 -2.47079E-02 1,68707E_03
15000. -4,72456E+01 1.22338E+00 3,57663E-01 -2.27359E-02 -5 99425E-02 -2.00776E-02 7,63417E,,04
20000. -4.66818E+01 1.00201E+00 2.99649E-01 -1,36330E-02 -4 72262E-02 -],65699E,-02 -I.65257E-05
Equal Temp, -5,31267E+01 5,47937E+00 -1,36275E.I00 6,93916E-01 -3 79924E-01 1.82789E-02 -3,07574E-03
See appendix for Chebyshev fit details.
i
B-43
, Pl* + t-le -> H(3s) + ,He+,
Mclxwcllion- MoxwelliGn
I_-44
i
Sl_;otren captuL'e Ra[:e CoefL'ieienLs tor IDlie .I. II + -> ll(3s) .I. lie +
Beam - Maxwellian Rate CoeffiCients (am3/s)
tt+
_'eml). He Energy ,(eV/ainu)
(eV) 10000, 20000, 40000, 70000, 100000, 200000, 500000,
1.0E+00 3.61E-II 1 29E-I0 4.57E-10 4.40E-10 3.32E-10 1.02_-i0 4.40E-12'
2.0E+00 3.62E.-11 ] 29E-10 4.56E-I0 4.40E-]0 3.32E-I0 1.02E-10 4.40E-12'
4.0E+00 3.62E-II 1 29E-10 4.55E-I0 4.40E-I0 3.32E-I0 1.02E-10 4.40E-12'
7.0E+00 3.63E-11 I 29E-I0 4.54E-10 4.40E-I0 3_32E-.10 1.02E-10 4.40E-]2'
1.0E+01 3.64E-II ] 29E-I0 4.54E-10 4.39E-I0 3.31E-I0 1.02E-10 4.40E-12'
2.0E+01 3.67E-II 1 30E-10 4.52E-I0 4.39E'10 3.31E.10 1.02E-10 4.41E-12'
4.0E+01 3.72E'II 1 30E-10 4.50E-I0 4.38E-10 3.30E-I0 1.01E-10 4.41E-12'
7.0E+01 3.78E-II 1 31E-10 4.47E-10 4.37E-I0 3.29E-10 1.01E-10 4.41E-12'
1.0E+02 3_83E-II 1 32Eii0 4.44E-IQ 4°36E-I0 3.28E-10 1.01E-10 4.41E...12'
2.0E+02 4.01E-II ] 35Eii0 4.38E-I0 4.33E-10 3.26E-I0 9.99E-II 4.42E-12
4.0E+02 4.35E-II 1 40E-10 4.29E-10 4.30E-10 3.24E-I0 9.92E-II 4.44E-.12
7.0E+02 4.86E-II I 49E-I0 4.19E-I0 4.27E-I0 3.21E-I0 9.86E-II 4.47E-12
1.0E_03 5.37E-II 1 57E-10 4.12E-10 4.24E-10 3.19E-10 9.82E-II 4.50E-12
2.0E+03 7.17E-II ].82E-I0 3.96E-I0 4.14E-I0 3.14E,I0 9.7BE-II 4.60E-12
4.0E403 1.08E-J0 2.16E-10 3.78E-I0 3.93E-10 3°06E-10 9.84E-]I 4.81E-12
7.0E+03 1.56E-10 2.47E-I0 3.59E-I0 3.66E-I0 2.93E-10 1.00E-10 5.14E-12
1.0E+04 1.93E-I0 2.66E-I0 3.46E-10 3.44E-I0 2.82E-I0 I°02E-10 5.51E-12 O
2.0E+04 2.61E-I0 2.90E-I0 3.13E-10 2.94E-IQ 2.48E-I0 1.06E-I0 7.04E-12
Aecuracyl * - Possible Error Greater Than 10%
•* - Posslble Error Greater Than 100%
Notes_ For Chebyshev fits of the above rate ooefficientEz it is neoessary to use the following parameters.
Eml n = 1.0E+00 eV, Ema x = 2.0E404 eV
Chebysi_ev Fitting Parameters for Rate Coeffioientslie
Energy
(eV/amu) A0 Al A2 A3 A4 A5 A6
10000. -4.69590E+01 9.17776E-01 4.84822E-01 1.28148E-01-3.38227E_02 -5.58964E-02 -2.93167E-02
20000. -4.50524E+01 3.95677E-01 1.97669E-01 3.56569E-02 -3.01554E-02 -2.88658E-02 -8.74226E-03
40000. -4.32289E+01 -].65074E-01 -7.60355E-02 -2.21081E-02 -4.24972E-03 -I._2033E_03 -1.77544E-03
70000. -4.32620E+01 -1.48289E-01 -9.51993E-02 -4.97051E-02 -2.06125E-02 -5.32942E-03 1.01964E-03
100000. -4.37786E+0]-].05527E-01 -6.21604E-02 .-3.28418E-02 -1.67902E-02 -7.71384E-03 -2.68575E-03
200000. -4.60232E+01 3.14283E-05 2.]2471E-02 1.95060E-02 8.72740E-03 1.21515E-03 -1.62989E-03
500000. -5.21281E+0] ].52077E-01 ].I0093E-01 6.67186E-02 3.41707E-02 1.49151E-02 5.83661E-03
See append.]× for Chebyshev fit deta_is.
e
B-45
Q
He + H*->H(3s) + He+
Beom MQxwellion
iU _ , , ,,l,,,l ' ' ''""I ' ' ''""i I , ,r',,,, i ,, , ,,i,,;--
- - He Energy
- (eV/amu)_, - ,,
_ -- I0000.
x --20000.
v --40000.
"_ -'- " / - _ --70000.
• - -o - • -- 100000'_/ --
C" _@ , m --200000.
'+-- i_ --500000.qp0
Oqp Recommended
---_r__ _ D a t ao¢y ,,J
i
- __ _ --- ..... Chebyshev Fit
0 12 1 11 I11111 1 l 1 ltlllJ 1 11 lllllI I i I llllil I I I I Jill
lo0 lo' ""' lO_ 1@ lO" lO_" H. Temp. (eV)'i?' ,E ,
B-46
AElectron Capture Cross Sections for
H + + lte -> 11(3p) + lle+
Energy . Velocity Cross Section
(eV/amu) (cm/s) (cm 2)
1.7E+03 5.73E+07 1.35E-19
2.0E+03 6.21E+07 1.48E-19
4.0E+03 8.79E+07 2.45E-19
7.0E+03 1.16E+08 3.84E-19
1.0E+04 1.39E+08 5.13E-19
2.0E+04 1.96E+08 8.57E-19
3.6E+04 2.64E+08 1.14E-18
4.0E+04 2.78E+08 1.14E-18
7.0E+04 3.68E+08 7.28E-19
1.0E+05 4.39E+08 3.49E-19
2.0E+05 6.21E+08 3.95E-20
4.0E+05 8.78E+08 1.75E-21
7.0E+05 1.16E+09 1.02E-22
I_0E+06 1.39E+09 1.44E-23
1.2E+06 1.52E+09 4.95E-24
References: 134, 136, 156, 157, 159, 160, 163, 164, 165, 166, 167
Accuracy: Unknown O
Notes: (i) Very few papers report absolute cross sections. The overall assessment of the data
is in doubt due to the validity of the different normalization schemes.
(2) Cascade from higher states is usually neglected but can contribute up to 5% error in
the reported cross section measurements.
(3i The cross section (oi) for capture into state i is determined by measuring the
emission cross section (aij) for a transition from state i to j, correcting for
cascading from upper states and correcting for any branching. For Balmer- a emission
from the n=3 state the cross section _(H_)=a(3s) + .l!8a(3p) + s(3d). _
For a Chebyshev fit of the above cross sections it is necessary to use the following parameters.
Eml n = 1.7E+03 eV/amu, Ema x = 1.2E+06 eV/amu
Chebyshev Fittin_ Parameters for Cross Sections
AO AI A2 A3 A4 A5 A6 A7 A8
-90.6049 -4.52585 -3.52507 -.678448 .325826 .143519 -.0657813 -.0500666 .0154546
The fit represents the above cross sections with an rms deviation of 1.7%.
The maximum deviation is 3.6% at 2.0E+04 eV/amu.
See appendix for Chebyshev fit details.
Q|
B-47
H+ + He->H(3p) + He+
Cross Section vsoEnergy
'l f_-/k../17 .. I I .i 1 i IIII I I I I IIIIl" I -T" Il illi I I I I I lilt:
10'-1_=-
- \\
10-19 \- \ -- \ -
(_) 2C/kJ ---
C -O --
(/) 4,..,-2< /u _-O - - Recommended
U - - Datam
10 -2 _ , _
_ : Chebyshev Fit
10-_
lA -24 . I I I li,iii 1 1.I. I_IL.I.LI 1 1 1 llllll I I I lllll/k.,/
10 3 1C)¢ 10 5 10 6 10 7
Energy (eV/am u)qr
@
B-48
.
0Electron Capture Rate Coefficlents for
H+ + He +-> t{('3p) + lie + ,
Ma xwellian - MaxwellJan Rate Coefficients (cm3/s)
H +
Temp. Equal He Temp. (eV)
(eV) Temp. !00. 500, i000. 5000. I0000. 15000. 20000.
1.0E+02 4.48E-17 4.48E-17 1.54E-14 2.06E-13 8 41E-12 2.24E-II 3.77E-II 5.37E-II
2.0E+02 3.19E-14 1.54E-14 1.44E-13 5.85E-13 9 46E-]2 2.36E-II 3.90E-II 5.49E-II
4.0E+02 8.46E-13 4.71E-13 9.92E-13 1.85E-12 ] 16E-II 2.60E-II 4.15E-II 5.75E-II
7.0E+02 3.74E-12 2.44E-12 3.29E-12 4.43E-12 1 49E-II 2.96E-II 4.54E-II 6,14E-11
1.0E+03 7.38E-12 5.15E-12 6.13E-12 7.38E-12 i 83E-II 3.34E-II 4.92E-II 6.52E-II
2.0E+03 2 12E-II 1.57E-II 1.69E-II 1.83E-II 3 02E-II 4.60E-II 6.20E-11 7.77E'II
4.0E+03 5.24E-II 3.99E-II 4.12E-ii 4.28E-II 5 56E-II 7.15E-11 8.68E-II 1.01E~I0
7.0E+03 9.84E-II 7.80E-II 7.93E-II 8.08E-Ii 9 26E-II ' 1.07E-10 1.19E-i0 ].31E-10
1.0E+04 1.35E-I0 1,12E-10 1,13E-10 1 14B-10 1 24E-I0 1.35E-I0 1,45E-I0 1.53E-I0
2.0E+04 1.90E-10 1.78E-I0 1.78E'I0 1.79E-I0 1 82E-I0 1.85E-I0 1.88E-i0 i,90E-10
Notes: For Chebyshev fits of the above rate coefficients it is necessary to use the follo%_ing parameters.
Emi n = 1.0E+02 eV, Ema x = 2.0E+04 eV
Chebyshev Fitting Parameters for Rate Coefficients
He 0_'emp.
(eV) AO A1 A2 A3 A4 A5 A6
I00. -5.48603E+01 6.73175E+00 -2.33750E+00 8.57032E-01 -2.92258E-01 8.89193E-03 1,19267E-02
500. -5.23540E+01 4.57847E+00 -9.34127E-01 1.52574E-01 -2,98508E-02 -5.41726E-02 1.56047E-02
i000. -5.09960E+01 3.48139E+00 -3,33404E-01 -6.24733E-02 4.55378E-04 -3.70467E-02 2.75925E-03
5000. -4.83469E+01 1.64909E+00 2.61394E-01 -I.05216E-01 -5.38273E-02 -7.49908E-03 7,09196E-04
i0000. -4'73425E+01 1.12338E+00 2.55051E-01 -5.63104E-02 -5.16563E-02 -I.13825E-02 1.38299E-03
15000. -4.67459E+01 8.47733E-01 2.16661E-01 -3.36664E-02 -4.24929E-02 -I.19700E-02 4.13866E-04
20000. -4,63234E+01 6.64850E-01 1.80257E-01 -2.17729E-02 -3.47781E-02 -I.13742E-02 -1.56934E-04
Equal Temp. -5.42194E+01 6.56075E+00 -2.45975E+00 9.87265E-01 -4.35539E-01 8.21003E-02 -9.92180E-03
See appendix for Chebyshev fit details.
B-49
H* + He->H(3p) + He*
MaxwelLiGn- Mexwellion
O ,
S-.50
AEleot ron
Capture Rate Coefficients for
He + H + -> H(3p) + lle+
Beam - Maxwellian Rate Coefficlents (cm3/s)//
H + I
Temp., / He Energy (eV/amu)
(eV) i0000. 20000. 40000. 70000. 100000. 200000. 500000.
1.0E+00 7.13E-II 1.68E-I0 3.16E-I0 2.67E-I0 1.53E-I _' 2.45E-II 5.53E-13"
2.0E+00 7.13E-II I.68E-I0 3.16E-i0 2.67E-]0 ].53E-!0 2,45E,,II 5.53E-13"
4.0E+00 7.13E-II 1.68E-I0 3.15E-,10 2.66E-I0 1.53E-I0 2.45E-II 5.53E-13"
7.0E+00 7.13E-II 1.68E-10 3.15E-I0 2.66E-10 1.53E-I0 2.44E-II 5,53E-13'
1.0E+01 7.13E-II 1.68E-10 3,14E-I0 2.65E-I0 1.52E-I0 2.44E-II 5,53E~13 *
2.0E+01 7.15E-II 1.68E-10 3.14E-I0 2,64E-I0 1.52E-I0 2.44E-II 5,54E-13"
4.0E+01 7,17E-II 1.68E-10 3.12E-10 2.63E-I0 1.52E-10 2,43E-II 5,54E-13"
7.0E+01 7.21E-II 1.68E-10 3.11E-10 2.62E.-I0 1.51E-10 2.43E-II 5.55E-13
1,0E+02 7.26E-II 1.68E-I0 3.09E-I0 2.61E-10 1.51E-10 2,42E-II 5.55E-13
2.0E+02 7.41E-II 1.69E-10 3_06E-I0 2.58E-I0 1.50E-10 2.42E-II 5,57E-13
4.0E+02 7.71E'II 1.71E-10 3.01E-10 2.54E-10 1.49E-I0 2 42E-II 5.61E-13
7.0E+02 8.16E-II 1.74E-10 2,95E-I0 2.50E-I0 1.49E-I0 2.42E-II 5.68E-13
1.0E+03 8.61E-II 1.77E-I0 2.90E-I0 2.47E-10 1.49E-10 2.43E-II 5,74E-13
2.0E+03 1.00E-10 1.86E-10 2.79E-I0 2.39E-I0 1.48E-I0 2.49E-II 5.97E-13
4.0E+03 1.24E-10 1.96E-10 2,63E-I0 2.25E-I0 1.46E-]0 2.63E-II 6 43E-13
7,0E+03 1.51E-10 2.04E-I0 2.45E-I0 2_08E-10 1.42E-I0 2.88E-II 7.17E-13
1.0E+04 1,70E-10 2.07E-I0 2.30E-I0 1.95E-I0 1,38E-I0 3.12E-ii 8.02E-13 A
2.0E+04 1.95E-I0 2.03E-I0 1.97E-I0 1.64E-I0 1.24E-I0 3.75E-II 1.18E-12
Aeeuracyz * - Possible Error Greater Than 10%
• * - Possible Error Greater Than 100%
Notes: For Chebyshev fits of the above rate coefficients it is necessary to use the following parameters.
Emi n = 1.0E+00 eV, Ema x = 2.0E+04 eV
Cheb_{shev Fitting Parameters for Rate CoefficientsHe
Energy
(eV/amu) AO A1 A2 A3 { A4 A5 A6
10000. -4.61593E+01 4.69768E-01 2.55845E-01 6_75806E--02 -2,06018E-02 -3.21005E-02 -1.71678E-02
20000. -4.48832E+01 1.05388E-01 5.13750E-02 1.87880E-03-1.77"_15E-02 "1.43595E-02 -5.2697!)E-03
40000. -4.39844E+01 -1.88716E-01 -i 03793E-01 -4.31001E-02 -1.44695E-02 -4.32136E-03 -8.32803E-04
70000. -4.43219E+01 -1.88451E'01 -I.07258E-01 -4.99127E-02 -2.00817E-02 -6.25364E-03 -3.66359E-04
100000. -4.52889E+01 -7.00699E-02 -4.15959E-02 -2.66009E-02 -1.74699E-02 -9.19908E-03 -3.00670E-03
200000. -4.87156E+01 1.42634E-01 1.14850E-01 6.70006E-02 2.67000E-02 5.12084E-03 -2.83726E-03
500000. -5.61687E+01 2.49112E-01 1.78331E-011.05979E-01 .,_.28963E-02 2.25156E-02 8.83834E-03
See appendix for Chebyshev fit details.
0
B-51
He + H+->H(3p) + He+
Beans Ma×wellian
" 10-9 "' l t l lIIil I , i-i-ili,ij 'i t,,'i,I1,1" l 1'I lli'll I l"; ,,ilu_ .,
- He Energyd A _
- , - (eV/am u)'1
_ A -- 10000.
x -- 20000.
ld-, , _ _J - v --40000,
"-_ : ...._, - _,- 700o0.tel
_ E ___ -,.20 _ • -100000.c"
@ _ m - 200000.._ 10-1_ -_-- - - [] --500000.
I_ -'
U - -
, Recommended
o _Data
10-'_ ._--- - ..... Chebyshev Fit
[ -
10-'3 i i llJllil i i illilll i i lliilil 1 i illiill _L_I I'lJlii
100 10' 10_ 103 104 105H+ Temp. (eV)
Q
B-52
Electron Capture Cross Sections for
11+ + lie -> H(3d) 4 lle+
Energy Velocity Cross Section
(eV/amu ) (cm/s ) (cm 2 )
3.0E+03 7.61E+07 1.16E-19
4.0E+03 8.79E+07 I_36E-19
7.0E+03 ].16E+08 1.65E-19
1.0E+04 1.39E+00 1.71E-19
2.0E+04 1.96E+08 1.43E-19
4.0E+04 2.78E+08 8.33E-20
7.0E+04 3.68E+08 3.95E-20
1.0E+05 4.39E+08 Io53E-20
2.0E+05 6.21E+08 1.44E-2]
2.7E+05 7.22E+08 4.00E-22
3.2E+05 7.86E+08 1.67E-22
Referencesl 134, 136, 156, 157, 158, 159,.160
Accuracy: Unknown
Notes: (i) Very few papers report the absolute cross sections. The overall assessment of the
data is in doubt due to the validity of the different normalization schemes.
(2) Cascade from higher states is usually neglected, but can contribute up to a 5% error
in the reported cross section.
For a Chebyshev fit of the above cross sections it is necessary to use the following parameters.
Eml n = 3.0E+03 eV/amu, Ema x = 3.2E+05 eV/amu
Chebyshev Fittinq Parameters for Cross Sectio.r_
AO AI A2 A3 A4 A5 A6 A7 A8
-90.4702 -2.99013 -1.60913 -.296858 -.0140200 .0353005 .0153108 '-.0221875 -.0321765
The fit represents the above cross sections with an rms deviation of 1.9%.
The maximum deviation is 3.1% at 1.0E+05 eV/amu.
See appendix for Chebyshev fit details.
; B-53
. ,
H+ -t- He -->t-t(3d) --t-Hef
ross_ LT:'-, : r"Lionvs. Er , jy
1O- 18_____q_.___r.__T I I I 1I' j" "-----r_--T--'T-T-TTTFr--'--T--- I" 1 '1 ITr_
10-1_:_ , \'\ ,- \
,_ - -
,9 10-_{1) -_
b") -{h{,f} _
0 Recommended__ -
{_) Data
10-2_- - Chebyshev Fit
1_-2:-. J l J I I l I I l_ I I ,2,, L I J_ll ..... L___L__I___LLLL!
10s i04 10s 106Ener9 y (eV/Gmu)
B.-54
Eleatron CaptUre Rate Coeffialents for
H + + lle -> ll(3d) 4 lle+
Maxwellian - Maxwelllan Rate Coefficients (cm3/s)
H+
Temp. Equal He Temp, (eV)
(eV) Temp. i00. 500. i000. 5000. i0000, 15000, 20000,
2.0E+02 2.41E-16 6,60E-17 3,49E-15 4.08E-14 3.27E-12 8,54E-12 1,24E-II 1,52E-II
4,0E+02 7,71E-]4 2.80E-14 1.01E-13 2.88E-13 4,19E-12 9.26E-]2 ],29E-]l 1,55E-]I
7.0E+02 8.89E-13 4.53E-13 7,29E-13 1.15E-12 5.53E-12 1,03E-II 1,36E-II 1,60E-II
1.0E+03 2.38E-12 1,43E-12 1,84E-12 2.38E-12 6.80E-12 i ]2E-li 1,43E-ll ],65E-II
2.0E+03 7.79E-12 5.85E-12 6.28E-12 6,80E-12 1,04E-II 1 37E-II 1,61E-II 1,78E-II
4,0E+03 1.48E-II 1.26E-II 1,29E-11 ].32E-II 1.52E-II i 72E-II 1,85E-II 1,95E-II
7.0E+03 1.94E-II 1.78E-II 1.79E-II 1.80E-II 1.90E-II 1 98E-II 2,04E-II 2,08E-II
1.0E404 2,10E-ll 2.01E-II 2,02E-II 2,02E-II 2,06E-II 2 10E-]I 2.12E-II 2,12E-II
2.0E+04 2.01E-11 2,09E-II 2.09E-II 2,09E-II 2,08E-II 2 05E-II 2,03E-II 2,01E-II
Notest For Chebyshev fits of the above rate aoeffiolents it is neoessary to use the following parameters,Eml n = 2.0E+02 eV, Ems × = 2,0E+04 eV
Chebzshev Fittlng Parameters for Rate Coefflci_nt__sHe
Temp Q(ev) Ao A1 A2 A3 A4 AS AG
i00 -5.63680E.015.53S26E+00-2.530_IE+007.68047E-01-2.09210E-013.02777E-028.99288E-045OO -S.46783E+014.0755_E+00-1.58318E.002.94914_-01-2.76037E-02-2.07_78E_021.01392E-02
I000 -5.34861E+0i 3.08285E+00 -I.00328E+00 6.05624E-02 3.07528E-02 -2.37156E-02 4.91264E-03
5000 -5.08092E+01 1.02925E+00 -I.15489E-01 -I.I1263E-01 1.29497E-04 5.31512E-03 -1.44689E-03
i0000 -5,00260E+01 5.09612E-01 -1.91665E-02 -7,34488E-02 -],56542E-02 2,56893E-03 7.98864E-04
15000 -4.96848E40i 2.98178E-01 -7.68530E-03 -5.18119E-02 -1.65953E-02 -3.35169E-04 1.07168E-03
20000. -4.94956E+01 1.81879E-01 -i.04948E-02 -3.99118E-02 -1.50920E-02 -].49095E-03 I.I1348E-03
Equal Temp. -5.53820E+01 4.85397E+00 -2.35173E+00 7,57520E-01 -2.46645E-01 5.44226E-02 -8.31810E-03
See appendix for Chebyshev fit details.
[t- 5 5
H+ -t-He-'-:, H(3d) +. t-Iu+
Maxwelliclr-1 Mc"'- _,_,welliar]
B-56
l
Electron Capture Rate Coeffiatents for Olie + tl _ -> 11(3d) _ He +,
Beam,- Maxwe111an Rate Coefflolents (om3/s)
H+
Temp, tie Energy (eV/ainu)
(eV) i0000. 20000. 40000. 60000. 80000. i00000, 200000,
i 0E+00 2.37E-11 2.80E=II 2,31E-II 1,65E-II 1.09E-II 6.71E-12' 8.94E-13'*
2 0E+00 2.37E_]I 2.80E-II 2.31E-11 1.65E,-ii 1 09E-.I_ 6.71E-12' 8.93E-13'*
4 0E400 2.37E-!LI 2.80E-II 2.31E-I] 1.65E-II 1 09E-11 6,70E-12' 8.93E-13'*
7 DE+00 2 36E-II 2.79E-11 2,30E-11 1.65E-II ] 09E,.]I 6.70E-12' 8.92E-13'*
1 0E_01 2 36E-II 2.79E'II 2,30E-II 1,65B-Ii i 09E-II 6.70E-12' 8.92E-13'*
2 0E+0] 2 36B-ii 2.78E-11 2.30E-11 1.65E-Ii I 09E-II 6.69E-12 8.91E-13,_
4 0E+01 2 35E-II 2_77E-II 2,29E-II 1.65E-11 1 09E-II 6.68E-12 8.90E-]3'*
7 0E+01 2 34E-11 2,76E-I] 2 28E-II 1.65E-]I i 09E-II 6.67E-12 8.89E-13'
] 0E+02 2 34E-11 2.75E-II 2.28E-II 1.65E-II 1.09E-ll 6.67E-12 8.89E-13'
2 0E+02 2,33E-]I 2,73E-II 2.26E-II 1.65E-II ] 10E-II 6.66E-12 8.89E-13'*
4 0E+02 2.31E-II 2,70E-II 2.24E,II 1.65E,,II I fOE-II 6.68E-12 8.92E-13'
7 0E+02 2.30E-11 2 66E-II 2.22E-11 1.64E-II i 10E-ll 6.72E-12 8,98E-.13'
] 0E+03 2.29E-II 2 63E-11 2,20E-11 1.63E-]I ] 09E-11 6.76E-12 9.05E-13'
2.0E+03 2.26Eii]' 2,55E-II 2.]5E-II 1.59E-11 i 0GE-II 6.90E-12 9.35E-i3'
4.0E+03 2.24E-II 2.41E-II 2.05E-II 1.53E-11 1 06E-II 7.06E-12 ].01E-12*
7.0E+03 2.22E-11 2.26E-]I 1,92E-]I 1.45E-II 1.04E-II 7.19E-12 1,13E-12'
1.0E404 2.]8E-II 2.14E-II 1.80E.-II 1.38E-II 1.01E-II 7.22E-12 1.26E-12'
2.0E+04 1.98E-II 1.83E-11 1.51E-11 ].20E-II 9.26E-12 7.06E-12 1.66E-12'
Acctl aoy_ * - Possible Error Greater Than i0%
• * - Possible Error Greater Than 100%
Notes: Fo r Chebyshev fits of the above rate coefficients it is necessary to use the following paraIiieters.
Eml n = i 0E+00 eV, Ema x = 2,0E+04 eV
Ch__ebyshev Fitting Paranleters for Rate CoefflelentnHe
EnErgy
(eV/ainu) AO A1 A2 A3 A4 A5 A6
10000. -4.90115E+01 -6.26583E-02 -3.14715E-02 -1.74368E-02 -I,18746E-02 -8.00345E-03 -5.51328E-03
20000. -4.87965E+01 -1.63847E-01 -9.40039E-02 -4.32626E-02 -1.65508E-02 -4.78447E-03 -6.28354E-04
40000. -4.91665E+01 -1.54448E-01 -9.66541E-02 -5.08695E-02 -2.30319E,-02 -8.09916E-03 -I.06973E-03
60000. -4.97788E+0] -1.I1497E-01 -7.93398E-02 54.38613E-02 -1.80124E-02 -5.25241E-03 -1.28373E-03
80000. -5.05382E+01 -4,92366E-02 -4.11913E-02 -2.64723E-02 -1.18809E-02 -3.95220E-03 .-2.08141E-03
I00000. -5.14178E+01 3.35427E-02 2.01516E-02 3.56710E-04 -9.44387E-03 -8 21678E-03 -3.58171E-03
200000. -5.52583E+0] 2.09996E-01 1.57946E-01 9.13682E-02 3.94669E.02 1,12103E-02 -2 26555E-04
See appendix for Chebyshev fit details,
O
,q|p,, ,, ,,,
1_1-,b "I
®
He + H+ ---:,.,H(3d) -t-t--le4
Becils-_....Mcl,<welliar-/i
I(D,-- 35,0-----r--TTl-rTr i I i i i ITmT- _ i r-_Tl-rrl---T-q-TCrmT---q-'r-r-rTrr×
I-le Energy
(eV/arnu)
30,0 - - _ --I0000,
, x -- 20000,
v 4.0000,"'...., _ --25,0
N
..U') "-" -- 'X .._.____ "-------_-..._.._=_\. _< 60000,
E ,o • -- BOO00,"-" 20,0 -
,Q2 IB - IC)O000,
_- I_ -- 200000,00 15.0
C.) .Recornmoncled
o , '\4' ....... Data©EL_
10,0 - ""- -
..... Chel:,yst_evFit
5,0 -
j:-t_
O. 0 i I J t_LLU_L._L_4_LJ_.I44_IL..... L_I__.L_LJ_LLL[_L_LLL.LJII.I_._J._..k..LL_LLLL
Io° 1o' ld I¢¢ id d,_H+ 'Temp. (eV)
0
I]-5_
• •' Eleotron Capttlro Crose_ SooLtone_ Co_
II"I' .I. L,.I. -> il(2g,2p) .I- Li "l+
li(20) li (2p)[_nergy Cros_ Sect]on Energy Crost_ L]ocL.ion
eV/anlu sm2 eV/atoLl sill2
9,6E+02 '1,09B-13 9, liE+02 I'+44E-15I,9E+03 2.22E-13 2,0E.103 2.37E-15
2,4E+03 2,52E-15 2,9E+03 2,95E-15
2,9E+03 2,56E-15 3,4E._03 3,05E-15
4.0E403 2,06E-15 4.91_,+03 2,751_-]5
6,7E+03 ,i. 39E-15 6,81,J.I0:I 2.02E-]5
8,6_+03 9,00P,-16 9,7E+03 J,]3ELj5
9,5E+03 7,26E'16 1,4_+04 3,01E-16
I+4E+04 2,73_-16 J,9E+04 9,71F,'-17
1,9E+04 1,23E-16 2,4B+04 3,76_3-17
2,41_:+04 6,20E-17 2.9E404 1,76E-17
3,8P,+04 i, 40E-17 3,9E+04 3.980-10
4,9m+04 6.291",-18 4'9E+04 1,21E-18
5,9E+04 3,550-18 5.9E404 4,47E-19
6,8E+04 2,22E-10 6,91;+04 ],94E-19
8.8E+04 9.76E-19 8,91_404 4.96PJ-20
9,8E+04 6,77E-19 1.1E+05 J, 691_-20
i, 3F,+05 2,72E-19
0Referennos_ 255, 256, 257
A_ocur.+___aoj_/E < 2x104 eV/ainu - 60%1 E > 2x104 eV/ainu - u[,kno_,n
(i) The CROSS section data for ol_ergles grs.ate/ than 2x104 eV/all(Lia_e theotetloal
results of Ern;olaev (ref, 257)I fOL' excilation of the I,i(2p) level by pLOtOlle see ref,250,
(2) Cascading from hlghef states is Ices than 5%, thus .(2p) : a([,,+va).
For Chebyshev fits of the above cross seotlons it is necessary to uI_e the following pal+amet!ers,
H(2B) Einln = 9,55F]+02 8V/amu, Ems x - 1.3E+05 eV/ainu
ll(2p) Eml n r, 9.8E+02 eV/ainu, Ems x = 1,1E+05 eV/amu !
i
Ce_h.q._!_eV Fittlnc Parameters for Cros SooLIoO8 }{{{
AO A1 A2 Al A4 A5 A6 A7 id{
II(2e) -73,9306 -.4,42348 -1.68271 .337287 .0733407 -,0624317 -.0223686 6.11347E-04 -.00i,73178
ll(2p) -75,0922 -5,75721 -2.57021 .0939967 .255624 -.0329880 -.0184241 .0249338 .03113479
The fit repL'esents the 11(28) cross seotlon with ai, rms deviation of 0.9%, •
The maXllllUmdeviation la 1.7% at 4.BE-f04 eV/ainu,
The /lt [epr,esents the H(2p) cross section will+ an fins deviation of 3,2%,
The maxlnium deviation ts 3.5% at 1,9E+04 eV/ainu,
See appendix for Chobyshev £it details. O
B-59
H+ + li->H(2s,2p) + Li +
Cross Section vs. Energy
- 1 I I IIIll l I 1 I lllll I I I I lillll I i I--1-TTT__
10-_5- _ zx- 2a; -
: : x-2p
10_ _
O d'" - -E - _-_ - _
:_o 10_1_0 - ---'(D _(/3 - _(/3Of)0 _ -
I - =
/\ -/
]0"-19 - / " _OGtQRec°mmended
- 1 Chebyshev Fit102(- l 1 1 JIIII[__LI 1 II1111 .I__J__L/ I1111 __.t I 1 l_.Ll..i
10_ 103 10_ 10_ 106
Energy (e\I/c_rnu)
O
B-60
Electron Capture Cross Sections for
H+ + Li -> l{(3s,3p,3d) + Li4
(3s) (3p) (3d)
Energy Cross Section Energy Cross Section Energy Cross Section
eV/amu cm 2 eV/amu cm2 eV/amu cm2
].3E+03 7.96E-17 9.8E+02 1.28E-16 3.1E+03 7 47E-172.0E+03 9.60E-17 1.5E+03 1.51E-16 3.9E+03 8 78E-172.9E+03 ].23E-16 2.0E+03 ].76E-16 4.8E+03 9 79E-173.9E+03 1.55E-16 2.9E+03 2.33E-16 6.8E+03 1 06E-164.9E+03 2.07E-16 3.9E.03 3.17E-16 9.7E+03 8 39E-176.0E+03 3 46E-16 4.9E+03 3.65E-16 1.3E+04 4 3]E-176.9E+03 4 43E-16 6.9E+03 3.45E-16 1.5E+04 2 78E-177.9E+03 4 55E-16 8.9E+03 2.81E-16 2.0E+04 i 16E-178.9E+03 4 29E-16 9.9E+03 2.47E-16 2 9E+04 2 97E-18
1.0E+04 3 83E-16 I_5E+04 1 23_-16 3 9E+04 1 lIE-181.5E+04 i 64E-16 2.0E+04 5 12E-17 4 9E+04 4 65E-192.0E+04 6 88E-17 2.5E+04 2 18E-17 7 0E+04 1 44E-192.5E+04 3 15E-17 3.0E+04 1 05E-17 9 9E+04 3 63E-203.5E+04 7 97E-18 3.5E+04 6 04E-18 1 3E_05 1 20E_204.9E+04 1 96E-18 4.5E+04 2 25E-18 I 5E+05 7 57E-216.0E+04 1 03E-18 5.0E+04 I 43E-188.0E+04 3 69E-19 6.0E+04 6.60E-191.0E+05 1 81E-19 7_0E+04 3.86E-191.3E+05 8 92E.-20 9.0E+04 1.48E-19
1.0E+05 9.25E-201.3E+05 3.87E-20
References: 256, 257
Accuracy: E < 2x104 eV/amu - 60%; E > 2x104 eV/amU -unknown
Notes t (i) The cross section data for energies greater than 2x104 eV/amu are the theoreticalresults of Ermolaev (ref. 257).
(2) The cross section (,i) for capture into state i is determined by measuring the
emission cross section [aij) for a tfansltlon from state i to j, correcting for any
branching from state i and correcting for cascading from upper states.
f
Fo_ Chebyshev fits of the above :_ross sections it is necessary to use the following parameters.
_3s) Emi n = 1.3E+03 eV/amu, Ems x = 1.2E+05 eV/amu
(3p) Eml n = 9.8E+02 eV/amu, Ems x = 1.2E+05 eV/amu
(3d) Eml n = 3.1E+03 eV/amu, Ems x = 1.5E+05 eV/amu
iChebyshev Fitting Parameters for Cross Sec£1ons
AO A1 A2 A3 A4 A5 A6 A7 A8
(3s) -77.4321 -3.51092 -2.10742 .102860 .543346 -.0941225 -.179427 .114301 -.00463543
(3p) -77.4555 -4.03388 -2.19950 .00628310 .364180 --.0330367 -.0799875 .00340643 -.00766823
(3d) -80.9668 -4.92271 -1.27692 .391264 -.0254482 -.0874189 .0722031 .0109053 -.0235328
The fit represents th_ (3s) cross section with an rms deviation of 6.8%.
The maximum devlatlonis 19.4% at 4.9E+03 eV/amu.
The fit represents the (3p) cross section with an rms deviation of 3.7%.
The maximum deviation is 6.6% at 3.0E+04 eV/amu.
The fit represents the (3d) cross section with an rms deviation of 3.2%.
The maximum deviation is 6.5% at 4.9E+04 eV/amu.
See appendix for Chebyshev fit details.
@
B-61
H+ + Li-> H(3s,3p,3d) + Li +
CrossSectionvs. Energy
B-62
Electron Capture Cross Sections for
He + + H2 -> He(21S + 23S)
Energy Velocity Cross Section
(eV/am u ) (cre/s ) (cre2)
2.5E+03 6.95E+07 6.75E-18
3.0E+03 7.61E+07 9.57E-18
4.0E+03 8.79E+07 1.58E-]7
5.0E+03 9.82E+07 2.18E-17
7.0E+03 1.16E+08 3.14E-17
9.0E+03 ].32E+08 4.14E-17
I.OE+04 ].39E+08 4.63E-17
1.5E+04 1.70E+08 6.54E-!7
2.0E+04 1.96E+08 7.00E-17
2.5E+04 2.20E+0B 6.69E-17
3.5E+04 2.60E+08 5.28E-17
4.5E+04 2.95E+08 4.03E-17
5.0E+04 3.11E+08 3.52E-17
6.0E+04 3.40E+08 2.75E-17
6.4E+04 3.51E_D8 2.48E-17
References: 98, 102; 196, 197, 198
Accuracy: 40% O
Note{ The cross sections are for capture into the metastable states 21S and 23S.
For Chebyshev fit of the above cross sections it Js necessary to use the following parameters.
Eml n = 2.5E+03 eV/amu, Ema x = 6.4E+04 eV/amu
C hebyshev Fitting Parameters for Cross Sections
AO A1 A2 A3 A4 A5 A6 A7 A8
-76.2905 .717609 -.746846 -.0903391 I.?1246E-03 .0416862 -7.59576E-04 -.0179523 6.0_163E-03
The fit represents the above cross sections with an rms deviation of 0.5%.
The maximum deviation is 0.9% at 4.0E+03 eV/amu.
See appendix for Chebyshev fit details.
B-63
He+ + H2 ->He(2'S + 23S)
Cross Sectionvs, Energy
10-16 I I I I I I Ii I I I I I I i i I
/ \ -
_ // "_
// "_ -- / \
/ \/ \/
_ / \
/ \
_ // '_ /E /
u /c /o /
'-= 10-17- /
// -_ -
{._ - __ _03
Recommended(._.) -'
Data
- Chebyshei¢ Fi{
10-18 i ii ] J I i i i_l 1 1 l._J. i i 11
.ld 104 10sEnergy (eV/amu)
0
B-64
A
Electron Capture Cross Sections for D
lie+ + H 2 -> He(21p,31p)
(21P) (31p)
Energy Cross Section Energy Cross Sectlon
eV/amu cm 2 eV/amu cm 2
1,3E+03 2,95E-17 2.5E403 2.05E-18
1.5E+03 3.02E-17 3.0E+03 1.89E-18
2.0E+03 3.37E-171 3.5E+03 ].61E-18
3.0E+03 3._7E-17 4.3E403 1.45E-18
3.5E_03 3.90E-17 5.0E+03 _.33E-18
4.3E+03 4.12E-17 5.8E+03 1.28E-18
5.0E+03 4.22E-17 6.5E+03 1.33E-18
5.8E+03 4.19E-17 7.0E+03 1.47E-18
6.5E+03 4.13E-17 8.0E+03 1.64E-18
7.0E+03 4.11E-17 8.5E+03 1.83E-18
8.0E+03 4.05E-17 9.0E+03 1.91E-18
8.5E+03 3.96E-17
8.8E+03 3.92E-17
Referencesz 20 163
i
Accuracy :I 60% O i
Notes._._____."(I) The cross section ( a iI) for capture into state i is determined by measuring the
emissio_ cross section ( a ij ) for a transition from state i to j, correcting for any
branching from state i and correcting for cascading from upper states.
(2) In these measurements cascade was neglected in the analysis of the cross section.
i
For Chebyshev fits of the above cross sections it is necessary to use the following parameters.
(2IP) Emi n = 1.3E+03 eV/amu, Emax I 8.8E+03 eV/amu
(3IP) Emi n = 2.5E+03 eV/amu, Ema x 9 0E+03 eV/amu
i
ChebyshleviFitting Parameters for Cross Sections
AO AI A2 A3 A4 A5 A6 A7 A81
i
(21p) -75.7187 .173380 -.0602524 -.0334767 .00459756 .00195946 00158847 -4,27148E-04 -.00726785
(31p) -81.8842 -.0794869 .]916956 ,0554748 -.00702131 -.0164034 -.0116162 .00548035 1.56409E-04
The fit rep._esents the (2lip) C[I O S _ sections with an rms deviation of 0.2%.
The maximum deviation is I 0.2% at 6.4E+03 eV/amu.i
The fit represents the (31P) cross sections with an rms fleviation of 0.2%.
The maximum deviation is 0.4% at 7.9E+03 eV/amu.
See appendix for Chebyshev fit details.
i
B-65
He+ + H2 ->He(2'P, 3'P)
Cross Section vs. Energy
0 _'E(O
c-O
10-17_CD(b
0'9, (/)
09©
U
' Recommendec
,/,x _-- Data
10- Chebyshev Fit1 I L_ i _ I i I L..
ld 104Energy (eV/_] m u)
II
B..-6 6 •r
0Line *Emission C_o[_s Sectlon.,_ of Electron Capture Colllalons foL
|le+ 4 I]2 -> He(587.6, 447.], 667.8 nra)
(587.6 nra) (667.8 nra) (447.1 am)
Energy Cross Section Er_ergy Cross Section Energy Cross Section
• eV/ainu cm 2 eV/ainu cm2 eV/ainu cre2
1.7E+01 1.12E-21 3.7E+01 9.97E-22 2.0E+0I 9.98E-222.0E+01 3.58E-21 5.0E+01 7.92H-21 2.5E+01 2.67E-212.5E+01 7.00E-21 6.0E+OI 1.47E-20 3,0E+01 3.75E-21
3.0E+01 8,74E-21 8.0E+OI 4,70E-20 4.DE+01 5.02E.-214.0E+01 1.26E-20 1.0E+02 1.04E-19 5.0E+01 6.21E-21
5.0E+01 1,81E-20 1.5E+02 2,70E-19 6.0E+01 7.65E-216.0E+01 2,83E-20 ].8E+02 3.35E-19 7.0E+01 1.00E-208.2E+01 7.80E-20 2,0E+02 3.95E-19 8,0E401 1.77E-201.0E+02 1.72E-19 1.0E+02 6.11E-20
!.5E+02 6.40E-19 1.2E+02 9,53E-,202.0E+02 1.12E-18 ] 5E+02 1.30E-192.4E+02 1.17E-18 2 0E+02 1.60E-193.0E+02 1.16E-18 2 5Ei02 1.75E-195.2E+02 1.02E-18 3 0E+02 1.82E-198.3E+02 8.33E-19 4 0E+02 1.81E-191.0E+03 7_69E-19 6 0E+02 1.63E-191.6E+03 7.00E-19 8 0E+02 1.45E-192,0E+03 6,93E-19 1 0E+03 1.31E-193.0E+03 7.25E-]9 ].5E+03 1.07E_194.0E+03 7.68E-.19 2 0E+03 9.32E-20
5.2E+03 8.05E-19 3 0E+03 8.58E-207,8E+03 8,90E-19 4 0E+03 8.98E-20
5 0E+03 9.72E-206 0E+03 1.06E-197 2E+03 1.16E-198 2E+03 1.27E-]91.0E+04 1.48E-19
References: 199, 200
Accuracy: 40%
Notes: (1) Relative data of Polyakova et al (ref. 200) have been normalized to data of Islet
et al (ref. 199) at 125 eV/amu.
(2) The 587.6 nm transition i_, the strongest He emisslorl from He + capture collisions in
H2 •
(3) The 43D -> 23p transition is 447,] nra, the 33D -> 23p transition is 587.6 nra, aJld
the 31D .-> 21p transition is 667.8 nra.
FOr Chebyshev fits of the above cross sections it is necessary to u;_e the followlng parameters.
(587.6 nra) Eml n = I,TE+01 eV/al_lu, Ema x = 7.8E+03 eV/ainu
(667.8 nra) Eml n = 3.7E+01 eV/ainu, Ema x = 2.0E+02 eV/ainu
(447.1 nra) Emz n = 2,DE_01 eV/ainu, Ema x = 1.0E+04 eV/ainu
Chc-b_,shev Fittin([ Parameters for Cross Sections
AO Al A2 A3 A4 A5 A6 A7 A8
(587.6 nm) -86,6646 2.83888 -].58217 .357959 .371758 -. 133932 -.263367 .286400 --.i04165
(667.8 nm} -89.392D 2.77428 -.477421 .04-5864 -.]23082 .]39543 -.0694321 .0304386
(447.1 nm) --89.4303 1.99037 -1.26304 .473572 .362531 -.183668 -.0812802 ,198425 -.197268
The fit represents the 587.6 nm cross_ section with an rms deviation of 4.7%.
T_le maximum deviation is 10,8% at: 3.1E+02 eV/ainu.
The fit represents the 667.8 nm cross section with au rms deviation of 0.0%.
The maxlmum deviation is 0.0%.
The fit represents the 447,1 nm cross section with an rms deviation of 14.7%.
The maxzmum deviation is 42.6% at 7.1E+01 eV/ainu.
See appendix for Chebyshev fit details.
B-67
He+ + Hs -> He(587.6, 667.8, 447.1 nm)
Cross Section vs, Energy
B-68
QElectron CaptUre Cross Sections for
He + + He -> He(21S + 23S)
Energy Velocity Cross Section
(eV/amu) (c_/s) (cm 2 )
1 0E+01 4.39E+06 1.00E-19
1 5E+01 5.38E+06 1.94E-19
3 0E+01 7.61E+06 7.49E-19
5 0E+01 9.82E+06 1.69E-18
8 0E+01 1.24E+07 2,33E-18
1 5E+02 1.70E+07 2.81E-18
3 0E+02 2.41E+07 2.99E-18
6 0E+02 3.40E+07 3.35E-18
i 5E+03 5.38E+07 4.54E-18
2 5E+03 6.95E+07 6.54E-18
4 0E+03 8.79E.07 9.49E-18
6 0E+03 1.08E+08 1.46E-17
9.0E+03 1.32E+0B 2.40E-17
1.0E+04 1.39E+08 2.61E-17
1.5E+04 1 70E+08 " 2.41E-17
3.3E+04 2.50E+08 1.85E-17
5.0E+04 3.11E+08 i.52E-17
References: 98, 196, 197r 201, 202
Accuracy: 40%
(I) Theoretical values of Sural et al (ref. 202) are used to extrapolate the data of
Gilbody et al (ref. 98) at 5x103 eV/amu to those of MacVicar and Barst (ref. 201) at 55
eV/amu.i
For a Chebyshev fit of the above cross sections it _s necessary to use' the following parameters.
Eml n = 1.0E+01 eV/amu, Ema x = 5.0E+04 eV/amu
C__/h_b%shev Fittinq Parameters for Cross Sections
A0 A1 A2 A3 A4 A5 A6 A7 A8
._ -80.6529 2.39212 -.649912.218666 -.468812 -.126058 .149096 .0275996 .0661909
The fit represents the above cross sections with an _ms deviation of 5.2%.
The maximum deviation is 12.8% at 1.5E+04 eV/amu.
See appendix for Chebyshev fit details.
B-69
0
He+ + He ->He(2_S + 23S)
ross section vs, Energy
10-,_ ._ I I I I'I III I I I I I I llll I I I I I Ill I I I [-I"ITF[
__\ '_ "-_ _
,--., 10-.'7__tN
_I E / -L) -I -
' 0 --
(/3
O90
Recommended
U lO-,e Data
Chebyshev Fit
10-19 i 1 i llllll 1 i i lllllj i 1 i 111111._ 1 i i IJ_LLJ.
10' 102 103 10" 102Energy (eV/amu)
0
B-70 "
A
Electron Capture Rate Coeffiefents for Q
Ilo+ + He -> He(21S + 23S)
' ' Maxwelllan- Maxwellian Rate Coefficients (em3/s) '
He +
Temp. Equal He Tenlp. (eV)
(ev) Temp 10, i00. 500. 1000. 5000. 10000. 20000.
2.0E+00 9.32E-17 7.50E-14 1.05E-II 4.83E'II 7,97E-II 3.80E-I0 9.44E-I0 1 97E-09
4,0E+00 1.30E-14 1.29E-13 1.08E-ll 4.84E-II 7.98E-II 3.80E-I0 9.44E-I0 1 97E-09
7.0E+00 1.29E-13 2.39E-13 1.12E-II 4.86E-II 8.00E-II 3.81E-I0 9.45E-I0 i 97E-09
1.0E+01 3.83E-13 3 83E-13 1.16E-II 4.88E-II 8.02E-II 3.81E-I0 9.45E-10 1 97E-09
2.0E+01 2.09E-12 1.09E-12 1.30E-II 4.95E-II 8.08E-II 3.82E.I0 9.46E-10 1 97E-09
4.0E+01 7.41E-12 3.29E-]2 _ 1.56E-II 5.09E-II 8.19E-II 3.84Eri0 9.48E-]0 ] 97E-09
7.0E+01 1.56E-II 7.41E-12 1,93E-II 5.29E-11 8.37E-II 3.87E-10 9.52E-I0 ] 97E-09
].0E+02 2.27E-II 1.16E-II 2.27E-Ii 5.49E-II 8.55E-ii 3.90E-10 9.56E-10 1.98E-09
2.0E+02 4.08E-II 2.38E-II 3.25E-II 6.13Eiii 9.14E-II 3 99E-10 9.67E-10 I_98Ei09
4.0E+02 6.75E-iI 4.15E-II 4.81E-II 7.36E-II 1,03E-10 4.19E-10 9.91E-10 ' 2.00E-09
7.0E+02 1.03E-10 6.20E-Ii 6.75E-II 9.14E-!I 1.21E-10 4 50E-10 1.03E-09 2.03E-09
1.0E+03 1.40Ez10 8.02E-II 8.55E-II 1.09E-10 1.40E-10 4.82E-I0 1.06E-09 2.05E-09
2.0E+03 2.88E-I0 1.41E-10 1.46E-I0 1.73E'I0 2.09E-10 5.92E-I0 ].18E-09 2_]3E-09
4.0E+03 7.07E-10 2 89E-I0 2.97E-I0 3.33E-I 0 3.80E-I0 8.25E-I0 1.40E-09 2.27E-09
7.0E+03 1.40EL09 5.93E-I0 6;03E-I0 6 49E-I0 7.07E-I0 1.18E-09 1.70E-09 2.46E-09
1.0E+04 1.97E-09 9.45E-I0 9.56E-I0 !.00E-09 1.06E-09 1.50E-09 1.97E-09 2.62E-09
2,0E+04 2.98E-09 1.97E-09 1.98E-09 2.01E-09 2.05E-09 2.33E-09 2.62E-09 2.98E-09
Notes: For Chebyshev fits of the abo_le rate coefficients it is necessary to use the following parameters.
Eml n = 2.0E+00 eV, Ema x = 2.0E404 eV
Chebyshev Fittin_ Parameters for Rate CoefficientsHe
Temp.
(eV) AO A1 A2 A3 A4 A5 A6
I0. -5.00830E+0] 5.12336E+00 -2.62808E-01 8.40742E-02 2.48250E-01 -].23169E-01 -7.59116E-02
i00. -4.68137E+01 2,59124E+00 7.95345E-01 5.35033E-02 1.89675E-03 -1.71822E'02 -5.25035E-02
500 -4.53295E+01 1.72678E+00 8.43475E-01 ].98073E-0! -3.44576E-02 -5.47555E-02 -3.44800E_02
I000 -4.46993E+01 1.46770E+00 7.78210E-01 2.19162E-01 -2.15385E-02 -5.87801E-02 -3.66707E-02
5000 --4.24353E+01 7.86347E-01 4.49607E-0] ].53041E-01 5.53429L-03 -2.94156E-02 -2.10243E-02
i0000 -4.10534E+01 4.26270E-01 2.5192]E-01 9.52564E-02 1.32834E-02 -I.03321E-02 -9.66498E-03
20000 -3.98951E+01 1,67503E-01 1.03069E-01 4.32423E-02 9.86815E-03 -1.82969E_,03 -3.51334E-03
Equal Temp -5.]1417E+01 7.32023E+00 -2.04605E+00 1.24837E+00 -5.]2909E-01 3.38169E-02 -1.21200E-0]
See appendix for Chebyshev fit detai]s.
B-71
I--le+ + He -> He(.2'S + 235)
Maxwellian Maxwellian
10-8 -_----T'l lllIIll I I I iIinl l i r-rTTIT[-'-'-T'--T-'TIIIII I I I 11111_4
- - He Temp.
(eV)-
_ A --10.10-_ _x --100.
- @..4
-- --I
- _ v --500,
"_ 10-'° × ....... _ -- 1000.I'D
• -_ _ • --5000.
C@ _ m -- I0000.'O IC)-'-
- - _ --20000.(i) --
0 --
U --
- - Recommended
0 10-12_ _--Data
- -, .... Chebyshev Fit
10-_- Equal Temp.
/10 -1'_ t i 111111 1 I iiiiii1 I 1 1111111 I 1 I llllll I 1 I lllll/v
100 10' 102 18 10" 18He* Temp. (eV)
B-'7 2
Electron Capture Rate Coefficients for.
Ite+ He + -> He(21S + 23S)
Beam - Maxwellian Rate Coefficients (cm3/s)
He +
Temp. He Energy (eV/amu)
(eV) i0000. 15000. 20000. 25000. 30000. 35000. 40000.
1.0E+00 3.62E-09"* 4.10E-09"* 4.29E-09"* 4.44E-09"* 4.57E-09"* 4.65E-09"* 4.68E-.09"*
2.0E+00 3.61E-09"* 4.10E-09"* 4.29E-09"* 4.44E-09"* 4.57E-09_* 4.65E-09"* 4.68E-09'*
4.0E+00 3.61E-09"* 4.10E-09"* 4.29E-09"* 4.44E-09"* 4.57E-09"* 4.65E-09"* 4.68E-09"*
7.0E+00 3.60E-09"* 4.10E--09"* 4.29E-09"* 4.44E-09 _* 4.57E-09"* 4.65E-09"* 4.68E-09"*
1.0E+01 3.59E-09"* 4.10E-09"* 4.29E-09,_ 4.44E-09,* 4.57E-09"* 4.65E-09*m 4.68E-09"*
2.0E+01 3.58E-09"* 4.09E-09"* 4 29E-09"* 4.44E-09"* 4.57E-09"* 4.65E-09.* 4.68E-09"*
4.0E_01 3.57E-09"* 4.09E-09"* 4 29E-09'* 4.44E-09"* 4.57E-09"* 4.65E-09"* 4.68E-09"*
7.0E+01 3.55E-09"* 4.09E-09"* 4 29E-09"* 4.45E-09"* 4.57E-09"* 4.65E-09"* 4.68E-09'*
1.0E+02 3.53E-09"* 4.09E-09'* 4 29E-09"* 4.45E-09"* 4.57E-09"* 4_65E-09"* 4.68E-09"*
2.0E+02 3.50E-09"* 4.08E-09.* 4 29E-09"* 4.45E-09"* 4.57E-09'* 4.65E-09"* 4°6BE-09"*
4.0E+D2 3.45E-D9** 4.08E-09"* 4 29E-09** 4.45E-09,_ 4.57E-09"* 4.64E-09 *_ 4.67E-09"*
7.0E+02 3.40E-09"* 4.07E-09"* 4 29E-09"* 4.45E-09'* 4.57E-09"* 4.64E-09_ 4 64E-09*k
1.0E+03 3.37E-09"* 4.06E-09"* 4.29E-09"* 4.45E-09,_ 4.57E-09"* 4°64E-09 _* 4.58E-09"*
2.0E+03 3.31E-09"* 4.03E-Dg** 4.29E-09"* 4.45E-09"* 4.56E-09"* 4.57E-09"* 4.30E-O9"*
4.0E+03 3.28E-09" 3.98E-09"* 4.28E-09"* 4.43E-09'* 4.47E-09"* 4.32E-09'* 3.B6E-09**
7.0E+03 3.30E-09" 3.93E-09 *_ 4.23E-09"* 4.34E-09"* 4.25E-09"* 3.96E-09"* 3.45E-09"*
1.0E+04 3.34E-09' 3.89E-09'* 4.14E-09"* 4.18E-09,* 4.02E-09"* 3.67E-09"* 3.18E-09'* A
2.0E+04 3.43E-09" 3.71E-09" 3.77E-09"* 3.65E-09'* 3.40E-09,* 3.07E-09'* 2_68E-09"*
Accuracy: * - Possible Error Greater Than 10%
•* -Possible Error Greater Than 100%
NoteS: For Chebyshev fits of the above rate coefficients it is necessary to use the following parameters.
Emi n = 1.0E+00 eV. Ema x = 2.0E+04 eV
Chebyshev Fitting Parameters fo_ Rate Coefficients
He
Energy
(eV/amu) AO Al A2 A3 A4 A5 A6
10000. -3.89516E+01 -4.51244E-02 1.69953E-03 ].65062E-02 1.06870E-02 2.64417E-03 -I.07811E-03
15000. -3.86669E+01 -3.54627E-02 -2.26753E-02 -1.21671E-02 -5.34610E--03 -1.80140E-03 -7.78336E-04
20000. -3.85671E+01 -3.27909E-02 -2.82327E-02 -2.24375E-02 -1.53665E-02 -8.81047E-03 -4.39280E-03
25000. -3.85158E+01 -5.09890E-02 -4.36393E-02 -3.40163E-02 -2.27913E-02 -1.25967E-02 -5.50588E-03
30000. -3.84991E+01 -8.72591E-02 -7.04596E-02 -4.87052E-02 -2.79930E-02 -].24934E-02 --2.97299E-03
35000. -3.85280E+01 -1.39891E-01 -I.06634E-0_ -6.39054E=02 -2.79358E-02-6.05892E-03 3.51648E-03
40000. -3.86081E+01 -2.17036E-01 -1.48805E-01 -7.02850E-02 -1.44258E-02 8.74155E-03 8.88909E-03
See appendix for Chebyshev fit details.
,
B-73
He + He*->He(2'S + 23S)
Beam MaxwellianO
I05,_,5 '" I I I I Ittl I t I 11 lilt I ---r" tl 111111 i t 11TIII I I i i i iiii'x
He Energy
50.0 - (eV/u m u)
A -- 10000.4-7,5 -
- x -- 15000.
45.0 - v --20000.
_ --25000.
E 4-2.5o • -- 30000
..l_.a
c 40.0@ m -- 35000.(D
'+- 37.5 - [] -- 40000cD0
URecommended
o 35 0o - Data
32.5
- Chebyshev FitIU
30.0
t3-7 4
AElectron Capture Cross Sections for
lie+ + He -> He(21p) + He +
Energy Velocity Cross Sectlon
(eV/amu' (cm/s) (cm 2)
1.3E+03 4.91E+07 1.25E-18
2.0E+03 6.21E+07 1.28E-18
3.0E+03 7.61E+07 1.07E-18
5.0E+03 9.82E+07 9.00E-19
8.0E+03 1.24E+08 7.67E-19
1.0E+04 1.39E+08 7.03E-19
2.0E+04 ].96E+08 5.17E-19
4.0E+04 2.78E+08 3.52E-19
7.0E+04 3.68E+08 2.29E-'19
1.0E+05 4.39E+08 1.46E-19
1.5E+05 5.38E+08 4o86E-20
2.0E.05 6.21E+08 1.60E-20
2.5E+05 6.94E+08 6.01E-21
References: 163, 203
Accuracy: Unknown
Notes: (i) Data between 1.2 - 9x103 eV/amu were never published in a referred journal.
(2) Cross sections between 9x103 and Ixl05 _v/amu were obtained by interpolation between
the low and high energy data. s
(3) For energies less than ixl05 ev/amu the cross sections measured by Hippler et al
(ref. 203) diverge from the data prestrnted here.
ll
For a Chebyshev fit of the above cross sections it is necessary to use the following parameters.
Emi n i= 1.3E+03 eV/amu, Ema x = 2.5E+05 eV/amu
Chebyshev Fitting Paralneters for Cross Sections
AO A1 A2 A3 A4 A5 A6 A7 A8
-85.5425 -2.19593 -.936988 -.450041 -.224752 -.0551700 .0123849 .0330118 .0293219
The fit represents the above cross sections with an rms deviation of 1.0%.
The maximum deviation is 2.0% at 7.0E+04 eV/amu.
See appendix for Chebyshev fit details.
®
B-75
O
He+ + He->He(2'P) + Ple+
Cross Section vs. Fnerg,\/
0 17 I I I I I 111 I ' I I I I I I I I I I I 1 I I I I L
,--
.-
i0-18_- "--_- _ -_---
_ "--,.,. .-
- _,.,.• _E - "-..(D \
C \
o \+_ 10-1_-¢_ - \br) - _ -
- \ -\ -
L° _ RecommendedU \ - Datai
/ -10-_'- 1 -
_- \ _-......Chebyshev Fit\ --
--
--
10-21__ ,i I I I I Jlll I I _LI J_III ___ i I I ,,II ILl
103 ,10'_ 10s 10_Energy (eV/am u)
0
B-76
Electron Capture Rate Coefficients for
lie+ + He -> He(2]P) + lie+
Ma×wel]ian - Maxwellian Rate Coefficients (cm3/s)
lle+
Temp. Equal He Temp. (eV)
(eV) Temp. 500. I000, 2000. 4000. 7000. i0000. 20000.
4,0E+02 3.80E-13 7.28E-13 4.54E-12 1172E-II 3 90E-II 5,75E-11 6.77E-II 8,29E-ll
7.0E+02 4.54E-12 2.64E,-12 8.03E-12 2. lIE-II 4 ] 5E-II 5.87E-II 6.85E-II 8.32E-.I ii
].0E+03 1,19E-11 5.64E-12 1 19E-II _.48E-II 4 38E-II 5.99E-II 6.92E-II 8.34E-II
2.0E+03 3.54E-II 1.85E-II 2 48E-II 3.54E-ii 5 03E-II 6,36E-II 7.15E-II 8.42E-II
4.0E+03 5,99E-II 3.98E-II 4.38E'II 5.03E-II 5 99E-II 6.92E-II 7.52E-II 8.56E-II
7,0E+03 7.52E--II 5.79E-II 5.99E-II 6.36E-II 6 92E-.II 7.52E-II 7.95E-II 8.73E-11
1.0E+04 8.26E-II 6,80E-II 6.92E-II 7.i5E-il 7 52E-II 7.95E-II 8.26E-II 8.87E-II
2.0E+04 9.16E-II 8 30E-II 8o34E-II 8.42E-II 8 56E-II 8.73E-II 8.87E-II 9.16E-II L
Notes: For Chebyshev fits Of the above rate coefficients it ii necessary to use the following,parameters.
Eml n = 4.0E+02 eV, Ema x = 2.0E+04 eV
Chebyshev Fitting Parameters for Rate Coefficients
He
Temp. @(eV) AO A1 A2 A3 A4 A5 A6
500. -4.99295E+01 2.33819E+00 -6 50090E-01 4,21924E-02 3.49426E-,02 -1.24395E-02 -i II193E-04
i000 -4.88301E+01 1.49821E+00 -2 72937E-01 -4.12913E-02 2.79783E-02 -2.24988E-03 -2 38793E-03
2000 -4.78893E+01 8.38347E-01 -5 35952E-02 -4.83802E-02 7.58342E-03 3.24901E'03 -8 41972E-04
4000 -4.71958E+01 4.15561E-01 2 60,934E-02 -2,42784E-02 -3.22992E-03 1.67069E-03 3 02996E-04
7000 -4.68029E+01 2.17494E-01 3 41131E-02 -8.30328E-03 -3.82190E-03 -5.16068E-05 2 23242E-04
]0000 -4.66140E+01 1.38147E-01 2 86268E-02 -2.78051E-03 -2.76127E-03 -4.58542E'04 5 63634E-05
20000 -4 63524E4.01 4.94719E-02 1 41098E-02 5.11657E-04-9.99744E-04-2.34546E-04-2,76502E-04
Equal Temp. -4.94385E+01 2.39001E+00 -Io04807E+00 3.37080E-01 -8.59497E-02 1.50447E-02 -2.44681E-03
See appendix for Chebyshev fit details,E
@
i
B-7"/
He+ + He-->He(2'P) + He+
MGxweliGn- K/Io×weliGn
10-10- ' ' ' ' '"''Jl ' i , ,-sr-rm-r_ J i i, ,l,L
- m - He Temp,
- e-.-
- _......__/_ - (eV)- - A -- 500.x -- 1000.
///v --2000.
-_, 11
-,? 10- - : _-4ooo o
_,_ E -.3 - • - 7000.-l-J
('-" ,_
@ [] -- I0000.
.9 _ I /'+- I',4-,--
_ --20000.
0 - /I
o@ Recommended
o 10-12- --DatQPr" 7
--. Chebyshev Fit/
Equal Temp.
I0"-'3------L' ''''Hl. ' ' ''''-iU-- ' , ,,,_U_10_ 103 10' 10s
He+ Temp. (eV)
B-78
b
Eleotron Capture Rate Coefficients for
He 4. He + -> He(21p) + He _
Beam - Maxwellian Rate Coefficients (cm3/s)
He +
Temp. He Energy (eV/amu)
i' (eV) i0000. 20000. 40000. 60000, 80000. i00000. 120000.
1.0E+00 9,76E-II 1.02E-10* 9.78E-II* 8.77E-II* 7.60E-ii* 6.40E-II* 4.28E-II**
2 0E400 9.76E-II ].02E-10 9.78E-II* 8.77E-II* 7,60E-II* 6.40E-II* 4.28E-11'*
4 0E+00 9.76E-II 1.02E-10 9.77E-II* Q.77E-II* 7.60E-II* 6.40E-II* 4.28E-II**
7 0E+00 9.76E-Ii 1.02E-10 9.77E-II* 8.77E-II* 7.60E-II* 6.39E-II* 4.28E-II**
1 0E+01 9.76E-II 1.01E-10 9.77E-II* 8.77E-II* 7.60E-II* 6_39E-II* 4 28E-II**
2 0E+0] 9.76E-11 1.01E-J0 9.77E-II* 8.77E-II* 7.60E-II* 6,38E,-II* 4 28E-II**
4 0E+01 9.76E-II 1.01E-10 9.76E-II* 8,77E-II* 7.60E'II* 6.36E-II* 4 29E-II*
7 0E+01 9.75E-!I 1,01E-10 9.75E-II 8.77E-II _ 7.60E-II* 6.35E-II* 4 29E-I] *
1 0E+02 9.75E-II 1.01E-10 9.75E-II 8.77E-II* 7.60E-I]* 6.33E-11' 4 29E-II*
2 0E+02 9.75E-II 1.01E-J0 9.74E-II 8.77E-II 7.60E-II* 6.30E-ii* 4 29E-II*
4.0E+02 9_74E-II 1.01E-10 9.72E-ii 8,77E-II 7.60E-II* 6.26E-II* :4 30E-ll*
7.0E+02 9.73E-II 1,01E-10 9,70E-II 8.77E-11 7.60E-II* 6.21E-II* 4.31E-II*
1,0E+03 9.72E-II 1.01E-10 9.68E--II 8.76E-II 7.60E-II* 6.18E--II* 4.32E-II*
2.0E+03 9.70E-II 1.01E-10 9.64E-II 8.74E-II 7.58E-II* 6,10E-II* 4,34E-II*
4,0E+03 9.68E-]I ].00E-10 9.58E-II 8.68E-II 7,50E-II 5.99E-II* 4.36E-II*
7.0E+03 9.63E-II 9.96E-II 9 5lE-II 8.59E-II 7.38E-II 5.88E-]I* 4.36E-II* l
1.0E+04 9,59E-II 9.90E-II 9.43E-II 8.50E-II 7,26E-II 5.80E-II* 4.35E-]I*
2.0E+04 9,52E-II 9;71E-II 9.18E-II 8.18E-11 6.92E-II 5.56E-II* 4.27E-II*
AcOUl:acy: * - Possible Error Greater Than ]0%
• * - Possible Error Greater Than 100%
Notes: For Chebyshev fits of the above r_te coefficients it is necessary to use the following parameters.
Emi n = 1.0E+00 eV, Ema x = 2,0E+04 eV
Chebyshev Fitting Parameters for Rate Coefficients
He
Energy
(eV/amu) A0 A1 A2 A3 A4 A5 A6
I0000. -4 61121E+01 -I.01540E-02 -5.73295E-03 -2.50999E-03 -8 40721E-04 -1.26867E-04 ] 76279E-04
20000 _. -4 60412E+01 -1.63968E-02 -9 47895E-03 -4.78055E-03 -2 35744E-03 -I,]4505E-03 -5 31594E-04
40000, -4 61253E+01 -.2.31383E-02 -i 33331E-02 -6.62458E-03 -3 18902E-03 -1.53689E-03 -7 59534E-04
60000. -4 63375E+01 -2.]6963E'-02 -i 67017E-02 -]._7850E-02 -5 66807E'03 -2,33604E-03 -7 64767E-04
80000. -4 66323E_0] -2.96500E-02 -2 31326E-02 -I,47960E-02 -7 40205E-03 -2.57953E-O3 -2 97132E-04
i00000. -4 70209E+01 -5,97314E-02 -2 79167E'02 -.9.52672E-03 -2 96002E-03 -I.]7463E-03 -6 06512E-04
120000. -4 77385E+OI 5.7017gE-03 -3 34664E-04 -4.37679E-03-4.62136E-03 -2.70887E-03 -7 41640E-04
See appendix for Chebyshev fit details.
@
B-'19
1 +He + He+ --> He(2 P) + He
, B-80
Eleatron Capture Cross Sect:ions roti
,
lie + -I lle -> IIe(31S,3]pt31D), + lle I
(31S) (alp) (3.10)
Energy cross seat_on Energy Cross Section Energy Cross Section'
eV/ainu elll2 eV/alnu I em 2 eV/allltl (Jlll2
2.5E+03 2.17_-19 7.5E+02 2.34E-19 20E.03 5.30E-19
3.0S+03 2.02_-19 1.0E+03 2,53E-'I 9 2 5E+03 4.91E'19
3.8E+03 1.94E-. ; 1.5E.03 3,57E-19 3 0E403 " ,42E-19
5,0S+03 2.13F,-19 2.0B+03 6,16E-19 3 5E+03 5.64E-19
7,0E+03 2,79B-19 2.5E+03 7.91E-19 4 DE+D3 _2.'/6E-I 9
[i.0_+03 3,30_-19 2,6B,_03 7.96E-19 5 DE+0_ 8.93E-19
I,OE+04 4,93_-19 3.0E.f03 7.34E-19 6 DE+U3 9.23E.-] 9•
1,5E+04 8,44E-19 3.5E+03 6 28E-19 ?.OE+03 9,]3E-19
2,0E+04 1,13_-1B 5.0E+03 500E-19 ]. OE+0,1 8.17E.-19
2,5E*04 1.27E-IS 6.5E+O'J 4 72E-]9 1.5E404 6.28E-19
3,5E-f04 1,3[_I._-18 8.OEr03 5 03E-19 2,0E404 4,69E-19
4.0E+04 I. 40E-18 1.0E+04 5 97E-19 2.5E404 3.48E-19
1.3E_04 0 63E-19 3,0E+04 2.50E-]9
, 1,5E+04 1 12E-18 3,7E+04 1.41E-19
2.0E+04 i 44E-]8
2.2E+04 1 45E-] 8
2.5E+04 ] 40E,-18
3.0E+04 1.24E-18
3.5E+04 i. 021';-18
3.8E*04 8. 691']-19
Referencesl 31S- 204/ 31P- 20, 204, 205, 2061 31D- 20, 204, 2,06
ACCU rac_._ 40%i
ot_ (I) The ClU.oted accuracy is only an estimate, The dl_agreement between the data _ets Is
as large as a factor of 2 or mole.
(2) T[)e cross section (o i} for ¢;aptUre into state I 11] c|etermlned by measuring tile
smlssloll cross section _lj) [_.r a t[ansltion [ioln IJtal.e I to j, correcting fo_ ally
btanchil%g from state i and correcting for cascading from u|>pe_ _tates.
For Chebysbev flts of the above cross sectlons it is necessary to use the following parameters.
(31S) Einln = 2.5E+03 eV/ainu, Ems x = 4.0E+04 eV/ainu
(31pi Eml n = 7.5E+02 eV/amtl, Ems X = 3,8E+04 eV/ainu
(31D) Emill = 2.0E+03 eV/afnu, Elllay' = 3.7F,+04 eV/a(nu
(:het,y_,hov Fittinq Parameters for C'lols_J Sect.]_
A0 AI A2 A3 A4 A5 A6 A'; AB
(31S) -84.2567 1.14450 .0774864 -,24835] ,00546389 ,04756]'I -6,68831E-04 -.0125101 ,00445413
(31pi -83,9443 .784951 -.124752 .043138|I -.173909 -.262303 i(1929503 .0881n88 -..0630714
(]lD) -84.384"I -. 485772 -.595547 -.0904580 .0360540 -,0805642 .O22337B -, 006"13[,03 -.0137040
The flt represents the (31S) cross sectloll with an rlllS deviatlon of 1,2%,
The maxlmuln deviation Is 1,9% at 8,0E+(J3 eV/ainu, --
The flt repre[_el_ts the (31pi c_oss sectloh wit}, arl rms devlatlOrl of 3.7%.
The maxlmum deviation Is 9.7% at '3,5E+03 eV/,,mu.
=
The fit. represents the (310) utoss F._ec'i:lon wlth ,:I11 rll,s deviation of ] ,0%,
The maximum deviai Ius i_ 2,5% aL 3,0I'i-I.03 eV/alnu, i
See appendix f(,[ Chebyshev fit detail_;,
B-B1
He+ +. He-> He(B'S,B'P,B'D) + He+
Cross Sectionvs. E:nergy
10-,7 , r, li ill I i i-i i I-i ill _ i i i lilT
_ _ /, - (3'S)
- - x - (3'P)
_ _ _ __(31D)
0 "E(J
c-O
10-; -
e / -- \ '
Q_) - _J
//l -_ v -_. , Recom mended
- --- Doto
..... Chel:Gshev FitI--0I, _ J_ _ !___LI ..... , i i i tj_J_l _.L_a__L_L_LLU
lo_ lo_ lo_ 1o'Energy (eV/clmu)
0
B-82
Elout. ron Captulc, Crost_ SE_ctJonr] 17or
lie "t + lie -> tle(33S_33t',33D) -i ilo _
(33S) (33P} (331_)
Energy Cross Seotlon Energy Cross Sentlon Energy Cio:_tlS{,_ct.ion
eV/ainu cm 2 eV/ainu cm2 eV/ainu (:m2
5,0E+03 4.52E-19 2o5E+02 2_05E-19 205E+02 ] 34E ]B6.0E+D3 4,65E-19 3.0E+02 2.02E-19 3.51.;+02 1 21E-]8
7.0E+03 4.89E-19 4, og+02 2.01E-19 5,01::+02 ] 07E-IS9,0_]+03 5.87E-19 6,0E4,02 2.331.:-19 7,0_H.02 B 97E-19
.. 0E+04 6.64R-19 8.01.1+02 3,03E-19 8.0E+02 B BIE-19i. 5E+04 I,26E-IB I. 0E+03 3,79E-.19 9.01_H02 [i94E-192,0E+04 I .93E-10 1.5E+03 6,16E-19 1,0E+03 9 43E-19
2.5_+04 2.68E-18 2,0E+03 8,05E-19 1.4E+03 I 35 E-,i|I3.OE+04 3.06_]-.18 2.5E+03 6,58E-19 1.7E+03 ] 0BE- l|J
3.0E403 6.31E-19 2.0E403 7 90E-194,0_+03 6.60E-19 2..5g+03 6 61g-196.0R+03 7.151'.]-19 2.88403 7 27E-198.0E+03 7,71E-]9 3.4g+03 fl22E-]99.9E+03 8.351.:-19 3.8E403 8 50E- 19
].5E+04 9.99E-19 4,5E+03 [I12E-192.0E+04 I.]lE-l|! 5.4E+03 6 94}.',-1.93.0E+04 1.251.]-18 5,9E+03 6,69E-193.7E+04 ].31E-18 6,5I.H03 7.03E-]9
7.1E+03 8.22E-197,7E+03 9.521.:-19B,5E+03 9.90E-191,OEr04 9.53E-19I. 2E+04 8.48[..:-191.5E404 6,73E-19] .7E+04 5.33E-192.2E+04 3.49E-192,9E.t04 2.34E-193,8E+04 ] .63E-19
_efersnoes£ (33S) -. _0, 2061 (331,) -20, 204, 205, 2061 (330) .-20, 204, 205, 206 O
Accur,aoy _ 40%
Notes_ (i) The quoted accuracy rs only an estinlste, rr'hedlsag:esment betwe_ll tile data sets is
aa large as a [actor of 2 or more.
(2) The cross section (el) fnr capture into state I is determined by measuring tile
onlissioll cross section (eli) fnr a transition from state I to J, co_rectlng for ally
branching from stale i and correcting for cascading from u'_pet states.
For Chebyshev fits Hf the above (,'rossseotlons .rr is neuessary to use tile following paralllel:t,l:_.
(33S) Eml n = 5.0E+03 eV/amu, Ema X = 3.01_+04 sV/amu
(33p) Eml n = 205E+02 eV/ainu, Ems X = 3.7g+04 eV/ainu
(33D) Eml n = 2.5E+02 eV/ainu, Ems x _ 3,8E+04 eV/ainu
Cheb_shev Fitt'Ing Parameters for Cross Sections
AO AI A2 A3 A4 A5 A6 A7 A_J
(33S) -82.7952 1 05996 146880 - 0978993 0162972 ,0066,1821 -,0131980 .0124651 .00414"/c', , " ° -" - j .l
(33p) -84.1155 .979750 -,132417 .00802795 .12]042 -,129354 -.0323880 °0827000 -.0303641
(330) 03,6677 .841000 -,315720 -.312650 -.0741395 -.00902"94 ,0814994 ]22383 -.0(,55rt)_
The fit represorlts the (33S) cross t_t.'otlollwith an rms deviation (,f 0,0%.
The maxlfaul, deviation is O.0% al; 6.0E+03 eV/ainu.
'l'h_fit represents tile (33p) cross section with an l:ms devlatJol] of 5,3%,
The maximum devlat]on is 9.0% at 3.0E+03 eV/ainu,
The flt represents the (330) ct'one Seotion with tln rms dev[atlorl of 11.0%.
The maximum deviation is 23,9% at 2.5E+03 eV/ainu. _ I
lm,See appendix for Cheb_shev fit (I£_talls,
B-83
He+ + He-> He(33S,33P,33D) + He+
Cross Section vs. Energy:
Chebyshev FitlO-,g l J i ill I li _h_ J l IJl 1.11 1 I I L LLLL
1('32 103 104 105Energy (eV/am u)
B-84
AF,lOctron Cal.)Lure CroSs SectlonD fo_
Ilo + + )le -.> Ile(41S,41p,41D) 4 lie +
(410) {41p) (41D)
Bnergy CiosB Seotlon Energy CrCBB Seotlon 8nergy CroSs Sect[on
sV/ainU cm 2 eV/ainU sm _ eV/,iinU cm 2
6.28+02 0,66F:..21 1.08+03 8,65E-20 2.5E+02 "1.248-20
7.3E+02 1,11E-20 1.1E+03 6.69E-20 3,0E+02 9 3BE-209,48+02 1,29E-20 I. 28+O3 5.338-20 3.5E+02 ] 038-19
I 0_:+03 1.30E-20 1,3E+03 4.828-20 4.1E+02 8 76E-20
1 28+03 1.23E-20 1.38+03 4.838-20 5.08+02 5 108-20
1 38+03 1.16B-20 1.4E+03 5.178-20 6,2E+02 3 558-201 48+03 ].IBE-20 1.6E+03 6.048-20 7.2E+02 3 99E-20
1 5E.F03 1.33E-20 1.8E+03 7.458-20 8.1l'I+02 4 868-20
1 68+03 1.658-20 2.2E+03 9.50_-20 9.1E+02 6 148-.201 88403 2.32E-20 2,6E'_03 1.16_:-19 1,0E*03 I 60E-20
2 08+03 2.871:-.20 3.2E+03 1.41_;_19 I.IEIU3 7 868-.202,3E+03 3,621:-20 3.6E_03 1.61E-19 I. 3E+03 7 941::-20
2.68+03 3,878-20 3.98_03 1,63E-19 1,6E+03 8 078..20
2.7E+03 3.93E-20 4.3E+03 1,61E-19 1,9E+03 8 23E-203.08+03 3. 838-20 4,9E+03 1.528-19 2, IE+03 0 65_:-20
3.2E+03 3,72E-2,0 5.4E+03 1.52E-19 2. 2111+03 1 04E-19
3.7E+03 3.62E-20 6.4E+03 1.64E-19 2,4E+03 1 168-194.18+03 3.698-20 7,5E+03 1.86_':-19 2.5E+03 1 188-19
4,98403 4.02E-20 8.68+03 2 32E-19 2.7E+03 1 fOE-19
6.5E+03 5.108-20 1.08+04 2 908-19 2.9E+03 8 958-20
7.9E.03 6.198-20 I,IE+04 3 508-19 3.0E+03 7 138-209.68+03 7.73E-20 1,3E404 4 29E-I.' 3.]E+03 6 368-20
1,2E+04 1,00E-19 1,6E+04 5 018-19 3.3I;+03 6 248-20
1.48+04 1.398-19 i. 88+04 5 80E-19 3,58+03 6. 408-201.6E+04 1,748-19 2.08+04 6 088-19 3.78+03 7 018-20
1.98+04 2,02E-19 2.4E+04 5 83E-19 3.98+03 8 148-20
2.28+04 2.208-19 2.8E+04 5 208-19 4,18+03 9 94_]-20
2.8_:+04 2.29E-19 3,2E+04 4 488-19 4.4E403 1 18[:-193.38+04 2.25E-19 3.7E+04 3 78E-19 4.0_;+03 1 42_:-19
3,88+04 2.148-19 3.98+04 3 538-19 5.68_03 I 718-19
7.08+03 2 118-198.3F:403 2 428-19
9.7_:.03 2 75B-191.2H+04 3 ]28-19
2.08+04 2 73E-19 _&3.0_:+04 0 42E-20
3,85+04 4 338-20
Referencest (41S) - 20, 204, 205, 206, 207; (41p) - 20, 166, 204, 205; (41D) - 20, 166, 204,
205, 206
Accuracyt 40%
Notes_ (I) The quote(] accuracy Is only an estimate. _'he dl_agreement between the data BL,ts IB
aB large as a factor of 2 or mo_e.
(2) The cross section .(.1) for capture into state i is determined by measurlng the
emission cross section (_lj) for a transition from state I to J, correcting for any
branching f[oin state i and correcting for cascading from upper states.
For Chebyshev flts of the above cross sections it is necessary to use the followlng parameters.
(41S) ' Eml n ". 6.2E+02 eV/ainu, Ema x : 3.88+04 eV/amu
(41p) Eml n - 1.08+03 eV/ainu, 8ma x = 3.98.04 eV/ainu
(410) Eml n = 2,58+02 eV/alnu, Ema x = 3.8_:+04 eV/ainu
Chebyshev Fittincj Parameters fur Cross Sections
AO Al A2 A3 A4 A5 A6 A7 AB
(41S) -88.9247 1.69591 .0108804 -.0955575 -,0023400 -,127347 -.00167808 _]49767 -.0939805
(41F) -86.2453 1.12538 -.147764 -.263207 -.0637178 -.16_724 .168441 .00791441 -.0240933
(410) -07.4670 .304065 -,224271 -.683543 -.287424 -.I18320 -.0304248 .229919 -.141272
The fit cepresent_ the (41S) ccoss suction with an rms deviation of 8.5%. =
The maximum deviation is 17.4% at 7.3E+02 eV/ainu.
The fit represents the (41p) c,oss section wit|, an rms deviation of 3.5%,
The maximum devlatlon Is 7.]% at: 2.6E+03 eV/ainu.
The flt represents the (41D) Cross section with an fins devlat'.J.(,tl of 16.5%,
The maximum deviation ts 37,8% at 3.38+03 eV/ainu, t
See appendix for Chebyshev fit details.
B-85
" He+ + He ->He(¢_S,41P,4-'D) + He+
Cross Section vs, Energy
i0-,8__ I I I I"1 I I I I I I I I 1 '1 I I I I I I I I I I
_ - z_- (4'P)/
_ x - (4'S)
- (4'D)10-19_ ,,',
• -_ -c" -
,0 -
V - /,,('_ - /
6O© j
U i0-2c_ y-. ,,-,m
- Recommended
DQta
10- Chebyshev Fit21 I 1 I I I 1111 I I I I IJLLII ,I I I i 111
lO_ lO_ lo_ lO_Energy, (eV/amu),
B-86
Electron Capture Cross SectiOns let
}le+ + lle -> He(43S,43p,43D) . lie:_
(43S) (43pi (43D)
Energy CrossSection Energy Cross Section Energy Cross Section
eV/amu cm 2 eV/amu cm 2 eV/amu cm 2
3.7E+02 3.9oZ-20 2.5E+02 3.05E-20 2.5E+02 2.84E-19
4.0E+02 _.25E-20 3.0E+02 2.388-20 3.0E+02 3.39E-195.0E+02 2.09E-20 4,0E+02 1.78E-20 3.5E+02 ' 3.62E-196,0E+02 2.]2E-20 5.0E+02 1.62E-20 3.8E+02 3.56E-19
7%0E+02 3.06E-20 5.3E+02 ].64E-20 4.2E+02 3.26E-197.7E+02 3.58E-20 5.6E+02 1.95E-20 4.9E+02 2.51E-19816E+02 3.44E-20 5.7E+02 3.00E-20 5.7E+02 2.06E-199.7E+02 3.17E-20 6.3E+02 4.53E-20 6.8E+02 1.76E-19
I.IE+03 3.08E-20 6.7E+02 3.97E-20 7.7E+02 1.66E-191.3E+03 3.30E-20 7.5E+02 3.137E-20 8.1E+02 1.71E'19|.5E+03 4.12E-20 8.3E+02 2,95E-20 8.9E+02 ].97E-19
1.7E+03 4.94E-20 9.2E+02 2.72E-20 9.9E+02 2.33E-192.0E+03 6.01E-20 1.0E+03 2.64E-20 I.IE+03 2.68E-192.4E+03 6.91E-20 I.IE+03 2.85E-20 1.2E+03 2.89E-192.6E+03 7.00E-20 ].4E+03 3,84E-20 ].3E+03 2.89E-,193.0E+03 6,90E-20 1,7E+03 4.83E-20 1.5E+03 2.64E-193.6E+03 6,54E-20 2.0E+03 6.20E-20 1.7E+03 2.26E-194.1E+03 6.71E-20 2,3E+03 8,50E-20 2.08+03 1.85E-19
5.5E+03 7.97E-20 2.6E+03 9,79E-20 2.4E+03 1.50E-197.6E+03 1.09E--19 3.0E+03 1.02E-19 2.6E+03 1.35E-19
9.7E+03 1,48E-19 3.5E+03 9,51E-20 2,9E+03 1.21E-19 ,1.2E+04 1.96E-19 4.0E+03 8.49E-20 3,2E+03 1.20E-191.5E+04 2,73E-19 4.7E+03 7,84E-20 3.4E+03 1.23E-191.7E+04 3.88E-19 ' 4.8E+03 7.76E-20 3.8E+03 1.37E-19
2.1E+04 5.52E-19 5.2E+03 8.09E-20 4.4E+03 1.60E-192.6E+04 7,13E-19 6.3E+03 9453E-20 5.1E+03 1.91E-193.0E+04 8.28E-19 8_8E+03 ].28E-19 6,1E+03 2.30E-193.4E+04 8,61E-19 1.4E+04 1.88E-19 7.3E+03 2.77E-19
3.7E+04 8.65E-19 2.0E+04 2.47E-19 8.4E+03 3,08E-192.7E+04 3.26E-19 9.8E.03 3.28E-19
3.3E+04 3.87E-19 I.IE+04 3.24E-193.8E+04 4.07E-19 1.3E+04 2.96E-19
1.4E+04 2.63E-191.6E+04 2.29E-19
2.0E+04 1.78E-192.5E+04 1.31E-193.0E+04 1.07E-19
3.4E.04 8.18E-20 e3.8E+04 6.62E-20
References! 43S) - 20, 166, 204, 205, 206, 2071 (43p) - 20, 166, 204, 205, 2071 (43D) - 20,
166, 204, 205, 206, 207
Accuracyz 40%
ot._Lq.___z(]) The quoted accuracy Is only an estimate. The d*sagreement between the data sets Is
as large as a factor of 2 or more.
(2) The cross section (el) for capture into state I is determined by measuring the
emission cross section (,li) for a transition from state i to J, correcting for any
branching from state i and correcting for cascading from upper states.
For Chebyshev fits of the above cross sections it Isnecessary to Use the following parameters.
(43S) Eml n = 3.7E+02 eV/amu, Ems x - 3.7E+04 eV/amu
(43P) Eml n = 2.5E+02 eV/amu, Ems x = 3.7E+04 eV/amu
(43D) Eml n = 2.5E+02 eV/amu, Ems x = 3.8E+04 eV/_mu
¢_ebyshev Fitting Parameters for Cross Sections
A0 A1 A2 A3 A4 A5 A6 A7 A8(43S) -87.3205 1.78746 .468525 -.0126958
.0197677 -.212447 6.18482E-04 -.0153550 .0609384
(43p) -87.9948 1.50655 .179990 -.0510960 .136680 -.148566 t.0)70060 -.0293030 .130037
(43D) -86.1432 -.506204 -.0953983 -.353322 -.207541 .0157713 .0723366 .167609 -.197508
The fit represents the (43S) cross section wlthan rme deviation of 9.9%.
The raximum deviation is 20.9% at ].3E+03 eV/amu.
The fit represents the (43p) cross section with an rms deviation of 19.8%.
The maximum deviation is 45.5% at 5.3E+02 eV/amu.
The fit represents the (43D) cross section wlth an rms deviation of 11.3%.
The maximum deviation is 34.8% at 3.0E+02 eV/amu.
See appendix for Chebyshev fit details.
W
B-87
O
He+ + He -->He(4.3S,43P,4-_D) + He+
Cn_ss 3ectlcn vs E]nergy
10-_8I I I''1 I I I I I I I' I I I I I I I I '1' I I I I
_ / -
/ " - (4_S)
, , ,, x -- (4-_P)I
- _ - (43D)
//
,_--, ,,\, / ",, lJ -
c !0 1_'_ 10- - , ,,
(_ -- j, ,*, ,(/-)' / ,t
CO
(.f) , '//_
0 - I /
U ''
tl,.tl.<' Recommended
_X_ - Data
..... Chebyshev Fit10-2'___._ , J JJl_l 1 I I I lJlll I J J *JJJl
102 103 104 105Energy (eV/amu)
0
B-88
q
OLine Emission cross sections of Elect:ron Capture Collisions forq
He + + Li -> He(58.4,53.7) + Li +
(58.4 nm) (53.7 nm)
Energy Cross Section ' Energy Cross section
eV/amu cm 2 eV/amu cm 2
5.0E+02 1.54E-16 5.0E+02 1.29E-18
1.0E+03 2.45E-16 8 4E+02 4.50E-18
1.3E+03 2.63E-16 1 0E+03 6.81E-18
1.5E+03 2.68E-16 1 5E+03 1.05E-17,
2.0E+03 2 87E-16 2 0E+03 1.47E-17
2.5E+03 3 31E-16 2 5E+03 2 06E-17
3.0E+03 4 38E-16 3 0E+03 2.93E-17
3.5E+03 5 02E-16 3 5E+03 3.98E-17
4.0E403 5 21E-16 4.0E+03 4.53E-17
4.5E+03 5 38E-16 4.5E+03 4.77E-17
5.0E+03 5 53E-16 5.0E+03 4.80E-17
References: 267
Accuracy.} Unknown
Note: (i) The 3p ip0 _ is 2 ]S transition gives rlse to the 53.7 nm line with the 58.4 line O
radiation coming from the 2p ip0 _ is2 l S transition.
For Chebyshev fits of the above cross sections it is necessary to use the following parameters.
(58.4 nm) Eml n = 5.0E+02 eV/amu, Ema x = 5.0E+03 eV/amu
(53.7 nm) Emi n = 5.0E+02 eV/amu, Ema x = 5.0E+03 eV/amu
Che.q_h__shevFittinq Parameters for Cross Sections
AO AI A2 A3 A4 A5 A6 A7 A8
(58.4 nnl) -70.6362 -.107414 .390900 .106996 -.435807 .414268 -.355868 .226467 -.0503910
(53.7 nm) -78.5786 2.06788 -.344623 .0776140 .0263737 -,24678! .]72594 -.0896915 .0520900
The fit represents the 58.4 nm cross section with an rms deviation of 1.3%.
The maximum deviation is 2.6% at 2.5E+03 eV/amu.
The fit represents the 53.7 nm cross section with an Ims deviation of 0.6%.
The maximum deviation is 1.4% at 4.0E+03 eV/amu.
See appendix for Chebyshev f_t details.
O
B-89
I-le* . Li-3, He(58,4,53.7) + Li*
Cross Section vs, Energy
-151, , ) i ) _ ) ' 'i , , , , ,-_-r-E_
,f/
_- _ -_ _-58.4- nmx - 53.7 nm
z_
10-_ _ _d" -- :
C) -
c- - //_"_© -
_ - /_) /
(/3 /- /
(_ //
U 10-)7 .t.."-- //
-- J ._
/'-- / --
- / -
_ Recommended
x//// _Data Chebyshev Fit10-18 ) i t J j , I I i L . l l ..i___L_L_.L_L.
ld 10_ 1C.tEnergy (eV/amu)
Q
;_-90
OEl_Jot'ron Capt'ure Cross Sections for
lle 2+ + II ,-> He+(2s) + tl "I
Energy Velocity Cross Section
(eV/ainu) (ct1_/s) (cre2 )
2.3E+01 6 66E+06 1.01E-23
4.0E+01 8 79E+06 1.93E-22
7.0E+01 I 16E+07 2. 961_;_21
1.0E+02 1 39E+07 1.64E-20
2.0E+02 1 96E+07 5.15E-19
4+0E+02 2 78E407 5.71[..:-]+8
7.0E+02 3 68E+07 2.19E-17
1.0E+03 4 39E+07 3.92E-17
2.0E+03 6 211"+07 9.06E-17
4.0E+03 8 79E+07 ].35E-16
7.0E+03 ] .16E+08 ] 57E-16
].0E+04 1.39E+08 1 63E-16
2.0E+04 ] .96E+08 1 40E-16
4.0E+04 2.78E+08 6 73E-17
7.0E+04 3.6BE+OB ] 95E-17 .
1.0E405 4.39E+08 7 ]51!:-18
2.0E+05 6.21E+08 6 07E-19
4.0E+05 8.78E+08 3 70E-20
7.0E+05 1.16E+09 3 23E-2]
I. 0E+06 I. 39E+09 6.01E-22
2.0E+06 1 +96E+09 ]. 561_:_23
2.5E+06 2.19E+09 4.77E-24
Referencesz 2l, 24, 25, 56, 57, 168, 169, 170, 171, 172, 173
Accuracy./ E < l. Sx]03 eV/ainu - unknown; 1.5xi03 eV/ainu < E < 1.2x105 eV/ainu - 40%; E > 1.2x105
eV/amu - unknown
Notes, (ii Data for energies less than 1.5x103 eV/amu and greater than 1.2xi05 eV/amu aret heoretic.al data.
(2) The He+(2s) population is obtained by quenching in an electric field and measuring
the additlonal 30.4 nm photons observed.
For a Chebyshev fit of the above cross sections it. is necessary to use tile following parameters.
Emi n = 2.3E+01 eV/ainu, Ema x = 2.5E+06 eV/ainu
Chebyshev Fitting Parameters for Cross Sections
A0 AI A2 A3 A4 A5 A6 A7 A8
-89.4268 -.438776 -8.73454 .130314 -.0101210 .0343355 .227699 -.188121 -.130396
The fit represents the above cross sections with an rms deviation of 8.2%.
'/'hemaximum deviation is ]9.6% at 2.0E+06 eVainu.
See appendix for Chebyshev fit detaJl+_.
0
B-91
He2+ + H ->He+(2s) + H+
Cross Sectionvs. Ener9y
10-_5 I i"t i11ril _ i rrliil I ' i I l i';Iill i ,I l lilll I ' I I"I llIil'_-"T'_ST__
= .
10-17: =
10-18-
c 10"o --
'-DG)
u_ 10-2c-ooO0
0 _- Recommended
U 10-2_i _-- Data=__]
]0 -2__ _ -- .... Chebyshev Fit
10-2-"
10-24 i 1 lllllll i 1 ill!iii I__LLLIIIIL__I I 1111111_ I I Lt.E.[IL__L_LL/t__
10' 102 103 104 105 106 107Energy (eV/am u)
0
@Elect:ton C,ap_ure Rat',o Coe_'flclont_ foz
fle2_ + II -> Ife'!'(2s) + _I"I'
Maxwel.llan - MaxWellian Rate Coefficients (cm3/s)
ile 2+
T_mp, , Equal tl ¶t'emp, (eV)
(eV) Temp, I0, 10O, 500, I000, 5000. I0000, 20000,
7 0E+00 2 97E-16 ] 49E-15 2,8]E-II ] 30E-09 3,62E-09 1 53E-08 1,93E-08 1.84E-0U
i 0E+01 2.USE-15 2.08E-15 2,88E-II 1 30E-09 3,6RE-09 ] 53[.,I-08 I,_3E-08 1,84E-08
2 0_"_.01 8.24E-14 5 56E-15 3,lIE-II I 31E-09 3.64E-09 1 53E-08 1,93E-08 1,84E-08
4 0E+OI 2,04E-12 2 59E-14 3,60E-I] i 33E-09 3.66E-09 I 53E-08 .1,93E-08 ].841']-08
7 0E+01 1,70ETl1 1 33E-13 4,42E-11 1 37E-09 3,69P.-09 1 53E-08 I093E-0B I,B4E-08
] 0E+02 5,34E-I] 4 24E-13 5,34E-11 i 40E-09 3,73E-09 ] 53E-08 1,93E-08 1.84E-08
2 0E+02 3,27E-I0 4 25E-12 9,04E-II _ 5]E-09 3,84E-09 1 53E-08 1,93F',-08 1,84E-08
4 0E+02 ],29E-09 3 6DE-II 1,93E'-I0 1 74E-09 4,07E-09 i 54E-08 1,93E-08 1 84E-08
7 0E+02 3,03E-09 1 58E-I0 4,04E-I0 2 09E-09 4,41E'.09 I 55E-0B 1,931i_'-08 i 84E-08
i 0E+03 4.75E-09 3 57E-I0 6,67E-I0 2 44E-09 4.75E-09 i 56E-08 1,94E~0B I 84E-08
2 0E+03 9,49E-09 i 33E-09 1,74E-09 3 61E-09 5,81E-09 1 60E-08 1,94E-08 1 83E-08
4 0E+03 1,53E-08 3 66E-09 4,07E-09 5 81E-09 7.77E-09 ] 66E-08 .I,95E-08 I 82E-08
7 OE+03 I.BBE-08 6 B7E-09 7,21E-09 8 66E-09 ].03E-08 i 74E-08 1.96E-08 I 80E-08
] 0E+04 1.96E-08 9,52E-09 9,80E-09 1 tOE-OB 1,23E-0B I BIE-08 ],96E-08 i 78E-08
2 0E+04 1,71E-08 1.53E-08 1.54E-'08 i 60E-00 ],66E-08 1.93E-08 1.951,'_0B I 71E-08
Notes2 For Chebyshev fits of the above rate coefficients it is necessary to use the following parameters.
Eml n = 7,0E+00 eV, Ema x = 2,0E+04 eV
, _shev Fittin9 Parameters for Rate Coefficients
H
Temp,
(eV) AO AI A2 A3 A4 A5 A6
I0, -5,09308E+01 8.87617E+00 -8.39518E~01 -8 53899E-01 3.05164E-01 4 68396E-02 -6,90001E-n2
100. -4.33040E+01 3 46156E+00 6,25707E-01 -3 5227]E-01 -1,41060E-01 4 76365E-02 2,50861E-02
500. -3.92464E+01 ] 26410E+00 4,89137E-01 2 19874E-02 -7.43310E-02 -3 138}7E-02 1,62905E-03
1000. -3.79446E+01 7 26279E-01 3,33593E-01 6 06574E-02 -2,B4279E-02 -2 45434E-02 -6.72865E-03
5000. -3,58707E+01 ] 02283E-01 5,59]05E-02 ] 82827E-02 7,91325E-04 -3 ]8886E-03 -2_27033E~03
i0000, -3,55175E+01 7 32263E-03 2.2,4624E-03 -I 32249E-03-2,]9045E-03 -1 6]I11E-03 -8.21561E-04
20000. -3.56488E+01 -2 68120E-02 -],78967E-02 -9 560]IE-03 -4,19249E-03 -I 52087E-03 -4,56494E-04
Equal Temp. -4.738B6E+01 8,61752E+00 -3,14861E+00 4,07425E-01 -9,02464E-03 -8 8245]E-02 3,10401E-02
See appendix for Chebyshev fit details.
_:1-9.1
I--le_+ + bl - .'.>ble+(2s) + t"t+
k/laxwelliclr_- Maxwellian
I_-94
iElectron Capture irate Coefflgients {',or
H + lle 2+ .-> He+(2B) + tl +
Beam - Maxwelltan l_ate Coefficients (om3/8)
He 2 +
'1'emp. H Energy (eV/ali_u)
(eV) 10000. 20000. 40000, 70000, 100000, 200000, 500000,
I,OE+00 2.26E-08 2.75E-OB 1.87E-08 7.16E-09 3.14E-09 3,77[',-10 1.37E-II
2.0E+O0 2.26_-08 2.74E-08 1.87E-OB 7.16E-09 3.14E-09 3.77E-I0 1.37E-11
4.0E+O0 2.26E-08 2.74E-08 i. 86E.-08 7.16E-09 3.14E-09 3.77E-I0 1.37E-ii
7,0E+00 2.26E-08 2.74E-08 i _86E-08 7.15E-09 3,14E-09 3.77E-]0 1.37E-I]
I,OE+01 2.26E-08 2.74E-08 1,86E-08 7.15E-09 _ 3,13E-09 3,77E-I0 1,37E-ii
2,0E+01 2.26E-08 2.73E-08 I,B6E-0B 7.15E-09 3.13E-09 3.77E-i0 1.37E-I]
4,0E+01 2.25E-08 2.72E-08 1.85E-08 7.14E-09 3,13E-09 3,76E-I0 1.37E-.II
7, OE+01 2.25E-08 2.71E-08 i ,85E-08 7 13E-09 3,13E-09 3,76E-I0 1.37E-I]
1,0E+02 2,25E-08 2.70E-08 1.84E-08 7 13E-09 3.12E-09 3,76E-I0 1,37E-II
2.0E+02 2.24E-08 2.69E-08 i. 83E-08 7 12E-09 3.12E-09 3076E-10 1.38E-II
4.0E+02 2.23E-08 2,66E-08 i. 81E-08 7 lIE-09 3.]2E-09 3.76E-I0 1.38E-II
7.0E+02 2.23E-08 2.63E-08 !. 80E-08 7 fOE-09 3.12E-09 3.77E-I0 1.38E-II
1.0E+03 2.22E-08 2.61E-08 1.78E-08 7 IOE-09 3.12E-09 3.78E-I0 1.38E-II
2.0E+03 2.21E-08 2.55E-08 i .75E-OB 7 11E-09 3.14E-09 3.81E-lO ].39E-11
4.0E+03 2.20E-08 2.47E-08 1.72['I-08 7 18R-09 3,19E-09 3,87E-I0 i. 41E-II
7,0E+03 2.19E-08 2.38E-08 1.67E-08 7 28E-09 3.27E-09 3.99E-]0 1.44E-II
I.OE+04 2.17E-08 2.30E-08 1.64E-08 7 37E-09 3.35E-09 4.11E-lO i. 47E-II
2.0E+04 2.11E-08 2.09E-08 1.53E-08 7.54E-09 3.61E-09 4.58E-I0 1.57E-II
Notes: Per Cbebyshev flcs of the above rate coefficients it is necessary to use the following parameters.
Eml n = I.OE+O0 eV, Ema x = 2.0E+04 eV
.Che_shev Fittlnq Parameters fpr___,t.e CoefficigJ3t._s
H
Energy
(eV/ainu ) AO Al A2 A3 A4 A5 A6
I0000. -3 52453E+01 -2,72966E-.02 -1,25046E-02 -5.94386E-03 -3 93360E-03 -2,52788E-03 -] 15226E-03
20000. -3 49559E+0] -1,07234E-01 -5,74126E-02 -2.46077E-02 -9 61541E-03 -3.68199E-03 -i 33552E-03
40000. -3 56977E+01 ,.8.13307E-02 -4,02505E-02 -1.59626E-02 --6 46672E-03 3.09676E-03 -] 64827E-03
70000. -3 74954E+01 ].58892E-02 ],66995E-02 1.04165E-02 3 58841E--03 -I,]4383E-04 -i 18569E-03
i00000. -3 91164E401 4.26359E-02 3.67186E-,02 2,35687E-02 I I0156E-02 3.70448E.,03 6 54932E-04
200000. -4 33336E+01 5,99177E-02 4.72882E-02 2.99739E-02 ] 60765E-02 6.77381E-03 2 80729E-03
500000. -,4 99733E+01 4.33562E-02 3.10236E-02 ],83053E-02 8 97845E-03 3,66858E-03 1 27965E-03
See appendix for Chebyshev fit details.
1.1-95
H + He_+ ->, He+(2s) -t.. H+
i
BecJrT/-- McJy,welllcJn
""'-IU_ :..:- r:-T i i"nTq--"-T_-'1-Fr'rmi- , I"I-FIITIF---]--I" i:iiii|i i:T"I'-FT'E
- - H Energy
- - (eV/am u)
"::' A --I0000
, "_ x - 20000,
•10-8 __z, ----------_ V -- 40000,
(J')
....., . - *, -" 70000,
_ • --I00000
C
m-_9I []- 200000.'8 Iv, -
,4-(t) _ " _- ma-- 500000.o L_ ...-m -
U E=Recommended(b
o DataPa::
10-`°: ....... Chebyshev Fit
1_-_.. __,_, .J..,__ , ,,, ,,,,__ , , ,_..U.u.L____LLU_U.a___LLU__1(.)0 10' ld 10a 1(04 lOs
the_+ Ten-lp. (.eV)
B-96
AElootron CaptuL'e Cross _Jeotlon_ for
tie 24 + Ii -> ite+(2p) + 11+
El_ergy Velocity Cross Seation
(eV/amu) (am/s) (o,,2)
3, OB+02 2 41F,FO7 2,55_-17
4,01,3+02 '2 7[JE+07 4,12E-i7
5.0_+02 3 lIE+07 5.94E-17
7,0E+02 3 68E+07 1,04E-16
9.0E+02 4 17E+07 1.61E-16
1,0E+03 4 39E+07 1,91E-16
1,5E+03 5 38E+07 3 44E-16
2,0E+03 6 21E.F07 4 71E-16
2_.5E+03 6 95E+07 5 68P,-16
3,0E+03 7 61E+07 6 57E-16
4,0E+03 8 79E+07 7 80E-16
5,0E+03 9 82E+C7 8 63E-16
7 0F.+03 1,16E+08 9 31E-16
9 0E+03 1,32E+08 9 39E-16
1 5E+04 1,70E+08 8.73E-16
20E+04 1,96E+08 7.12E-16
2 5E+04 2,20E+08 5,35E-16
30E+04 2,41E+08 3.89E-16
4 0E404 2.78E+0B 2.13E-16
5.0E+04 3. IIE+08 i. 19E-16 _&
6 0E+04 3.40E+08 7,18E-17
0 0E+04 3.93E+08 3,12E-17
i 0E+05 4,39E+08 1.36E-17
I 5E+05 5,38E+08 3 32E-18
2 0E+05 6,21E+08 1 24E-18
2 5E+05 6,94E+011 6 06E-19
3 0E+05 7,6]E+08 3 _8E-19
4 0E405 8.78E+08 I 8iE-.19
5 7E+05 1.05E+09 1 01E-19
ReferenGes_ 169, 170, 172, 173, 174, 175, ]76
Aoouraoyl 1 < F < IX104 eV/amu - 20%
(i) Referenoes 172 and 173 (C1riÙ st al.) are the only experimental results. Other data
are theoretioal data which in the energy region of overlap agree well with experiment,
For a Chebysh_v fit of the above cross sections lt is neoessary to use the following parameters.
Eml n = 3,0[,]._02 eV/ainu, Ema x = 5.7E+05 eV/ainu
_shev Fittinq Pa r@n_eter s for Cros____gqtions
AO Al A2 A3 A4 A5 A6 A7 A8
•-76.4723 -2.gE_91B -3,20835 .0657861 .450590 .217258 ,0371010 -.0738139 -,0123768
The I it: represel_ts the above cross ecel:torts with an rms deviation o1_ 2.8%. d_&
The maximum deviation is 5.3% aL 9.0[,:.I03eV/ainu,
See append.rx for ChebyF.|ev fit details.
B-97
He=+ + H ->He +(2p) + k-I4'
Cross Sectionvs. Energy
"I0-m, .........., , i,-,irl'l . , , _,._-r-,_' -- ,-w,rr_,
t.
lC)-1__
/_,-%
Q _Ec-O
,._ 10-1__(1.) -
CO -09 "Or)
_0 _ RecommendedU _ Data
10-18__ Chebyshev Fit-- ,'
10 -19 J 1 I illlll I I 1 illlll I I J llJlJl I 111
lO_ ,lo_ lO_ lO_ lO_Energy (eV/am@
Q
i
13-98
i
Elea'eron Capture Rate Coefficients for '
He 2+ 4. H -> HB.(2p) + }I+
i
Maxwellian - Maxwellian Rate Coefficients (cm3/s)
He2"k
Temp. EqL1al H Temp. (eV)
(eV) Temp. i000 500. i000. 5000. i0000. 15000. 20000.
I.OE+02 2.98E-10 2.98E-I0 7.39_-09 2.06E-08 8.70E-08 1 03E-07 9.73E-08 8.77E-08
2.0E+02 1.72E-09 4.98E-I0 8.00E-09 2_12E-08 8.72E-08 i 03E-07 9.72E-08 8.77E-408
4.0E+02 6.78E-09 1.03E-09 9.26E-09 2.26E-08 8.76E-08 1 03E-07 9.71E-0B B.7OE-08
7.0E+02 1.65E-O8 2.11E-09 1.12E-08 2.46E-.08 8.82E-08 1 03E-07 9.70E-08 8.74E-08
1.0E+03 2.65E-08 3.48E-09 1.32E-08 2.65E-0B 8.87E-08 1 03E.-07 9.69E-08 8.73E-08
2.0E+03 5.46E-08 9.26E-09 1.99E-08 3.29E-08 9.06E-08 1 03E-07 9.64E-08 8.68E-08
4.0E+03 8.68E-08 2.26E-08 3.29E-08 4.45E-08 9.36E-OB 1 02E-07 9.55E-08 8.58E-08
7.0E+03 1.02E-07 4.12E-08 4.98E-08 5.92E-08 9.71E-08 1 02E-07 9.41E-08 8.44E-08
1.0E+04 1.01E-07 5.65E-08 6.33E-08 7.08E-08 9 96E-08 1 01E-07 9.27E-08 _ 8.30E-08
2.0E+04 7.83E-08 8.76E-08 9.06E-08 9.36E-08 1.03E-07 9 73E-08 8.78E-08 _ 7.83E-08
Notesz For Chebyshev fits of the above rate coefficients it is necessary to use the following parameters.
Eml n = 1.0E+02 eV, Emc x = 2.0E+04 eV
Chebyshev Fittinq P__rameters for Rate Coefficients A
H
Temp.
(eV) A0 AI A2 A3 A4 A5 A6
i00. -3.80891E+01 3.04269E+00 -5.03692E-02 -2.14921E-01 '7 02489E-03 ].33936E-02 -3.51323E-03
500. -3.53407E+01 1.33422E+00 2.37587E-01 -8.16883E-02 -4 I1875E-02 4.97820E-04 3.60655E-03
1000. -3.42278E+01 7.87638E-01 2.02270E-01 -2.32859E-02 -3 10588E-02 -7.16158E-03 1.05223E-03
5000. -3.23931E+01 8.58442E-02 2.79249E-02 -7.64042E-04 -5 28180E-03 -2.73625E-03 -8.72863E-04
10000. -3.22047E+01 -1.79017E-02 -1.27932E-02 -7.35687E-03 -3 35962E-03 -1.20009E-03 -3.44007E-04
15000. -3.23427E+01 -4.11290E-02 -2.23406E-.02 -9.19084E-03 -3 13037E-03 -9.49262E-04 -2.08801E-04
20000. -3.25558E+01 -4.63175E-02 -2.45398E--02 -9.65926E-03 -2 98432E-03 -7.43123E-04 -1.57791E-04
Equal Temp. -3.61487E+01 2.77246E+00 -I.05020E+00 7.78393E-03 -2.49781E-02 4.65115E-03 2.17778E-03
See appendix for Chebyshev fit details.
B-99
O
He2. + H-> He*(2p) + I-t*
MQxwelli@n MQxwellion
10-4 ' I '1 I I I III I I / I I I II11 I I I I I IlL.
- H Temp.
- (eV)
,_ -- 100.
x -- 500.10-.7
_- v -- 1000_
--- _ -- 5000.
_ • -- 10000.
¢-
._ 10-8 15000.
¢) , l [] 20000.0
LD /q.) Recommendedo , .Data
¢Y / "
10-9_ Chebyshev Fit
z _-- Equal Temp.
I10-' , I i I III£l I I I I I IIII I 1 1 I II11,
10_ 103 104 10sHe_+ Temp. (eV)
B-lO0
Electron Capture Rate Coefficients for
H + He 2+ -> He+(2p) + H +
Beam - Maxwellian Rate CoefficientB (cm3/s)
He2+
Temp. _ H Energy (eV/amu)
(eV) i0000. 20000. 40000. 70000. i00000. 200000. 500000.
1.0E+O0 i.28E-07 1.40E-07 5.91E-08 1.69E-08 5.97E-09 7.71E-I0"* 1.23E-I0"*
2.0E+00 1.28F-07 1.40E-07 5.91E-08 1.69E-08 5.98E-09 7.70E-I0 e* 1.23E-I0"*
4.0E+00 1.28E-07 1.40E-07 5.91E-08 1.69E-08 5.98E-09 7.70E-I0"* 1.23E-I0"*
7.0E+00 1.28E-07 1.39E-07 5.91E-08 1.69E-08 5.98E-09 7.71E-10,* I_23E-I0'*
1.0E+01 1.29E-07 1.39E-07 5.90E-08 .69E-08 5.98E'09 7.71E-I0"* 1.23E-I0"*
2.0E+01 1.29E-07 1.39E-07 5.90E-08 1.69E-08 5.98E-09 7.71E-I0"* 1.23E-I0'*
4.0E+01 1,29E'07 1.39E-07 5.89E-08 1.69E-08 5.99E-09 7.71E-I0 _* 1.23E'I0"*
7.0E+01 1.29E-07 1.39E-07 5.89E-08 1.69E-.08 5.99E-09 7.72E-I0" 1.23E-I0"*
1.0E+02 1.29E-07 1.38E-07 5.88E-08 1.69E-08 6.00E-09 7.72E-I0" 1.23E-I0'*
2.0E+02 1.29E-07 1.38E-07 5.88E-08 1.69E-08 6.02E-09 7.73E-I0" 1.23E-I0 *_
4.0E+02 1.28E-07 1.37E-07 5.87E-08 1.70E-08 6.05E-09 7.75E-I0" 1.23E-I0"*
7.0E+02 1.28E-07 1.36E-07 5.87E-08 1.7iE-08 6.09E-09 7.77E-I0' 1.23E-I0'*
1.0E+03 1.28E-07 1.34E-07 5.87E-08 1.71E-08 6.14E-09 7.80E-I0" 1.23E-I0"*
2.0E+03 1.28E-07 1.31E-07 5.89E-08 1.74E-08 6.28E-09 7.88E-I0" 1.23E-I0"*
4.0E+03 1.26E-07 1,25E-07 5.93E-08 1.78E-08 6.53E-09 8.03E-I0" 1.21E-10**
7.0E+03 1.22E-07 1.18E-07 5.95E-08 1.85E-08 6.88E-09 8.27E-I0" 1.18E-10**
1.0E+04 1.19E-07 1.13E-07 5.93E-08 1.92E-08 7.22E-09 8.52E-I0" 1.14E-10**
2.0E+04 ].IOE-07 9.85E-08 5.73E-08 2.12E-08 8.38E-09 9.47E-I0' 1.06E-I0'*
Accuracy: * - Possible Error Greater Than 10%
•* - Possible Error Greater Than 100%
Notes: For Chebyshev fits of the above rate coefficients it is necessary to use the following parameters.
Eml n = 1.0E+00 eV, Ema x = 2.0E+04 eV
C hebyshev Fittinq Parameters for Rate Coeffici@n_
H
Energy
(eV/amu) AO AI A2 A3 A4 A5 A6
i0000. -3.17882E+01 -4.92276E-02 -3.82539E-02 -2.43393E-02 -1.22728F-02 -4.54785E-03 -7.79239E-04
20000.-3.17232E+01 -1.30716E-01 -8.13104E-02 -4.04778E-02 -1.57809E-02 -3.98767E-03 3.36890E'05
40000. -3.32955E+01 -5.40047E-03 -1.99166E-03 -4.45358E'03 -6.27891E-03 -5.14199E-03 -2.92410E-03
70000. -3.57028E+01 8.02848E-02 5.54250E-02 3.03851E-02 1.33090E-02 4.49405E-03 7.72971E-04
i00000. --3.77338E+01 1.19799E-01 7.98553E-02 4.24318E-02 1.81018E-02 6.30836E-.03 2.00635E-03
200000. -4.18916E+01 6.78830E-02 4.78977E-02 2.81571E-02 1.45668E-02 6.26534E-03 2.69138E-03
500000. -4.56871E+01 -4.63255E-02 -3.72726E-02 -2.45372E-02 -1.26363E-02 -4.18959E-03 7.18096E-04
See appendix for Chebyshev fit details.
Q
B-lO1
H _+ He2* ->He*(2p) + H*
BeGin -M@xwelli@n
lO-e i ., ,, Illll I i I I li'Iii I I II IJIJII I II Illll I, I li II_u- H Energy
- (eV/am u)
a z 10000.
10_;,i _ × - 20000,- - v -- 40000.L
/-_ -_
m - - )_ -- 70000.-0 °---i - _ • -- I00000.
c-
O m 200000,0 10-8 -,I
,+.- .I...8 -o _ - [] --500000.0
U
o Recommended_t_,a
o --Data_/ --
10-9 _,_ _ - Chebyshev Fit
n
10 , J t,ltiJl ! J l lJJJll l i ,,_J_ll J J J llllt'TTTt"'---,mI j JlJJl
100 ld 102 103 104 105He2. Temp. (eV)
B-102 ,,
iLine Emission Cross Sections of Electron Capture Collisions for
He 2+ + H -> }le+(Lys,Lyg,Lyy,H_) + II+
(Ly a) (Lye) (LyT) , (Ha)
Energy Cross Section Energy Cross Seotion Energy Cross Section Energy Cross Section
eV/amu cm 2 eV/amu cm 2 eV/anu cn 2 eV/anu cn 2
1.2E+03 2.68E-16 1.6E+03 6.37E-18 4.8E+03 2.39E-18 2.8E%03 ].99E-171.5E+03 3.21E-16 2.2E+03 1.30S-17 5.0E+03 2.45E-18 2.9E+03 2.03E-172.2E+03 4.90E--16 2.9E+03 1.93E-17 5.7E+03 2.75E-18 3.6E+03 2.36E-172.9E+03 6.35E-16 3 6E+03 2.18E-17 6.4E+03 3.08E_18 4.3E+03 2.73E-173.6E+03 7.49E-16 4 3E+03 2.32E-17 7.2E+03 3.48E-18 5.0E+03 3.17E-174.3E+03 8.30E-16 5 0E+03 2.39E-17 7.9E+03 3.96E-18 5.7E+03 3.70E-175.0E+03 8.82E-16 5 7E+03 2.47E-17 8.6E+03 4.47E-18 6.5E+03 4.22E-175_7E+03 9.11E-16 6 5E+03 2.54E-17 9.1E+03 4.89E-18 7.2E+03 4.70E-i7
6.5E+03 9.31E-16 7 2E+03 2.64E-17 9.3E+03 5.08E-18 7.9E+03 5.03E-177.2E+03 9.50E-16 7 9E+03 2,75E-17 1,0E+04 5.84E-18 8.6E+03 5.24E-177.9E+03 9.59E-16 8 6E+03 2.87E-17 9.3E+03 5,35E-178.6E+03 9.73S-16 9 3E+03 3.04E-17 I.OE+04 5.40E-17
9.3E+03 9.87E-16 1.0E+04 3.24_-171.0E+04 9.91E-16
References: 173
Accuracy: 30%
Notes: (i) Transition wavelengths are: Lyman-a - (2p->is) 30.4 nn; Lyman-J_- (3p->is) 25.6 nm;
Lyman-¥ - (4p->is) 24.3 nra; Balmer-a- (n=3->2) 164 nra.
(2) The Baimer-_ emission cannot be measured since the transition has the same wave
length as the Lynan-a radiation.
,t0For Chebyshev fits of the above cross sections it is necessary to use the following parameters.
(Ly a) Eml n = 1.2E+03 eV/amu, Ems x = 1.0E+04 eV/amu
(Lyp) Emi n = 1.6E+03 eV/anu, Ema x = 1.0E+04 eV/amu
(Ly7) Emi n = 4.8E+03 eV/amu, Ema x = 1.0E+04 eV/amu
(}la) Eml n = 2.8E+03 eV/ainu, Ema x = 1.0E+04 eV/amu
Chebvshev Fittin q Parameters for Cross Sections
AO A1 A2 A3 A4 ;%,5 A6 A7 A8
(LY a) -70.0765 .658545 -.176878 -.00575199 .0163374 .00346973 -.00221833 -.00217295 -4.61984E-04
(Lye) -77.0977 .692364 -.245444 .142376 -.00794442 -.0119412 .0163687 -.00929968 .00446139
(Ly7) -80,3639 .441485 .0512890 .00405517 9.45294E-04 .00161819 .00182462 -4.78184E-04 -6.34056E-04
(Ha) -75.8681 .546644 -.0142448 -.0516937 -.0137147 .00553121 .00525928 -.00130955 9.09970E-05
The fit represents the (Lya) cross section with an rms deviation of 0.1%.
The maximum deviation is 0.2% at 7.9E+03 eV/amu.
The fit represents the (Lye) cross section with an rms deviation of 0.2%.
The maximum deviation is 0.3% at 8.6E+03 eV/anu.
The fit represents the (Ly7)cross section with an rms deviation of 0.1%.
The maximum deviation is 0.2% at 8.6E+03 eV/anu.
The fit represents the (lla) cross section with an rms deviation of 0.1%.
The maximum deviation is 0.2% at 6.4E+03 eV/amu.
See appendix for Chebyshev fit details.
B--I03
Q
qe_+ + H -> He+(Ly_,Lye, Lye, PI) + H+
Cross Section vs. Energy
10-,15__ I l I .... '1 ....
- _ -
A (Lye)
x-(H)
- (Lye)10-16
- - x - (Lye,)_i -b'l E _
(-
,o(J Tq.)
Or)CO
U 10-17_
_ Recommended
I_ Data
i
18 ...... Chebyshev Fit10- _ _ , _ _ _ , ,_o_ lO,
Energy (eV/am u)
I
B-104
Electron CaptUre Cross Sections for
fie 2+ + II -> He+[3p,3s+3d,4p) + li +
. (3p) (3s+3d) (4p)
Energy Cross Section Energy Cross Seotlon Energy Cross Section
eV/amu cm 2 eV/amU cm2 eV/amLl cm 2
1.6E+03 7.71E-18 2.5E+03 1.78E-17 5.0E+03 2.49E-IS
2.0E+03 1.46E-17 3.0E+03 1.87E-17 5.5_+03 2.73E-18
2,5E+03 2.09E-17 3.5E+03 2.01E-17 6.0E+03 2,99E-18
3.0E+03 2.40E-17 4,0E+03 2.23E-17 7.0E+03 3.56E-18
3.5E+03 2.63E-17 4.5E+03 2.51E-17 8,0E+03 4.22E-18
4.0E+03 2.83E-17 5.0E+03 2.81E-17 9.0E+03 4.96E-18
4.5E+03 2.97E-17 6.0E+03 3.49E-17 1.0E+04 6.03E-18
5,5E+03 3 20E-17 7.0E+03 4.15E-17
6.0E+03 3 29E-17 8.0E_03 4.63E_17
7.0E+03 3 43E-17 9.0E+03 4.89E-17
8.0E+03 3 57B-17 1,0E+04 4.97E-17
9.0E+03 3 67E-17
1.0E+04 3 74E-17
References: 172, 173
Accuracyx 30%
Notes: (1) The 3s and 3d states could not be determined separately due to the degeneracy of
states In lie + . I_
(2) Capture into the ground state is negligible at low energies for a H target.
(3) The cross section (ai) for capture into state i is determined by measuring the
emission cross section (oij) for a transition from state i to j, correcting for any
branching from state _ and correcting for cascading from upper states.
For Chebyshev fits of the above cross sections it is necessary to use the following parameters,
(3p) Eml n = 1.6E+03 eV/amu, Ems x = 1.0E+04 eV/amu
(3s+3d) Eml n = 2.5E+03 eV/amu, Ema x = 1.0E+04 eV/amu
(4p) Em% n = 5.0E+03 eV/amu, Ems x = 1,0E+04 eV/amu
Cheb_shev Fitting Parameters for Cross Sections
AO AI A2 A3 A4 A5 A6 A7 A8
(3p) -76.6256 .667773 -.257128 .115045 -.0496129 .0142615 9.03999E-04 -.00746439 .00421196
(3s+3d) -76.1346 .575824 .0291040 -.0715718 -.0133196 .00539953 -.00104695 .00377347 -.00137059
(4p) -80.2658 ,432003 ,0343796 .00725815 .00469173 .00296970 .00183023
The fit represents the (3P) cross section with an rms deviation of 0.]%.
The maximum deviation is 0.3% at 4.5E+03 eV/amu,
The fit represents the (3s+3d) cross section with an rms deviation of 0.]%.
The maximum deviation is 0.1% at 4,0E+03 eV/amu,
The fit represents the (4p) cross section with an rms deviation of 0.0%.
The maxlmum deviation is 0.0%
See appendix for Chebyshev fit details.
Q
B-lO5
He_+ + H-> He+(3p,3s+3d,4.p) + H+
Cross Sectionvs. Energy
10-16 , J , r----r---1.......,''-i
z_, (3s+ 3d)
x - (3p)i
' '_' - (4p)
10 '_LP(b
Of)V)O3
o /(._) ///
// -
__ -Recommended
- ----Data
Chebyshev Fit10-1 , I , , , I. I .u_._
103 104Energy(eV/arnu)
e
li_- 10 6
iEleotron Capture Cross Seatlorls for
lle2+ + 112 -> lle+(2st2p)
lie + (2p) Ile + ( 2s )
Energy C1_o_ s Section Ene/:gy Cross Se¢ltion
eV/ainu cm 2 eV/ainu cm 2
1.2E+03 4,90E-17 2.0E+03 7,99E-18
1,5E+03 5,94E-17 3.0E+03 1.97E-17
2.0E403 8.22E-17 4.0[.':+03 3.33E-17
3,0E403 1.35E-16 5.0E+03 4.56E-17
4,0E+03 2.15E-16 5o5E+03 5,12E-17
5.0E403 3,16E-'16 6.0E+03 5.76E-17
7.0E403 4,79E-16 7.3E+03 7.46E-17
9.0E+03 6.18E-16 7.5E+03 8,86E-17
1.0E+04 7.08E-16 8,0E+03 9.88E-17
9.0E+03 I,]7E-16
].0E+04 ]. 28E-16
1.5E+04 i. 37E-16
Referenoess He+(2s) -56, 145, 177; He+(2p) -172, 173
Accuraoy_ He+(2s) - 60%; He+(2p) - 30% i
For Chebyshev fits of the above cross sections it is necessary to use the following parameters.
He+(2P) Eml n = 1.2E+03 eV/ainu, Ema x = 1.0E+04 eV/ainu
He+(2s) Eml n = 2,0E+03 eV/ainu, Ema x = 2,0E+04 eV/ainu
Chebyshev Fitting Parameters for Cross Seetlons
AO AI A2 A3 A4 A5 A6 A7 A8
He+(2p) -72.5057 1.39004 .0296375 -.0736032 -.0100517 ,0209333 .0217835 -.00206200 -.00793171
He+ (2s) -75.1849 1.42417 -. 425662 -.0917408 -.0265286 .0447348 .0526597
The fit represents the He+(2p) cross section with an rms deviation of 0.0%.
The maximum deviation is 0.0%
The fit represents the He+(2s) cross section with an rms deviation of 2.4%,
The maximum deviation is 4.6% at ].3E+04 eV/ainu.
See appendix for Chebyshev fit details.
B-lO7
He'_+ + t-t2 ->He +(2s,2p)
hlllo Emlilr_le,HCros_J S(mt.lonn o[' F:.loctt'o_LCspttlru Coll11_Lotlu (at
lie 2'_ -t. II2 -,', Ilo . (l,yull,Yll t l,Yy ,llu)
hy u II u l,_'ll hyy
EnOl_{ CL'OBB [;ou_lon _llOl(J_{ Crt.I[IH80£i_[on _]l)_l(]_{CL'O0[-I[Ill,trOll l!ll'%Ol'-Jy[_lOfdl',8E_ULI'on
_://alnU Cm2 oVlamu cm 2 _V/,'|Ino o;i_2 c,V/aniu OI,2
I,3E+0,1 4,82_'17 2,5E403 6,44E-18 1,7E+03 1,77E-18 5,0E+03 4,931,;-19
] 5_03 5,62_:-I'I 2,912+03 7,44Z-18 2,_,_1+03 2,52H-18 5,"/I:H03 7,561_-19
2 2E+03 9,218..17 3,6}:+03 9,638-18 2,9E403 3, "/SE-I[I 6,5E+03 1,151.1-111
2 9E.03 1,371,-16 443 F,.03 I_18_-17 3,61:-I(]3 5,188-18 "/,2H-I03 I,"I'IF,.-III
3 6E+03 1,90E-16 5,0f:+03 ,l,44E-17 4,3E403 6,94_:-.I0 7,9E403 2,32E-18
4 3f_+03 2,511E-16 5,7Z*03 1,7514-17 5,[IE_03 8,79_:_18 8,6E403 2,6[IB-18
5 0E+03 3,25E-16 6,4E.03 2,188-17 5,7E+03 1.06B-17 9,3E_03 2,94E-Ili
5 7E.03 3,9,1E-16 7,2E+03 2,40i:-19 r,.41,403 I,24E-17 ],0f:.I04 3,151:-18
6 5E+03 4,59_-16 7,9E_+03 2,89E-.17 ,,2_+03 J,42E-17
7 2E.03 5,24}]-16 8,6E403 3,238-17 '1,9E._03 I,51E-I'I
7 9E+03 5,08_:-16 943E+03 3,49E-17 B,6E+03 ,|,55_I-I'/
8 6E.03 6,561_-16 1,0_+04 3,65E-17 9,3_;+03 1,56P-17
9',3E.03 7,361;-16 1,0E+04 I,52}:"17
1,0E+04 8,06E-16
R_ELu_grLyjZcELt173
Acc_ 30_
_gtor_t (I) Transition wavolencjtlm are! Lyman-. (2p->Is) 30,4 lint/ I,yman-[_ (3p->Is) 25,6 .nrel
hyman-y (4p-;,l_) 24,3 nrel Balmer-a (lla,n-3->2) 164 nra, A
(2) The Balmer-, zadl_tion cannot be meaSuled since the tlaaaltloll hat_ thu s_mu wave
length as the Lyman-a radiation,
For Chebyshov fits of the above cross sectlonu lt is naoessary to uuo Lhc following |*al'al_1otolB,
{L,yu) Eil|l H - 1,3E+03 eV/aITiLl_ Erllax ., 1,0E+04 eV/ainu
(lla) Bmi h - 2,5l.H03 eV/alllU, l':max - 1,08+04 eVlamu
(hy_) Elm[n ,, 1,7_+03 sV/ainu, Elnax _ 1.0_,+04 eV/ainu
(Lyy) '_mJn : 5,01.,'+03eV/ainu, Emax _ 1.0E.04 eV/ainu
¢|!obvsI_9_Y FIttln(.lParameters for Cro[Ir_Bootless
AO AI A2 A3 A4 A5 A6 A7 A0
(LYu) -72_3892 1,45574 ,0140540 -.0435817 ,00'1095[7 ,00345598 .0136342 -.00690786 .-,00272240
(Ha) -77,4506 ,904442 ,0279735 -,0253175 -.0268277 ,-,00920010 ,00430881 -.00254202 ,00325_144
(by_) -79,3508 1,17675 -,116050 -,0780599 -,0348000 -,0102977 ,0150173 -,0).23859 .0116818
(hyy) -82.1736 .953689 -,126724 -40689492 ,0127445 ,0372528 -,0256612 .00533416
The rtr _eplesonts the Ly. crosu section with ali [,,Bdeviation of 0,3%,
The maximum d_vlatlon is 0,6% at 3,6E+03 eV/ainu,
The flt ['eprosonts the II_ cross section wlth ali [llll]C]OVJ(_LIoHOf 0,ill.
Tl,e maximull_O_vlatJon iu 0.2% at 7',IE+U3 o_/alnu,
q'he fit represents the Ly_ ClOSH soc,tlon wlth an z'nm devlatlon of 0,4_,
q'he maxlm%|m devlatlulz Is 0,7% at [1.6E+03 eV/ainu,
The fit represents t.l,o I,yy trolls _IoctlOllwith an [i,[I dovl_tit,n or 0,0%.
The maxlmuln dovlatJon IH 0,0%, i [
See appendlx for Chebyshev flt (Jeta|]l_, _ "-
B.-:[09
t--le2' + t-I:_--> I-le+(Ly,, L.y_,L..y_,t-I)
Cross SeeLionvs. Ener-gy
10-,5 ,, r------r 1.... m--r---r'_
"'J 1//"__" _ -(Ly°_
/" ' " x-'"'crl:
I0-'6- 11I/'_' ' _ v- (Ly,)
c"©
10-'7or_O0
oo
('-) / /"
.10-1 _ / -
- 4y"- Rec o nnrnend er.I, - -----Data
Chebyshev Fit10-Ig , , , _..... ,. :., , L
.lo_ lo4Energy (eV/a m u)
I:1-,l.1,0
l!l.Lootl:olt Capl_LIr(1 C.l'o£1/j _tool_JOrlr_ Curl
11o2+ .I I1_ ,-> II0 '1"(31,,,311.1-3cls4I,)
(3p) , (3s-t..ld) (4pil'_not'gy Ct'o_ _ootioll _norgy Crotl_ _ar)tlon l_nergy Cro.n ,UouLlon
eV/alnCl Um2 eV/nmur cm 2 eV/_mu o,t 2
2,5 _.,FO3 6,'/0_-10 , I, 9B.+03 1,96t,_-IB 5,01']l{)3 5,7[IB-19
3,0E+03 7,05_I-10 2,3i.;+03 2,64f_-1[I 5,0_H03 !),10I,i-19
3,5F,+03 9,24L-10 3,0B+03 4,5!)P:-iO 6,5_.I,03 1,39[,_-III
4,3E:+03 i,17_-17 3,5_'t03 6,101';'30 7,3l_.i03 2,10_-'10
5,0E+03 1,451'.'-i? 4,3E+03 7,72E-IU 8,01';+03 2,IlRE-I[I
5,,_+03 1,75_-17 5,01_+O3 9,5[I_-18 8,51!:.I03 3,301.'}-Ili
6 5E+03 2,05E-17 5,8E+03 I_17E-17 9,3_]-_03 3,G4E-I8
"/ 31':+03 2,35['I-17 6,5P,+03 1,30E-17 I,OE+04 3,OdE:-IEI
8 0E+03 2,65p2-i'/ 7,3_+03 1,56_-17
8 5I_D 3 2,96_]-17 0,01'I+03 I,68_:-,17
9 3_+03 3,25F,-17 II,5E+03 i,75F,-17
I 0E:+04 3,54P,-17 9,31.'I+03 1,7B_-17
I_0E+04 1,71E-17
ReferenoeBi 173
Aoeuraay! 30%
t_.q.__E.! (1) '/'he 3B and 3_3 _t:ates oould not be determined separately duo to the degeneracy eL'
states /n lie + , ' /
(2) The o,'oaa Beu_t:ton Eor oapturo into _tat'e I iu cleterm/ned by mea_)urincj the el, in[tlOll
cross section (.lj) (Tor a tranoition _om state l Lo J, oorreotlnu for any b,'anchil_cjfroII]state i and correct/ns /or oasoadlllg from tippet'_tatou.
For Chobyshov fits of tile above cross sections lt Is necessary Lo use the /oJlowJng pat'alllotors,
(3p) Era,la- 2,5_:+03 eV/a_u, Ems x - 1,0B+04 eV/ailtll
(3a+3d) _mln = 1,9I,:+03 eV/ainu, Ems x = 1,0_+04 eV/ainu
(4pi Emil] = 5,01,',.103eV/ainu, F,inax = 1,0E:+04 eV/amt|
Chebyshov _'lttlllg Parameters) for Cross SectJolls
AO AI A2 A3 A4 A5 A6 A7 ht_
(3pi -77.5134 ,877384 ,0236181 -,0330936 ,0119138-,00648625 ,00667714 -,00553227 .00234918
(3s+3d) -7B,9402 1.10256 -,166612 -.0123653 -,0567272 -,00713119 ,00939'103 4,306.17B-04 -,00609836
(4p) -Bi,8167 ,998271 -,145940 -,O60USB2 ,011_762 ,01'_4494 -,004"/4599 -.00803524
The fit rapiosents tile 3p cross seatlon Wlth an rms devlaLloll oi 0,1%.
Tlm maximum deviation i_a 0,1% at 7,9_+03 eV/ainu,
The fit represents the 3_+3cI cross sectioll with an rms deviation of 0,2%,
The maximum dovlatlon iu 0.4% at 0,6[,',+03eV/ainu.
The fit represents the 4p or'oo_ laeotlon w,Lth an rmB duvlation of 0,0%,
Tile ,laXllfiUllldeviatlon J,u 0,0%,
See appendix for Chebyshev fit detail.s,
t-le2+ + t--I_-> t--te+(3p,3s+3d, 4-p)
' c, EIlergCross Se.Cti_-_nv_. y
10-1_ , , , i ,' , ...., r-I
- fj_
- 3t)
:_"- 3s .-I-3d
/./.j//.j11--, v - 4-pICY17 ///_ //"tl _
_--, ,. _- / _t_ E - --- // /_ -
,2: - J :- ,,,/"" i-
® /L_ _ .x(/
U 10-1__
Recornmendedz
.... DGto
Chebyshev Fit
10-1_-- , L , , l , , , .lo_ lo_
Energy (eV/o rnu)
0
U-l:L2
Electron Capture Cross Sections for
He 2+ + lie -> He'l(2s) 4 He i
Energy Velocity Cross Saction
(eV/ainu ) (cm/s ) (cre2 )
2.0E+03 6,21E+07 2.79E-18
3,0E+03 7.61E+07 3.30E-18
4.0E+03 8.79E+07 4.04E-18
5.0E+03 9.82E+07 5.32E-18
7.0E+03 1.16E+08 9.18E-18
9.0E+03 1.32E+08 1.37E-17
1,0E+04 1.39E4.08 1.62E-17
1.5E+04 1.70E+08 3.04E-17
2 0E+04 1.96E+08 3.75E'17
2 5E+04 2.20E+08 3,90E-17
3 0Es04 2.41E+08 3.84E-17
4 0E+04 2.78E+08 3.36E'-17
6 0E+04 3.40E+08 2.21E-17
8 0E+04 3.93E+08 1.40E-17
1 0E+05 4.39E+08 8.65E-18
1,5E+05 5.38E+08 2.83E-18
2.0E+05 6.21E+08 1.26E-18
2.5E+05 6.94E+08 6.87E-19
3.0E+05 7.61E+08 4.10E-19
4.0E+05 8.78E+0B 1.75E-19
4.7E+05 9.52E+08 1.27E-19
Referencesz 56, 145, 177, 178, 179, 180, 181, 182
Accurac_ E < 2x104 eV/amu - 50%7 _; _ 2x104 eV/amu - unknown
Notesl (i) Experimental data (ref. 56, 145, 177) extends only to 2x104 sV/amu. Irl the energy
region of overlap (7x103 eV/amu-2x]04 eV_amu) between experimental data and theoretical
data (ref. 178, 180, 181) the theoretical data is greater than experimental by 1.5-2_5
orders of magnitude. Data above 2x104 eV/amu should be used with caution.
(2) No experimental data exists for He 2+ + }le -> He+(2p).
For a Chebyshev fit of the above cross sections it is necessary to use the following parameters.
Eml n = 2.0E+03 eV/amu, Emc x = 4.7E+05 eV/amU
Chebyshev Fittinq Parameters for Cross Sections
A0 AI A2 A3 A4 A5 A6 A7 A8
-80.4752 -1.31324 -2.07504 -.28]865 .383911 5.87536E-03 -'.0220039 .0340012 -.0262370
The fit represents the above cross sections with an rms deviation of 2.7%.
The maximum deviation is 5.6% at 4.0E+05 eV/amu.
See appendix for Chebyshev fit details.
B-II3
0
He_+ + Pie--> He+(2s) + He+
Cross Section vs. Energy
-16 1 i ' i i i i i 1I i i i i i i 1i I i i i i 1,1'11,
10-1' _• -
'('4 E _ --
0 -
c- _
60 _O9(n0 RecommendedL_u 'S_t_1(3-1_ _/%,J
-
f'_k / L Fit_ , t, neDysnev
1(_-1¢" _.L__I I I I I III ' 1 1 1 11 I I1! J I I 11 I 11
lo_ lo_ 18 to_Energy (eV/o m u)
Q
B-114
Electron Capture Rate Coefficient_ for O
He 24 4, Ite-> He+(2s) + }le +,,
Maxwellian- Maxwellian Rate Coefficients (cm3/s)
He 2+
Temp. Equal He Temp. (eV)
(eV) Temp. 500. i000. 2000. 4000. 7000. i0000, 20000,
7.0E+02 1.96E-12 7.88E-13 5.12E-12 2,78E-II 1.lIE-10 3.08E-I0 5.88E-10 1.84E-09
1.0E+03 1.01E-II 2.81E-12 1.01E-II 3 76E-] i 1.27E-I0 3.32E-10 6.20E-10 1.88E-09
2.0E+03 7.73E-II 2.20E-II 3_76E-II 7 73E-II 1.86E-I0 4.20E-10 7.31E-10 2.02E-09
4.0E+03 3.32E-I0 1.01E-10 i. 27E-I0 i 86E-I0 3.32E-I0 6.20E-I0 9.70E-lO 2.28E-09
7.0E+03 9_70E-I0 2.92E-I0 3.32E-I0 4 20E-10 6.20E-10 9.70E-10 i. 35E-09 2.65E-09
i. 0E+04 i. 75E-09 5.67E-I0 6.20E-10 7 31E-10 9.70E-10 ].35E-09 i. 75E-09 3.01E-09
2.0E+04 4.01E-09 i. 82E-09 I, 88E-09 2 02E-09 2.28E-09 2.65E-.09 3.01E-09 4.01E-09
Notes: For Chebyshev fits of the above rate coefficients it is necessary to use the following parameters.
Eml n = 7.0E+02 eV, Ema x = 2.0E+04 eV
Chebyshev Fittinq Parameters for Rate Coefficients
He
Temp.
(eV) AO Al A2 A3 A4 A5 A6
500. -4,71093E+01 _ 3,78408E+00 -.4,25226E-01 1.09485E-01-1,88308E-02 -2.18471E-02 1.64914E-03 W
I000. -4.59288E+01 2.96506E+00 -6,94375E-02 4.01519E-03 -9.10887E-03 -1.53339E-02 -4.97257E-04
2000. -4.46311E+01 2,18675E+00 1 67647E-01 -3.86105E-02 -].57224E-02 -6.51960E-03 -3.71278E-04
4000. -4.32631E+0i 1.54495E+00 2 39004E-01 -3.13418E-02 -I.96927E-02 -2,77831E-03 6.46638E-04
7000.-4.20414E+01 1.09232E+00 2 I0178E-01 -1.36333E-02 -1.49539E-02 -2.16792E-03 5.39745E-04
i0000. -4.12037E+01 8.21778E-01 1 74596E-01 -3.48824E-03 -,I.I0046E-02 -2,36544E-03 -2.58516E-04
20000. -3,96301E+01 3.84302E-01 9 69796E-02 5.67825E-03 -3.92022E-03 -1.53584E-03 -5.16122E-04
Equal Temp. -4,49085E+01 3.65780E+00 -6 02220E-01 1.33794E-01 -9.85265E-02 2.12708E-02 8,09123E-03
See appendix for Chebyshev fit details.
B-II5 ' , ,
' He2. ,+ He ->He*(2s) + ,He+
MoxwelliGn - Maxwellion
B-II16
Electron Capture Rate Coefficients for
He + He 2. -> He+(2s) 4 He +
Be_m - Maxwellian Rate Coefficients (cm3/s)
He 2+ ,
Temp. He Energy (eV/amu)
(eV) I0000. 20000. 40000. 60000. 80000. I00000. 200000.
1.0E+00 2.25E-09 7.35E-09 9.33E-09 7.51E-09 5.50E-09' 3.80E-09' 7.83E-I0'*
2.0E+00 2.25E-09 7.36E-09 9.32E-09 7.51E-09 5.50E-09' 3.80E-09" 7.83E-I0'*
4.0E+00 2.25E-09 7.35E-09 9.32E-09 7.51E-09 5.49E-09" 3.80E-09' 7.83E-I0'*
7.0E+00 2.25E-09 7.35E-09 9.31E-09 7.51E-09 5.49E-09 3.79E-09' 7.83E-I0'*
1.0E+01 2.25E-09 7.34E-09 9.31E-09 7.50E-09 5.49E-09 3.79E-09' 7.83E-I0"*
2.0E+01 2.26E-09 7.33E-09 9.30E,09 7.50E-09 5.49E-09 3.79E-09" 7.83E-10'*
4.0E+01 2.26E-09 7.32E-09 9.29E'09 7 49E-09 5.48E-09 3.79E-09' 7.83E-I0"*
7.0E+01 2.27E-09 7.31E-09 9.27E-09 7 48E-09 5.48E-09 3.78E-09' 7.83E-I0'*
1 0E+02 2.28E-09 7.30E-09 9.26E-09 7 47E-09 5.47E,09 3.78E-09 7.83E-I0"
2 0E+02 2.31E-09 7.28E-09 9.23E-09 7 45E-09 5.46E'09 3.78E-09 7.84E-I0'
4 0E+02 2.37E-09 7.26E-09 9,19E-09 7 43E-09 5.45E-09 3.77E-09 7.85E-10'
7 0E+02 2.45E-09 7.23E-09 9.14E-09 7 40E-09 5.43E-09 3.76E-09 7.87E'I0'
1 0E+03 2.54E-09 7 22E-09 9.10E-09 7 38E-09 5.42E-09 3.76E-09 7.88E-I0"
2 0E+03 2.79E-09 7 17E-09 8.99E-09 7.32E-09 5.40E-09 3.76E-09 7.93E-I0'
4 0E+03 3.20E-09 _ 7 lIE-09 8.81E-09 7.23E-(19 5.36E-09 3.76E-09 8.02E-I0'
7 0E+03 3.68E-09 7 05E-09 8.57E-09 7.11E-09 5.31E-09 3.77E-09 8.15E-I0 _
1 0E+04 4.06E-09 7 01E-09 8.35E-09 6.98E-09 5.25E-09 3.77E-09 8.29E-I0" i
2 0E+04 4.94E-09 6 91E-09 7.72E-09 6.58E-09 5.08E-09 3.75E-09 8.76E-I0'
Accuracy: * - Possible Error Greater Than 10%
•* - Possible Error Greater Than 100%
Notes: For Chebyshev fits of the above rate coefficients it is necessary to use the following parameters.
Emi n = 1.0E+00 eV, Ema x = 2.0E+04 eV
Ch_h_shev Fittinq Parameters for Rate Coefficients
He
Energy
(eV/amu) AO A1 A2 A3 A4 A5 A6
i0000. -3.94248E+01 3.34599E-01 1.94015E-01 6 86806E-02 4.95694E-03 -9.99564E-03 -6 I0649E-03
20000. -3.74937E+01 -2.78645E-02 -I.]1501E-02 -3 09862E-03 -9.33585E-04 8.71220E-06 1 09550E-04
40000. -3.70648E+01 -6.95474E-02 -4.17914E-02 -2 13044E-02 -9.81107E-03 -3.95679E-03 -i 20270E-03
60000. -3.74705E+01 -4 74430E-02 -2.81261E-02 -] 48208E-02 "7.60963E-03 -3 68669E-03 -i 56303E-03
80000. -3,80745E+01 -2.90089E-02 -1.58763E-02 -8 00256E-03 -4.24777E-03 -2.17637E-03 -8 77601E-04
i00000. -3.87879E+01 -5.76796E-03 1.27600E-04 8 95128E-04 -2.39349E-04 -7.73294E-04 -5 69452E-04
200000. -4.18939E+01 3.77781E-02 2.64380E-02 1.53165E-02 7.52659E-.03 3.09706E-03 i 14409E-03
See appendix for Chebyshev fit details.
0
B-II7,,
He + He2. -> He*(2s) + He*
0.0
10o 10' 0= i03 104 10sHe_+ Temp. (eV)
B- 118
Elsctron Captul e Cross sections for
lle2+ -_ Li-> He+(2p,3p,4p,3s+3d,4s+4d) + IJ_+
(2p) (3p) (4p! (3s+3d) (4s+4d)
Energy Cross Section Energy Cross Section Energy Cross Section Energy Cross Section Energy Cross Section
eV/amu om 2 eV/amu cm 2 eV/amu _ cm 2 eV/amu cm2 eV/amu cm 2
I.IE+04 3,70E-16 5.6E,02 4.96E-15 1.3E+03 2.99E-16 3.8E+03 6.02E-15 3.BE403 9.77E-16
1.5E+04 2.71E-16 7.1E+02 4.56E-15 1.5E+03 3.54E-16 5.0E+03 5.31E-15 5.0E+03 1.39E-152.0E+04 1.97E-16 9.1E+02 4.20E-15 2.0E+03 4.29E-16 7,0E+03 4.17E-15 6.0E+03 1.51E-153.0E+04 1.15E-16 1.5E+03 3,55E-15 3.0E+03 5.30E-16 1.0E+04 2.64E-15 7,0E+03 1.50E-153.8E+04 5,90E-17 2.0E+03 3.23E-15 4,0E+03 6.08E-]6 1.5E+04 9.31E-16 1.0E+04 1.28E-15
3.0E+03 2.82E-15 6.0E+03 7.51E-16 2.0E+04 3.60E-16 1.5E+04 6,27E-165.0E+03 2.24E-15 7.0E+03 8.00E-16 2.5E+04 1.50E-16 2.0E+04 3,38E-167.0E+03 1.68E-15 8.6E+03 8.36E-16 3.0E+04 7.39E-II 2.5E+04 1.89E-161.0E+04 9.50E-16 1.0E+04 7.94E-16 3.8E+04 2.19E-17 3.0E+04 I.]8E-161.5E+04 3.53E-16 1.5E+04 4.72E-16 3.7E+04 6.50E-172.0E+04 1.45E-16 2.0E+04 2.34E-16
2.5E+04 5.49E-17 2.5E+04 9.89E-173.0E+04 1.77E-17 3.0E+04 4.39E-173.2E+04 1.08E-17 3.8E+04 1,44E-17
References: 240, 243, 245, 259, 262, 263, 264
Accuracy: unknown
Notes: (i) Cross sections Into excited states are determined by measuring the emission fronl the
state and subtracting cascade transitions from higher states aPd making corrections for
the branching ratios.
(2) lt is believed that the data are accurate to within 60%.
(3) References 263 and 264 contain theoretical data that were not included in colnpl]ing A
the present data.
For Chebyshev fits of the above cross sections it is necessary to use the following parameters.
(2p) Emi n = I.IE+04 eV/amu, Ema x = 3.8E+04 eV/amu
(3p) Eml n = 5.6E+02 eV/amu, Ema x : 3.2E+04 eV/amu
(4p) Eml n = 1.3E+03 eV/amu, Ema X = 3.SE+0a eV/amu
(3s+3d) Emin = 3.8E+03 eV/amu, Ema x = 3.8E+04 eV/amu
(4s+4d) Eml n = 3.8E+03 eV/amu, Ema X = 3.7E+04 eV/amu
C__hebyshev Fitting Parameters for Cross Sections
AO AI A2 A3 A4 A5 A6 A7 AB
(2p) -72.5775 -.B54328 -.132073 0636576 -.0301663
(3p) -69.3960 -2.53366 -1.]5152 -.477709 -.109491 -.0224733 -.0359280 -.0364469 -.0124596
(4p) -71.9553 -1.18550 -1.26810 -.417040 -.0333091 .0B22485 .0242456 .00]55260 .00317940
(3s+3d) -69.5364 -2°77071 .724373 -.0299068 .0383153 -.0274998 0511074 .0199350 -.0465182
(4se4d) -70.4843 -1.46194 -.666629 ,0919477 .0166653 -.00399733 -.0199710 .0194456 -.00484478
The fit represents the above cross sections with an rms deviation of 0.0%.
The maxlmum deviation is 0.0%.
The fit represents the above cross sections with an rms deviation of 0.8%.
The maximum deviation is 1,5% at 3.0E+04 eV/amu.
The fit represents the above cross sections with an rms deviation of ].2%.
The maximum deviation is 2.7% at 1.5E+04 eV/amu.
The fit represents the above cross sections with an rms deviation of 0.0%.
The maximum deviation is 0.0%.
The fit represents the above cross sections with an rms deviation of 1.]%,
The maximum deviation is 1.7% at 7.0E+03 eV/amu.
See appendix for Chebyshev fit details.
B-II9
He_+ + Li --> He*(2p, 3p, 4p, 3s+3d, 4s+4..d) + Li+
Cross Section vs, F-ner-gy
----- Chebyshev FitlO-r_-_ , _ J,,,,,l J L ,,,,,,l
ld ld lO_ ldEnergy (eV/am u)
e
Ii
hills Em:Lsslon Cross Sections o£ E]FJOtLon Capture Colllsh, ns £oL'
Ilo2+ + hl -> tle+(Lya,hyp,LyY) + l,i"_
(by.) (hyp) (byy)Energy Cross SectiOn Energy Cross Seotlol] El]elgy Cross Seoti()ll
eV/ainu cm 2 ' eV/ainu (Jm2 eV/al]iLl cm 2
0, IE-01 4,72E-16 B,3E-01 3 ,'/IE-16 1,31'_+03 2 55E-16],OE+00 4.83E-16 I, 0E'l'00 4,42E-16 I,:,1_403 3 01E-16
1,5B+00 5,53E-16 i, 5E+00 6,23E-16 2,0E'I03 3 77E-162,0E+O0 7.30_-16 2,0E+00 7.70E-16 3,0E+03 4 69E-16
2,5E+00 9,40E-16 3,0E+00 8,83[':"I6 4,OE'F03 5 3iE-163.0E+00 1,12E-15 4,0E+00 0.42E-]6 6,0E+03 6 25E-154,0E+00 1.26E-15 5,0E+00 7 65E-15 8,0E+03 6 8[IE:-166,0E+00 1,28E.15 6.0E400 7 02E-16 9,]E+03 6 94E-168,0E+O0 1,21E-.15 8.0E+00 5 99E-16 1,Or+04 6 74B-161,0E+OI I.]3E-15 1,0E+01 S 32E-16 ],SE_D4 4 06F,'-161,3E+01 1.04E-15 ],4E+01 4 43E-]6 2,0E+04 2 02E-165,4E+02 7,23E-15 5,4E+02 4 6U_]-_5 2,5E+D4 B [_IE-178,0E+02 7.351,',-15 7,0E+02 4 04E-15 3,0E+04 4 OO'Z-171,or+03 7,3DE-15 9,0E+02 3 59E-15 3,5E404 1 98_;-17].5E+O3 7,31E-15 9,9E+02 3 42E-15
2.0E+03 7,27E-15 1,5E+0_ 2 93E-153.0E+03 7.07E-15 2,0E+03 , 2.75E-155,0E+03 6,77E-15 3.0E+D3 2,67E-156,9E+03 5.67E-15 4.0E+03 2.63E-151,0E+04 4,10E-15 5.0E403 2,5lE-L5
1,5E.04 2,04E-15 7,01']+03 2,03E-152.0E+04 1,00E-15 9,0E+03 i, 49E-153.0E+04 3,39E-16 1.0E+04 1.29E-15
3.8E+04 1,79E-16 1,5E+04 5,97E-162.0E+04 3.02E-16
3,0E+04 6.52E-173.8E+04 2.20E-17
Referencesz 240, 243, 245, 259, 262 D
A_O.Oo U_Ura_ unknown
ot_ (i) On purpose, no attempt has been made to extrapolate the data between the low alld high
energy regions,
(2) The emission cross seetlon is defined as the photon smlss.[on from state nl with no
correction for cascading f_om higher states.
For Chebyshev flts of the above cross sections lt Is necessary to use tile followJng paramete[s.
(hy a) Eml n = 8.1E-0! eV/amu, Ema x = 3.8E+04 eV/ainu
(Lye) FJmln = 8,3E-01 eV/amu, Ema x = 3,8E+04 eV/ainu
(Lyy) Eml n = 1.3E+03 eV/amu, Ema x = 3,8E+04 eV/ainu
Chebyshev Fitting Parameters for Cross Sections
AO A1 A2 A3 A4 A5 A6 A7 A8
(Lye,) -68.3492 .342390 -1,29878 ,-.802770 -.377254 .0373709 -.0758118 -,0906659 .182862
(Lyp) -69.8158 -,378103 -1.48217 -1.03893 -.3[]0773 .0694862 -,330382 -,0604033 .]95831
(Lyy) -72.2366 -1.]5996 -1.25436 -.404927 -,0551144 ,0691596 ,0107803 -,0]7]457 -.0103497
The fit represents the (Lye) cross section with an rms deviatlon of 3.3%.
The maximum deviation is 6.3% at 2,0E+00 eV/am_,
Tlle fit rep['esents the (hyl)) cross section with an L'ms clevlatlon of 4,6%,
The maximum deviation is 7.3% at 1.4F.IOI eV/ainu,
The fit represents the (Lyy) cross section wlth all rms devlatJon of 1,4%.
The maximum deviation Js 2.7% at 1.5EI04 eV/ainu.
See appendix for Chebyshev fit details.
I]-_12 .I.
Pie;_+ -I- Li -> He+(Ly Ly#, Ly,) + Li"
CrossSectionvs. Enerqy
...... C,hebyshev Fit10-17__LLU_Uj__.L_LZ.U_U.U.,__ _JU_J_I__LL.U_U____L_Lt.ZZU_--L_-mU.
los' lO° ld icl ld' 1o4 ld'F_[nercjy (eV_:lm t.l,')
ii
B- :t22
0hills l'I,lI_lalmn Crollt_ flc(.,k.lorla ml' l;lleotLron CaPture Cmlll.iOT_i_ fret:
11o2'1 .t l_L -.> .lIe 'l(ll.01111tllYtll_) + l,i't '
(lltL) (lJl_) (fly) (II/_)
FInorgy Cr.'mnlJSootlon l,]nel.gy Cron_3 ,¢]eotJol_ l,;norg_ Crmos ,c]ootlon l_'0tlortjyCt'oLin_eotlon
tW/tu, U sm 2 eV/amtl ol, 2 eV/amtl ¢;m2 {.,V/al, LI em2
3,91_403 9,19E-15 3, DI.F_03 7 l17t;-I 6 5, f)Ii:.t 03 2,26I::-] 6 5,00,t.03 1,19L,:-I 6
5,11:_+03 ' B,03_:-15 5,11,1+03 1 05[,3-.L5 6,OFH03 3,]9t%-lG 6,01_.t03 .1,24l,:-16
6,1F.+03 '7,23F,-15 6,0 E-t.03 .1 IO'E-I 5 7, lE.t03 3,60_:-1 6 B, leg,03 1,320-16
7, I_;+03 6,55_]-15 7, ] I,:.I.03 ] ] II,:-15 U,01,:+03 3,66F:-]6 1,01_I04 ], 38_:-16
B, lE+03 5,73F1-,15 I, 0F_-I'O4 9 791!;-16 I ,0E'_04 3,41F_-16 I, 51_;+04 1,291,3-.16
Q, I 0_]+04 4,07E-15 1,5F;+04 5 20[,'-16 1,.,I,,t04 2,33F',,-16 2,01_.t04 8,231_:-1'/
1,5E+04 1.490-_15 2,0_]+04 2, 71F',-16 2,DE.F04 ],46L]-16 2,5_]+04 3,51]_-1'/
2,0E+04 6,02E-16 3, Of.t04 9 35l_-17 2,5F.I 0,1 7,35l:',- 1 "1 3,0P,40 4 2,30F,'-17
2,5F,+04 2,60E.-16 3,8F,+04 5,04E-17 3,0E+04 4,61_;.,]7 3,8P.+04 i. 58_:-I'I
3.0_I.104 1,03P,-16 3, [II::40,1 2,99E-]7
3,7E+04 4,36E-17
R_ferenOeSl 240, 243t 245, 262
AeeuraoZj 60%
ot_9__t (i) The emission cross section is deflno(l as Lhc, p|imton eltiJss|on l_z'om_Itato Iii wlt;h no
correatimn8 for cascading i,e, |_a.llne_r-l_emissLon cross seotlon is t,ho om]sslon of
photons in t||o 3 ->2 trans]tioll aL X =164 l_m which does not inclutlu any other mitransll Ions. i(2) The probable accuracy of the c]ata i_ estimated at 60%,
F'mr ChebysheV [,,itsof the above cross _eet]on,d lt is necessary Lo tlso the _m/lowing paraltietors,
(II.) _"mi!]_ 3,9E+03 eV/amu_ [':ma_= 3,7E+04 eV/atoLl
(}I_) Eml n = 3,8E+03 sV/ainu, Ema x = 3,8l,;+04 eV/ainu
(111) };mln '_ 5,08+03 eV/ainu, _:max = 3,8l,_.I04eVatoLl
(II6) Eml n = 5,0E+03 eV/amtl, Elnax = 3,8I.I.104eV/alnu
Chet_shev l,'ittir,_LParamoters fret"Crmu[_ Seotloi_n
AO A| A2 A3 A4 A5 A6 A7 AB
(|Ia) -60,6366 -2,68265 -,765389 -.03()8549 .0354272 .00]27287 ,0359553 ,0365120 ,0161142
(II,) -71,0392 -1.4615"I -.6776_I ,0638041 ,0375640 .00465953 -, 009182'J0 ,0189071 ,0164169
(Hy) -72,9366 -i,]4183 -.55406D ,i05201 .0358399 ,0591207 --,00055619 -,[)336544 -,0423521
(ll_) -74,4125 -.995923 -.,511481 -,0]19520 .359667 ,067056] -,0432569 -,0655[125 -,0724875
'rbe fit represents the (11_,) cross section with an l:,_l dovlt_tton o[, 0,6%.
The r.aximum deviation i_ 3.0% at: 2,()I:',_04t_V/_unu,
The fit t'opresont8 the (II[%)cross sectimn with an rm_i (It-vJatiorlor 0,0%,
The max|mUm devlatLon ]s 0.0%,
The _]t rep['esents the (lly) crosl_ section with an rl._.] (leviaLiorl mE 0.5%,
The maximum deviation i_ ] 1% at [1,0E+03 eV/ainu,
'Phe fit represents the (tl 6) cros'J section with _in Ims devlattmn mr, 0,(}%,
TLe m(txlmut_ deviation _s O,0%,
S_o apl)en{]ix for Chebyshov f|t (lelal]s,
Q
i
2-=
O
t-le:_ -t- li :, Ile+(I-.I I.-I_lqr, I-t_) .I li _
o.
.. I (_!,"JC.b ..... P0
O
C. Cross Sections for Bxcltation and Spectral Line Emission(* denotes rate coefficient data _also)
Page
H + H -> H(2s) ....... , ..... , C-2-> H(2p) ............ , , C-2-> n(3s) ........ , , .... C-4-> H(3p) .......... , ..... C-4-> H(3d) ......... , ..... C-4-> H(Balmer-.) ........... C-4
H + H2 -> H(2s) [projecti]e] , , ..... C 6-> H(2p) [projectile] ....... , C-6-> (2s) ['target] . . , , ..... , C-6-> (2p) [target] ......... C-6-> (Lyman-.) .......... , , C-8-> H(3s) ........... C-10-> H(3p+3d) .......... C-10-> H (Balmer-.) ........ C-12-> H(4s) .......... C-14-> H(4p+4d) .......... C-14-> ]l(Ba].me:r-_) , . , ..... C-14
H(2s) H_ -> H (Lyman-,,) .... , .... C-16•-> H(3s) ............ C-18-> l[(Balmer-.) . ........ C-18
H(2s) + He -> ii(Lyman-,,) .......... C-20-> H(3s) ............ C-22-> II (Ba].mer-.) ......... C-22
H + I-le - > H ( Lyman-L,) .......... C- 24 *-> H(2s) ........... C-30-_ lt(2p) ........... C-30-> H( 3s ) ........... C-32-> I-I(3p) ........... C-32-> H(3ct) ............ C-32-> H(3p+3d) ....... , . . , C-32-> H (Balmer-,) ......... C-34-> 11(Bal.met-o) ......... C-34-> H(4s) .......... C-36-> H(4p+4d) ......... C-36--> IIe(31P) ......... C-38-> He(3!_P) ......... C-38-> He(3:ll)) ....... C-38-> tle(41S) ........ C 40-> He(4_P) ........ c-40.-> He(41D) ...... . . C-4()
-> I-le(4_S) ........ C-42> He(4:_P) ....... , . C-42-> He(4:JD) ......... C-42
C. (Cont'd) O
H+ + H -> H(2s) .............. C-44
( ) C-44"-> H 2p .... , .........
-> H(n=2) .............. C-48
-> H(n=3) .............. C-48
-> H(n=4) .............. C-48
H° + li2 - > H+ + H(2s) 4. H ......... C-50-> I-I_ + H(2p) + H ......... C-50-> H' + H(3p) + H ......... C-52
- > I{(Lyman-c, ) ........... C- 54-> H (Balmer-.) ........... C-56
-> H (Balmer-_) ........... C-56-> H (Balmer-_) ........... C-56
-> H2(Lyman"Band) ......... C-58
-> H2 (Lyman-Band) ......... C-58
H + + He -> He(2:ts) ............. C-60"
-> He(2]P) ............. C-60"
-> He(21S + 2aP) .......... C-60
-> He(3:tS) ............ C-66
-> He(3:tP) ............ C-66-> He(3:ID) ............ C-66-> He(4:ts) ....... ..... C-68
-> He(4tp) ............ C-68
-> He(41D) ............ C-68
-> v.u.v.(20-140 nra) ........ C-70
He + + 14 -> H(n=2) ............. C-.72
-> H(2s) .............. C-74
-> H(2p) .............. C-74'
He' + H2 -> H(Lyman-,,) ........... C-78
-> H (Lyman-o) ........... C-78
-> H (Balmer-.) .......... C-80
-> H (Balmer-o) .......... C-80
-> H(2s) ..... ........ C-82-> H(2p) ............. C-82
-,> H(3s) ............. C-84-> H(3p) I ...... • ...... C-84
-> He'(2s) ......... , , , C-86
He+ + He -> He(2tS) [target] ........ C-88
-> He(2]P) [target] . . . , , . C-88-> He(23S) [target] ....... C-90
-> He(23P) [tar'get] ....... C-90
-> He(3:IS) [target] ........ C-92
-> He(31p) [target] ....... C-92
-> He(31D) [target] ....... C-92
-> He(33S) [target] ........ C-94 O
-> He(33P) [target] ........ C-94
-> He(33D) [target] . , , ..... C-94
C. (Cont'd)
He) + He -> He(4/S) [target] ....... C-96
-> He(4:IP ) [target] ....... C-96-> He(4_D) [target] ....... C,-96-> He(4]S) [target] ....... C-98
-> He(4]P) [target] ....... C-98
-> He(43D) [target] ....... C-98
-> He+(n=2) [projectile] ..... C-100
-> He'(n=3) [projectile] ..... C-I02
He + H2 -> H(Balmer-,) ........... C-I04
-> H (Balmer-_) ........... C-I04
He + He -> He(2 S) ............ C-I06
_> He(2 P) ............ C-I06
-> He(3 P) ............ C-I08
-> He(3 D) ............ C-i08
-> He(3 P) ............ C-I08
-> He(3 D) ............ C-I08
-> He(4 S) ........... C-II0
-> He(4 P) ........... C-II0
-> He(4]S) ......... C-I12
-> He(43P) .......... C-I12
O _> He(2s 2 itS) ........C-I14
-> He(2s2p3P) . ....... C-I14
> He(2p 2 lD) ......... C-I14> He(2s2piP) ..... . . . + . C--I14
> He-(is2s 2 2S) .......... C-I14
He 2) + H -> H(2s) . . .... ....... C-I]6
-> H(2p) ......... .... C-I16
He(2]S) + He(I:IS) -> He(31P) + He ..... C-I18
-> He(3JP) + He ..... C-]20
-> He(43S) + He ..... C-122
-> He(4_D) + He ..... C-!22
-> He 4 He(4:_S) ..... C-]24
-> He + He(4]D) ..... C-124
H+ + Li(2s) -> Li(2p) ........... C-126
-> Li(670,8 nm) ........ C-126
He -) + Li(2s) -> Li(6'70.8 nra) ........ C-128
He 2) + Li(2s) -> Li(2p) .......... C-130
-> Li(670.8 nra) ....... C-130
C-2
Excitation Cross Sections for I
H + H -> H(2s,2p) + H(z)
H(2s) H(2p)
Energy Cross Section Energy Cross Section(ev/m.u) (cm') (ev/ml_u) (cm2)'
2.0E+03 8.03E-18 4.0E+03 1.62E-173.0E+03 9.80E-18 5.0E+03 2.29E_174.0E+03 1.15E-17 6.0E+03 2.44E-17
5.0E+03 1.29E-17 7.0E+03 2.47E-17
6.0E+03 1.43E-17 8.0E+03 2o41E-177 0E+03 1.51E-17 90E+03 2.35E-178.0E+03 1.56E-17 I.OE+04 2.28E-17
9.0E+03 1.59E-17 1.5E+04 1.92E-]71.0E+O4 1.60E-17 2.0E+04 1.58E-17
1.5E+04 1.37E-17 3.0E+04 i.17E-172.0E+04 1.04E-173.0E+04 6.64E-184.0E+04 4.65E-18
5.0E+04 3.48E-186.0E+04 2.74E.-187.0E+04 2.28E-188.0E+04 2.02E-189.0E+04 1.84E-18
References: 15, 592, 593, 594, 595, 596, 597, 598
Accuracy.' Unknown
Notes: (]) The S_l_ol H(_) denotes that the target atonl nlay be left ii] any
[excited] state after the collision. (2) All theoretical treatments of theH + H excitation cross sections are in serious disagreenlent withexperiment and with each other, both ill absolute magnitude and energydependence. For various theoretical treatments see Flannery (Ref. 594 -four state impact paraqleter method), Mcbaughlin and Bell (Ref. 595 - closecoupling exchange), Shingal et al. (Ref. 596 - four state semiclassicalimpact parmlleter), and Khurana et al. (Ref. 597 - 2Tld Born approximationand also distorted wave Born).
C!]ebyshev Fittinq Parmlleters for Cross Sections
H(2s) Emi n = 2.0E+03, Ema x = 9.0E+04H(2p) Eml n = 4.0E+03, Enlax = 3.0E+04
AO AI A2 A3 A4 A5 A06
H(2s) -79.1098 -.784062 -.651723 .0462865 .]]4234 -.00487654 -.0114391H(2p) -'77.1082 -.256046 -.232311 .070]782 -.0315673 .0229762 .006]2383
The fit represents '. tile H( 2s ) cross section with all rlllS deviation of i. 2%.The maximum deviation is 2.8% at 2.0E404 eV/aanu.
The fit represents the H(2p) cross section with ali rms devlation of 0.3%.The maximum deviation is 0.6% at 6.0E*03 eV/_uu.
See appendix for Chebyshev fit details.
0
C-3
0, H + I-t -> H(2s,2p)
Cross Section vs. Energy-1610 , , ..,., ,,,,,, ,- , , ,,,,,.
= H(2p)
x = H(2s)
E \\
° f0 '_ lO-r/0 - Recommended® - Databr)
(/3
o _@ _ ' _ Chebyshev Fit
• . , _ _\\X"\_
10-1. 8 l I 1,, , I i iii I 1 I 1 I I I 1
lo_ lO' lO_Energy (eV/a mu)
C-4
Excitation and Spectral Lille Emission Cross Sections for Q
H + H -> H(3s,3p,3d) + H(r)-> Balmer-a enlissior_
H (3s) H (3p) H (3d) Ha
Ene rgy o Energy o Energy o Energy o
(eV/_uU ) (cm 2) (eV/_ml ) (cm 2) (eV/_llu ) (cm 2) (eV/_ml ) (cm _)
I.OE+03 i. 68E-18 1.0E+O3 7.24E-19 I.OE+03 2.53E-20 I.OE+03 1.87E-182.0E+03 6.73E-18 2. OE+O3 5.76E-18 2.0E+03 3.22E-19 2.0E+03 8.27B--184.0E+03 1.22E-17 4.0E+03 1.45E-17 4. OE+03 i. 14E-18 4.0E+O3 1.45E-177. OB+03 8.59E-18 6. OB+O3 ].63E-17 60E+03 1.39E-18 7. OB+03 I. 20E-17I. OE+04 6.47E-18 7. OB+03 i. 59E-17 7. OE+03 i. 38E-18 I. OB+04 9.34E-182.0E+04 3.48E-18 1.0E+04 1.34E-17 1.0E404 i. 18E-18 2.0B+04 5.05E--184.0E+04 1.76E-18 2.0E+04 7.42E-18 2.0E+04 6.78E-19 4.0E+04 2.68E-187.0E+04 1.07E-18 4.0E+04 4.27E-18 4.0E+04 4. liE-19 7.0E+04 1.71E-181.0E+05 7.69E-19 7.0E+04 3.11E-18 7.OE+04 2.99E-19 1.0E+05 1.32E-182.0E+05 4.08E-19 1.0E+05 2.55E-18 1.0E+05 2.44E-19 2.0E+05 7.6OE-194.0E+05 2.11E-19 2.0E+05 1.61E-18 2.0E+05 1.50E-19 4.0E+05 3.97F.-197.0E+05 I. 20E-19 4.0E+O5 9.29E-19 4.0E+05 8.23E-20 7.0E+05 2.32E-191.0E+06 8.72E-20 7.0E+05 5.57E-19 7.0E+05 4.91E-20 1.0E+06 1.65E-19
I. 0E+06 4 .OOE-19 i. OE+06 3 .56E-20
Reference: 598
Accuracy : Unknowil
Notes: _I) We are not aware of any experimental data for the excitationof-_]e i = 3 levels of H by H impact. (2) The data Shown are obtained from
Mcbaughlin and Bell (Ref. 598) using first order excl]ange theory. Theyalso calculated these excitation cross sections using the first Bornapproximation. Below lO s eV/_ilu tl]e Born calculations are as much as a
factor o_ 5 below tile data obtained f_om the _xchange tI_eory. TIlese data
are placed here to PrOvide an insighti as to the magnitude and energydependenoe of the n = 3 excitation cross sections. (3) The H= emission
cross section is given by Ha = o(3s) + 0.118 o(3p) + o(3d). (4) The syn_oldenotes that the target atom may be left in any state.
Chebvshev Fittinq Par_11eters for Cross Sections
H(3S) Elll]n = I.OE+03 eV/a]iltl, Enlax = 1.0E+06 eV/_llull(3p) Emi n = 1.OE+03 eV/ainu, Enlax - 1.0E+06 eV/_llu
H(3d) Bmi n = I.OE+03 eV/ainu, _._max = I.OE+06 eV/_lulHa Emi n = I.OE+03 eV/6uuu, Bnlax = I.OE+06 eV/a/flu
AO AI A2 A3 A4 A5 A6I
H(3s) -82.5799 -2.05302 -.908967 .534!01 -.249917 .0520636 .0418468H(3p) -81.2005 -.954175 -1.20328 .638574 -.32834] .0263311 .0719202H(3d) -86.3820 -.612848 -1.47849 .754596 -.362929 .0428931 .0876543I-la -81.7586 -1.76650 -.933877 .519497 .264797 .0406777 .0464266
Tile fit represents the H(3s) cross section with an r,llsdeviation of 4.2%.The maximunl deviation is 6,2% ai 2.0E+03 eV/6mlu.The fit repre_ents tile H(3p) cross section with an rms deviation of 2.0%.Tile lilaximum deviatic_n is 2.9% at 2.0E+05 eV/6uuu.
The fit represents the H(3d) cross section with an rms deviation of 2_6%.Tile maximum deviation is 4.6% at 2.0E+04 eV/6mlu.
Tile fit represents the Hc, cross section with an rms deviation of 1.6%.
The maximum deviation is 2.2% at 2.0E+03 eV/_m].
See appendix for Chebyshev fit details. W
(' 5
0H + H --> H(3s,3p,3d,H_)
Cross Section vs. Energy10-16- .... I', I, i I III'li I I I 1 IIIII I I '! ! IIlll ...... i 1 'I"1 111
,_ A = H(3p)10-17_- X=H_
- q = H(3s)
P-. - x - H(3d)IN
E -0
0 t'._ -1B !
O 10 :" 7 Recommended
@ - Datau_u)0
U Chebyshev Fit
10-i! _
- j10-2 _. 1 l 1 llllil I 1 I 111111 1 1 1 Illlll 1 I 1 1111
102 ld 10" 10_ 106Energy (eV/am@
C-6
Projectile, Excitation and Target Dissociative ' Excitatioll Cross Sections for Q
H + H2 -> H(2s,2p) + _ H2
-> _ H 4 H(J,2p) + H
H(2s)[proj.] N(2p)[proj.l H(2s)[targ. l H(2p)[targ.]
Energy o Energy o Energy o Ene rgy o
(eV/mllu ) (cm 2) (eV/_lu ) (cm 2) (eV I_llU) (cm 2) (eV I ml_u) (cm 2)
2.0E+03 5.56E-18 5.0E+03 4.13E-17 5.0E+03 2.78E-]8 5.0E+03 6.90E-18
3.0E+03 6.69E-18 6.0E+03 3.53E-17 6.0E+03 3.26E-18 6.0E+03 8.60E-]84.0E+03 7.62E-18 7.0E+03 3.11E-17 7.0E+03 3.57E-18 7.0E+03 9.97E-185.0E+03 8.47E-18 8.0E+03 2.79E-17 8.0E+03 3.75E-18 8.0E+03 1.12E-17
6.0E+03 9._9E-18 9.0E+03 2.61E-17 9.0E+03 _.81E-18 9.0E+03 1.22E-177.0E+03 9.90E-18 1.0E+04 2.49E-17 ].0E+04 3.86E-18 ].OE+04 1.32E-]7
8.0E+03 1.05E-17 1.5E+04 2.40E-17 1.3E+04 3.88E-18 1.3E+04 1.39E-179.0E+03 1.lIE-17 2.0E+04 2.08E-17 ].5E+04 3.83E-18 1.5E+04 1.37E-17I.OE+04 1.16E-17 2.5E+04 1.78E-17 2.0E+04 3.68E-18 2.0E+04 1.16E-171.5E+04 1.32E-17 2.5E+04 3.53E-18 2.5E+04 9.03E-182.0E+04 1.20E-172.5E+04 9.84E-18
References: 124, 592
Accuracy: Unknown
Notes: (i) H is considered tile projectile and }I2 the target. (2) The s_iR_ol _denotes all states in which the products are left. (3) The n=2->l transitionis at wavelength 121.57nm.
Chebyshev Fittinq Par6u,eters for Cross Sections ' Q
H(2s) proj. Emi n = 2.0E+03 eV/mllU, Enlax = 2.5E+04 eV/_lluH(2p) proj. Emin = 5.0E+03 eV/6uuu, Ema x = 2.5E+04 eV/_lluH(2s) tarE. Emirl = 5.0E+03 eV/ainu, Ema x = 2.5E+04 eV/_lluH(2p) tarE. Emi n = 5.0E+03 eV/aullu, Ema x = 2.5E+04 eV/muu
AO Al A2 A3 A4 A5 A6
H(2s) proJ. -78.5298 .381193 -.153241 -.0881960 -.0354361 -.00839689 ,00756242
H(2p) proJ, -76.3640 -.378165 ,0409330 -.0624299 -.0180012 .0197844 ,0125324
H(2s; targ. -80. 3831 .0903819 -, 109415 .0282363 -.00676568 .000903034 .00303522
H(2p) targ. -78.217S .158165 -,269341 -.0251991 .00457227 .00145158 -.00685275
The f_t represents the H(2s) proj. cross section with a,] rms deviation of 0.5%.The maximum deviation is 0.8% at 1.0E+04 eV/6mlu.
The fit represents the H(2p) proj. cross section with an rms deviation of 0.2%.The maximum deviation is 0.3% at 8.0E+03 eV/_llu.
The fit represepts the H(2s) tarE. cross section with an rms deviation of 0.2%.The maximum deviation is 0.3% at 9.0E+03 eV/_uu.
The fit represents the II(2p) targ. cross section with an rms deviation of 0.4%.The maximum deviation is 0. I_ at 1.3E+04 eV/6um,.
See appendix for Chebyshev fit details.
0
C- 7
0H + H2 -> H(2s,2p) + EH.,
td + H_ "> EH + H(2s,2p) -tt t--t
Cross SectionvsoEner-gyI I 1 I I I I '1 I I 'l ' I" 1 '--[_T--T--T'-
-\\ A- ls-->2p (proj.)\
_ \\\ "< - ls->2s (proj.)
""'_..--___._ q - Is- >2p (target)
g--. - ".xX_ _ = ls->2s (target)E0
10 -17 RecommendedIL_ --
,AL ':lP -- Data
g br )
0o
o _-U - - ..... Chebyshev Fit
--
10-18....... I I 1 J t J ,Jl i l I J i i J l
103 104 10sEnergy (eV/am u)
C-8
A
Total Spectra] bii]e Eill:l_Bs:t.orl Cross Sections fol g
H -i. t12 -> H(Lylilan-c_)
Energy Velocity Cross Sect_otl
( eV/_mi ) ( cm/s ) (cm _')
i. 5E+03 5.38E+07 7.17E-172. OE+03 6.21E+07 6. _7H:-.173.0E+03 7.61E407 5 98_]-]74. OE+03 8.79E+07 5.38E-1"75. OE+03 9. 821_,]+07 4.9]E-176.0E+03 1.08E+08 4.50E-] 770E+03 1.16E+08 4.22E-1780E+03 1.24E+08 4.04E-179 0E+03 1.32E+08 3.92E-171 0E+04 1.39E+08 3.80E-171 5E+04 ].70E408 3.48E-172 0E+04 ].96E+08 3.20E-]72 5E+04 2.20EI.08 2.97E-173.0E404 2.41E+08 2.81E-]74.0E+04 2.78E+08 2.52E-175. OE+04 3.11E+08 2.28F,-176.0E+04 3.40E+08 2.15E-] 77.0E+04 3.68E+08 2.06E-178.0E+04 3.93E+08 ]. 98E--179. OE+04 4.17E+08 I. 92E-17i. 0E+05 4.39E+08 ]. 88E-17I. 3E+05 5. OIE408 1.7"7E-17
References: 124, 194, 333
Accuracy: Unknown
Notes The total spectra], line emission includes radiation from excitation
of-r-_e H projectile and the dissociative excitation of the II2 target.
Ch_ebyshev Fittinq Parcmueters for Cross Sections
Elllin = i. 5E+03 eV/a_llu, Elllax = I. 3E+O5 eV/_im
AO AI A2 A3 A4 A5 A6
-75.7615 -.720784 .0118290 005'40110 -.0025"1496 0252003 -.00232715L
The fit represents tl]e above cross section with all rius deviation of 1.2%The maximum deviation is 2.4% at 2.0E+03 eV/mllu.
See appendix for Chebyshev fit details.
g-9
OH + H_ -> ZLy_
Cn:,ss Section vs. Energy "-16
'iU"" ..... , , 1 i i i i t I ..... i i I '1' i I'1'1 I ' i i" i i i i li
_ _, z_ - ZLy_- _,
\
_ \r.; X,
h _ \_..,.
CO
'4-_ \. Recommended
0 @ - DataOr)
ogooOk_.
U ..... Chebyshev Fit
10-17..... .J i 1 1 l lilt I I !__L...£1III, l 1 I l 1 ILL
lO_ lo' _o_ lo_Energy (eV/a m u)
II
_x¢_]t:at.lon Cro_f_ Sec_t.].on_ for
H t 112 -> 11{3s) -r H2-> H(3p-i,3d) + 1.1_
' I-1(3s) tl (3p-t.3d)
, Ellergy Cross Sect.loll l!hlel!gy crOSS SoctlOll*(eVlamu) (c,._) (eVl_.{u) (c,l_)
2.0E+02 1,'84F,-18 2,0F,I02 5 "12_-]84,0B+02 4,6JB-18 4,0E-I.02 i 011_-1'I6.4B+02 5,66B-18 7,0E+02 1 25E-177,0 E+ 02 5., 6 ii.g I,8 ] , 0 I2]-t-03 1 35 I_- ] 7
B -. i' 4 "' I OB+03 4,951!; "]8 1.51,, -03 ]. 281_-171,5B'I'03 3,53E-18 2,,0E4"O3 I 17_]-.1+7
0 |'2 0_,+03 2 96_]-]8 3 OE'IO3 8.66L-18d4,0[',+03 2 43E-18 4 '()E+O3 6 34F,-18
5.0F,4.03 2 36B-.18 l 01".,I+O3 3 91E-].87,OB-lO3 2 46E-18 i OE+04 '3 64E=18],0_.I-04 3 21E-18 ] 5FH04 3 .13E-.18
- iu1.5P,+04 4 01f.,-].8 2 0E-I-04 2 ]3E-182,0_+04 4 411!:-18 4 OE-I.04 .| 291_,-18
, r _2 3E+04 4 ,._01.,-18 7 OB+04 ]. 17E ]80 _ ' " |_ "2 5_+04 4 46F,-.L8 J. OB+Ob 1:1.61_,-18
4.0_H-04 3 591]]- ] 8
7.0E4.04 2 861]_-.I.8 * see tlot:eta (3) and (4)1.0E+05 2 "13E-1.8
References.l 133, 500, 601
Accuracy I Unknown .
Notesl (.l) Because of its imlch longer liietJ.nle, the 3s excl.tatloll ts resolvable][ii'"t!he Ballller-n elllJss.[on. (2) The 3s .cross section represents that for
excitation of'the H projectile only. (3) The cross section label].ed H(3p + 3d)is de ternlined by subt:tact:ing o( 3s ) fronl tile t ct al. Ba.l.lller-_ elllis (]icl] cross
sect:ion, and therefore represents o(3d) 4 (),]2 o(3p) because of br ancllirlgrat 'los, (4 ) Pcr energies above 2 keV /aluu, tile H( 319 .I- 3d ) cross aec:t:ion
represents excitation oi! tile project:l].e only., At ].swat energies, contribtlt:.i.onsfrom dissociative excitatiorl of 112 targe t lllO].ecules are included. Coillparisonof the data suggests tllat these oontribtltlons are slnal]..
Chebyahev F]ttinq Par.gmet:ers for Cross Sections
It ( 3 s ) Etu:l.n = 2, OE+02 eV/_ml, E = 1. oB-r05 eV/miniH(3p43cl) Bmi n 2.0E+02 'eV/_mm, ,max= II,till x =' i. CB+05 eV/allltl.
AO A l A2 A3 A4 A5 A6
I{,(3s) -80,5534 -. 0150679 -. 1.45036 , ] 0962"I -, 341.180 . ] :1.3"/[]:I . ]3] ]59H(3p+3d) -80, :1203 -], ]3:176 -. 496856 ,359704 .00520846 -. 0168451 .0653.15]
The fit represents t:he t1(3,'3) crot-ls sect.loll w.t.t:ll an rms dev.t at .t on of 3.2%.The maximum deviation :is 7.0% at 4.0S-ro4 eV/amtt.
The fit represents the ll(3p-l-3d) c:rc)ss ,,:lect..l¢:)il w.ltll all 'rlr, s clev] at LOll o.L 'I..1%,The IIlaX]tlltllll deviation is' L4.5% at '1. OE-I O] (_V/?:llllII,
See append:l× for (Theby_:dlev .f.:].l. det:a.L 1 s, _I
i
c- 11.
H + H2 .-> H(3s) -h H2H + H2 -> H(3p+3d)+ H2
Cross Section vs. Energy10-;6
_'-- i, 1 i: u i u v i'1 ..... t' i "T" i I"i 1 i'f ..... I _r--'T--:l -1 i iii,
,x = : l(3s)
x = H(3p+3d)
Eo
0 ,'__ 17o 10- - Recommended¢> '" ---_'-- Data
0_0 _ ' Chebyshev Fit
U _ '_\
- / \ \,:,, ,f"X,
10-1 .... I 1, I l_lLJ._ll 1 I J I *llll I 1 £ I II11
lo_ lo_ _o" lo_Energy (eV/a m u)
O
C-.t 2
Total ,SperJt'ral btlle l?llllJ t.t[1.|Oll Crcms Sect ]cHl[_ fr__r
t.I .t t1_ -> {Ba].ltler-_
Tot:al (H t. t17,} II;,, (tat'g,) li (prt_j,}
Bne rgy o t_,nergy o I_ne rgy o(eV/a]lltl } (Cltl_.) (eVlalltl) (c_lll_) (eV/all11.1) (cJ'lt_:_)
5 0_-I..01 .Io9B_-19 2,01]+03 i 901_-.L8 2 01_-I03 I b81]-1770B-t.OI 6,351_-19 3,0E+03 I B'11!;-18 3 OI?He3 1 141.,-]7i OB+02 1,67B-.18 4,0E+03 1 901_-18 4 013-I03 9 06E-181 5E4.02 4,93E-18 5,0E-t.03 1 95E-18 5 0B-tO3 "1 6.[F]-1820B-I.02 7,09[_-18 6,0E-I03 2 02E-]8 6 0B+03 6 83E-IB4 0_;.1.O2 ],47P.,-17 7,OF,403 2 ]ll_-J(] "1 01_'t.O3 6 54F,-.1870E+02 1,80P,-17 '8,0B403 2 241_-1B 7 5B-IO3 6 52F,.-1890E+02 1,84E-]7 9,0E4.O3 2, 37E-lB B 0l_-IO3 6 62F.,-IB1 0F,403 1.82B-17 1,0F.,-I.04 2 541_-18 9 0E-I.03 6 88F,-18i 5P,4-03 1,75_]-17 1,5E404 2 94l_-18 I 0_.I-O4 7 04F]-1820E+03 1,56P,-17 2,0E'I-04 3 15E-18 I 5{U-IO4 7 liE-184 oB+e3 1,JOE-J7 2,31_-t-04 3 1(L-.[8]_ 20Lr,'t'O4 6 69I_-187 0E+03 8,76E-18 3,0F,+04 2 89E-18 3 01!H_04 5 391_-1880E+03 g,69B-i8 4,O_-IO4 2 30E-18 4 OB+D4 4 "23E-].8
1 oB+e4 9 54B-.18 5,0E+04 I 93E-].8 5 0F,+O4 4 43E-181 4P.+04 ] O]P,-II7 6,0E404 I 63E-18 6 0B+O4 4 25F_-]82 0B+04 9 84E-18 7,0B-I04 I 41E-JB 7 OB+04 ' 4 20E-]84 OF,+04 7 14E-18 8,0F,.I04 ] 24E-18 8 0[_,404 4 18[_-18,.OB+04 5 26E-18 9,O_-I04 I iI[_]-18 90F_.I.O4 4 ]7E-]8I.OE+O5 4 61B-18 1,0E+05 ] 0]._3-18 1 OB+05 4 17E-]8
Referencesl 133, 500, 601
A=.q.ccu_.._ Unknown
Notesl (] ) The total Balmer-c, emlsslon cross sectiorl Ht, is equal to tile FJLIII|
of tile ellllssion from tile projectile (Flpc,) alld the target: (2-l,r_),(2) Ha]flier-s radiation is from the n=3->11=2 transition ill II w.l.th x 56,2811111,
Ctleb_t.itl_ Paranjeters for Cross SectioNs
Total Eml u = 5.OE_01 eV/ainu, _max = I,OE+05 eV/emlu}t 2, El_.l,j.n = 2 , OE-t-03 eV/alllt.i, Nil_ax = 1 . OE+05 eV/_utltlH I_111tn = 2, OB-t03 eV/alllU, _'lllaX = ] ' O_,-t-O5 eV/r.'lllltl
AO A1 A2 A3 A4 A5 A6
Total -79.7992 ,953923 -1,39409 ,663856 -, 262806 -..O749405 ,0516520H 2 -81,5995 --.183064 -.361113 -.]85120 ,05591]4 .059]802 -,0130234
H -79.OO77 -,627859 ,128139 -.0950362 .07"/2477 ,O565053 -.0596124
The fit represents tile Tot;al cross sect:Iou w tt:ll all rlns dev lat:Icn] oJi 7.0%,Tile lllaxillltllll deviation .ts 13,6% at; 7,0E:-I0] eV/alllu.
Tile f/t: represents the II 2 cross se(ttton wj.t:h an ,IUS cl(,_v.]at].on of 1,4%.The ma×/mum deviatJorl Is 3,0% at 4.0_:-t04 eV/anu_,
The fit; repres_::nts t:he 14 c',t'oss section wl.t:h an rm_] devlaL.lo_ o[ t,9%.The illa×tlllul_l devtat_,tor'_ :1[-_ 3.4% at: 3.0_.1t {)3 cV/atm_,
See appendl.x for Chebyshev fit: det:a:l.l_;, O
10 -19 I I I J lllll ,1 I I I Illll I I 11 lllll I I I I Iii
10' 102 103 104 105Energy (eV/am@
, I_I,
C-14
Oq'otal I_xctt:al:ton _t_cl 8poot-l:al h_/no I_nltr4slon Cvoat_ Ek:_e.t-tt_na for'
H .t. t1_. -> t1(4_4p-t-4cl)
-> H( l..lal.lllo t-B )
H( 4s ) H(4p+4d) H( Ba,L011or-_ ) ,
Bllergy o [!]ILOr cjy o [!_rlerg_ o
(e V l_im ) (om 2) (oV lamu ) (C:ml2) (eVlmnu ) (cml_)
2 OB+02 2,698-19 2 OB-l-e2 9,258-19 6,0t_-t.01 3 13_-203 0_+02 5,20E-19 3 0t_-1.02 .1'_50l_-18 7.01_-t0] 5 98E-20
40E+02 9.30E-19 4 0t_+02 J.,911_-18 ],0B.i02 2 _[91_-1950E-I,02 1,01_I-]8 5 01_-t02 2,20F,--18 1.51_.F02 7 3BI_-.19
6 0L_+02 i 318-18 60_].l.O2 2 4Ot_-18 2,O_-iO2 1 24_,-.18"l 01_+02 1..128-18 70E-t'02 2.54I/I-18 4,()F,-t02 2 67E-18
B OE-l,02 1,]0F.-18 80[_I02 2.66F,-18 7,0E402 3 661",-1890E+02 1,068:-18 90F,-F02 2,76E-18 1.01.,3-I_03 3 90E-18I 0_.I.03 ], O2F,-18 10|DI.03 2,861,3-]B I, 5_:-II03 3 95H:-3.8] 5_:+O3 _,58_:-19 ] 31Dt.03 2,99E-]8 2.01Dti03 3 69E-]8
20E-t03 7.48F,-19 I 51']-t.03 2,98_-18 " 2.51_-ti03 3 37E-]82 519,'1"03 6.67_-19 2 01_.I03 2,84F,-]8
2.5E403 2,64F,-]8
Referencesl 600, 6017
¢
Aocurapy.i , Unknown
Notes I (1 ) The cross SeCt to11(_ t110.1 tlcle e×ctt at to11 of the project 11e H,disso61atlve excltatloll of the target H2, alld .H Ballller-B lilll9 ellllsSloll frOlll bothprojectile and target. (2) The Ball,er-B racllatlon has a wav_length of 486.1311111,alld corresponds to _ t h_
ll= 4'->11= 2 t rallstt.l.oll ill H. B
Chebyshev Fttttnc I Parameters for cross Sect_i_Qns
H(4s) ._m'lu = 2.0EI02 eV/aura, _luax = 2,5F..+03 eV/_uutl(4p+4d) _P]lll:l.n = 2.0B+02 eV/ainu, ._;ma× : 2.5_+03 eV/ainuH(Ba].iBer-B) I.'IIII:LII = 6.01_-I-0.1 eV/alllU, l!.llli:lx = 2 i 51t:'I'03 eV/alllLl
AO AI A2 A3 A4 A5 A6
H(4s) -83,7360 .403599 -.495244 .O926298 .O476553 4,0421657 .00996875H(4p+4d) -91,4782 .5.13746 -,253426 ,0120434 -.0154708 -.00146OO7 .00795248H (Balmer-B) -82,9678 2.14325 -1,06498 .222304 -.0396703 -.0277369 ,0217573
Tile flt represents tile tl(4s) cross sect]on w.ltll all rills clevlatlon of 0,4%.The lllaXllllLllll deviation is i, ]% at 5, OE'I02 eV/Eulltl.
Tile flt represelltS the [l(4p+4d) cross sect]ell with all rills devlatJon of 0.3%.The lllaXilllUllldevlatlon :l.s 0.4% at 4,0E-I02 eV/allltl.
Tile /"it represents tile H(Ballller-B) cross sectloll wlt:h all rills clevlatlorl of J,6%.Tile illa×tlmlnl devlatJorl Js 2.5% at I.OE.I02 oV/alllu.
See appendlx for Chebyshev lilt cletalls,
O
' c!- :LG
H-F t-I2 -> H(4s_4-p..4d)t-1-F I-I_-> b-I_
Cr-oss _uc_lon vs. Energy ,, -17lO --"-'--- I i i " i i t-t I I .... F ..... I--l"J I IJ I 1 ........ I " 1' I--T-'I--T-IT
10-2¢ , ..i i i i i111 ..... L__A I 1 1 l l!l .... I 1 I .1 .LJ__
lO' 1¢ 1¢ 1¢Energy (eV/am u)
C-16
ATotal Spectral Line Emission Cross Sections for
H(2s) + H2 -> H(b_allan-a)
Energy Velocity CroSs Section
(ev/ainu) (c_I/s) (cm2)
7.0E+[)d 1.16E+08 1.46E-168.0E+03 1.24E+08 1.49E-169.0E+03 1.32E+08 1.50E-16I.OE+04 1.39E+08 1.49E-16I.IE+04 1.46E+08 1.48E-161.2E+04 1.52E+08 1.46E_161.3E+04 1.58E+08 1.43E-161.4E+04 1.64E+08 1.41E-16
1.5E+04 1.70E+08 1.38E-161.6E+04 1.76E+08 1.34E-161.7E+04 1.81E+08 1.3]E-]61.8E+04 1.86E+08 1.27E-161.9E+04 1.91E+08 1.23E-16
2.0E+04 1.96E+08 1.20E-162.1E+04 2.01E+08 1.16E-162.2E.04 2.06E+08 1.13Ei16
2.3E+04 2.11E+08 1.10E-162.4E+04 2.15E+08 1.07E-162.5E+04 2.20E+08 1.04E-162.6E+04 2.24E+08 1.02E-16
References: 333, 692
Accuracy: 60% ONotes: (I) These data include enllssion f_om excitation of the projectile H andfrom the dissociative excitation of H 2 (2) L_llan.-a emission occurs at awavelength of 121.57nm.
Chebyshev Fittinq Parmueters for Cross Sections
Eml n = 7.0E+03 eV/_llU, Ema x = 2.6E+04 eV/_llU
AO AI A2 A3 A4 A5 A6
-73.1370 -.183791 --.0767839 .0013061! .00262379 .00284]23 -8.70436E-05
The fit represent_ the above cross section with an rms deviation of 0.2%.The maximum deviation is 0.4% at 1.3E+04 eV/_,u.
See appendix for Chebyshev fit de_ails.
r
i ,i
C-17
H(2s) + H_ -> Ly_
'o Cross Section vs. Energy* 150.0 . I , " I _ l l I r
N
145.0 -
,\140.0 -h
135.0 -\
P. \Eo 130.0 -,._1 \ -c \
o _
Q _ 125.0 - - Recommended(1)
br) ---Data
cn 120.0 - "0 -"t_
U 110.0.115.0_- ', _- ...... Chebyshev Fit
105.0 - _.
100.0 I l ..... i J _ I l i
5.0 7.5 10.0 12.5 Ib.O 17.5 20.0 22.5 25.0 27.5
. Energy (eV/amu) ,103|
C-18
Excitation and Spectral Line Emission Cross Sections for _O
H(2s) + H2 -> H(3s)
-> H(Ballller.-_)
H(Balmer-a) H(3s)
Energy Cross Section Energy Cross Section(eVl_1_u) (cm 2) (eVl_llu) (cm 2)
5.0E+03 2.27E-17 5.0E+03 1.58E-176.0E+03 2.29E-17 6.0E+03 i_60E-]78.0E+03 2.31E-17 8.0E+03 1.64E-171.0E+04 2.32E-17 9.0E+03 I 65E-171.2E+04 2.33E-]7 1.0E+04 1 64E-17
].4E+04 2.31E-]7 1_2E+04 1 60E-171.6B+04 2.22E-17 1.4E+04 1 53E-171.8E+04 2.06E-17 1.6E+04 1 45E-172.0E+04 ].88E-]7 1.8E+04 1 36E-172.2E+04 ].75E-17 2.0E+04 I 28B-]72.4E+04 1.66E-17 2.2E+04 1.21E-172.6E+04 1.58E-]7 2.4E+04 ].]5E-17
2.6E+04 1.10E-17
Re_erence: 69]
Accuracv: 50%
_,L_tes: (I) The Ba]mer-a cross sections are determined by measuring the emission_1" A = 656.28nm from the n = 3 states of H and are related to the levelexcitation cross sections as follows: c(Ha) = 0(3s) + 0.118 0(3p) + 0(3d). The I
factor 0.118 arises from the branching ratio for decay of the 3p state. (2) Theg
0(3s) have been corrected for cascading.
Chebyshev Fittinq Par_neters for Cross Sections
H(Bal,ler-a) Emlh ' = 5.0E+03 eV/_nu, Ema x = 2 6E+04 eV/mlluH(3s) Emi,l = 5.0E+03 eV/EmlU, Ema x = 2.6E+04 eV/6mlU
AO Al A2 A3 A4 A5 A6
H (Balmer-a) -76.8150 -.162721 -.109854 -.0325036 .0085463 .0165529 .00525437 _
H(3s) -77.5541 -,175436 -.101810 -.00744771 .0115273 .00202386 -7. 45889E-05
The fit represents the H(Balmer-a) cross sectioi_ with an rms deviation of 0.5%.
The maximum deviation is 1.0% at 2.0E+04 eV/a],_u.
The fit represents the H(3s) cross Section with an rms deviation of 0.1%.The maximum deviation is 0.1% at 1.0E+04 eV/ainu.
See appendix for Chebyshev fit details.
rf
C-19
0H(2s) + H_ -> H(3s)
H(2s) + _2 -> H_
Cross Section vs. EnergyOt"--
24,0 I I I i
22.0 -
A = I-I_
X = H(3s)\\
20,0 - _ -
ht)
18.O - '_ -
,(_) '-4"-' _' , Recommended
0 ¢_ " Data
cn 16.0(/')' ,,
O '_'"_X\ ...... Chebyshev Fit
, U "x
14.0 -
12.0 -
10,O ....... l_ J j I
5.0 10.0 15,0 20.0 25.0 30,0
Energy (eV/omu) •103
J
C-20
Spectral Line Emission Cross Sections for
H(2s) + He -> H(L_llarl-_)
Energy Velocity Cross( Section(eVl_.u) (orals) c,.2)
1 0E+04 1.39E+08 1.86E-17
I.IE+04 1.46E+08 1.75E-171.2E+04 ].52E+08 1.65E-17
1.3E+04 1.58E+08 1.56E-171,4E+04 I,64E+08 1.48E-171.5E+04 1.70E+08 1.46E-171.6E.04 1,76E+08 1.43E-171.7E+04 1.81E+08 1.41E,-17],8E.04 1.86E+08 1.37E-]71.9E+04 1 91E+08 1.32E-172.0E+04 1 96E+08 1.28E-172.1E+04 2 01E+08 ].24E-172.2E+04 2 06E+08 1.22E-172.3E+04 2 lIE+08 1.20E-172.4E+04 2 15E+08 1.19E-17
2.5E+04 2._0E+08 1.19E-172.6E+04 2.24E+08 1.18E-17
Referencez 333
A.._ccurac Y : 80%
Note: The H Llanan-a radiation is at a wavelength of 12].57,],i.
0Chebgshev Fittinq Par_ueters for Cross Sections
Eml n = 1.0E+04 eV/aauu, Ema x = 2,6E+04 eV/muu
AO AI A2 A3 A4 A5 A6
-77.5542 -.232829 .0249886 _.00284785 .0873114 .0106037 -.00679600
The fit represents tile above cross section with an rms deviation of 0.5%.The maximum deviation is 1,2% at 1.4E+04 eV/_llu.
See appeI_.dix for Chebyshev fit details.
C-21
H(2s) + He .-> H(Ly_)
i/
-_ " Cross Section vs. EnergylO ' / ' ,."-- 19.0 r, i i I i 1
18.0 _,
_ A - Ly_
17.0
_E 16.o -
c-O
o 15.0 - _ Recommended
¢) DataOr) ,
0 14.0 - _', -g ..... Chebyshev Fit
xN
13:0 - \\N
12.0
11,0 ...... J J 1 I ............... L - i
10.0 12.5 15.0 17.5 20.0 22.5 25.0 27.5
Energy (eV/brnu) • 103
C-22
AExoitation and Spectral bine EllliL_Slot] Crc_s Sent J_1]_ For
H(2s) + He -> H(3s)-> II(13ai111c_-_,)
H( 3 s ) It ( Ba hue r-L., )
Energy Cross Section glle1:gy Cross Section(eV /anlu) (Clll2 ) (eV /alULI) (ClII;)
5.0E+03 7 05E-18 5.0P,+03 1.15E-176.0_+03 6 62E-18 6.0E+03 1.lIE-178.0B+03 5 95E-]8 8. OE-103 1.04E-171.0E+04 5 53E-]8 ].OE+04 9.86E-]81.2E+04 5 21E-18 1.2E+04 9.35E-18].4B+04 5 O5E-18 1.4E+O4 8.97E-18I. 6E+04 4.95E-18 I. 6E+04 8.66E-18
1.8E+04 4.83 P,--18 ]. 8E4 04 8.37E-182.0E+04 4.67B-18 2.0E+04 8.13E-182.2E+04 4 .44E-18 2.2E+04 7 •87E-182.4E+04 4.23E-18 2.41'_-104 7 •64E-182.6E+04 4.07E-18 2.6F_404 7 .42E-18
Reference : 691
Accuracy: 50%
Notesz (1) The Balnler-a emission cross section Js given by 0(3 s) + 0.118 o(3p)
+ o(3d). Tile factor 0.118 is to correct f,,r the branching ratio of the 3p state.
(2) The o(3s) has been corrected for cascadil]cj. (3) The Ballller-c, radiatiol] is
at a wavelength of 656.28nm. I
ChebJshev fittlnq Par6uueters for Cross Sections
Ii(3S) Emi n = 5.0_'+03 eV/_llU, = 2 6E+04 eV/alllUH (Balmer-a ) Bmi n 5.0E+03 eV/6mlu Ema× '= , Enlax = 2.6E+04 eV/_uu
AO Al A2 A3 A4 A5 A6
H(3_) -79.5230 -.258972 7. 15363E-O4 -.0165922 -.0141266 -2.93267E-04 .00596856
H( BalI, er-_) -78.4151 -.218179 -.0140659 2. I0927E-05 -.00210701 -.00118313 3. 35892E-0_,
The fit represents the H(3s) cross section with at] r.us deviation of 0.3%.The maximum deviation is 0.5% at 8.0E+03 eV/_llu.
,
The fit represents the H(Balmer-a) cross section with at] rms deviation of 0.:[%.The maxinlum deviation is 0.1% at 8.0E+03 eV/nrel.
See appendix for Chebyshev fit details.
O
C-23
0H(2s) + He -> H.
H(2s) -F He --> H(._s)
__,_,.,_Cn-)q_c- ., c,ection vs, Fnergyo
12,0 i _ i l
11.0
X a=H_x = H(3s)
I0,0 - '_\
E 9.0 -- \\ -o ".....
,o_c) 8,0 - Recommended
...... DataCO6O© ,_- 7,0 -
u I\ Chebyshev Fit
6.0 _ X
5.o - "_-.._..
4,0 l 1 I _I'_<
5.0 10.0 15.0 20,0 25.0 30,0
Energy (eV/ainu) •10a
(?-24
Spec_t ra1. I.,I ne Ellli aB J.Oll Cross Sect:J Oils .for
H + He -> I-I(t, ynuan-.)
Erie, rgy , Ve].ot'..t t y Cross 8_ct t.on( eV/anlu ) ( clu/s ) (eta")
3, OE-F.O1 7,6 ].l_,>i-O6 I, O1E- 1 "l4,0t_;+ 0 .1 8 79 _;-t,06 2.4 :t t_- ].17,0E+01 1 16E+07 4.]5E-171,0E4,02 ] 39E-}07 5,23E-172,0E+02 ] 96E4-O7 6,6513-17.
. 4.0E+02 2 78E4-O ? 6.96E-177.0E+02 3 68E-t-O1 6.90F,-]71,0E+03 4 .39E-t07 6.58E-1"I2,0I']4'03 6 21E4.07 5.61E-177,0E+03 1 16E+08 2.63E-]71.0E+04 1 39E.t-O8 1.95g-17
2,0E+04 1 96E+08 1.OOE-174.0E+04 2 78[_408 4.40F_-187, OB+04 3.68E+08 ]. 90E-189.0E4.O4 4.17E.I.08 i. 26E- 18
References1 46, 639, 643, 644, 645, 651
80P
Note___.._lTile /,_qllan-_ ellllssiol] at: 121,611111 illcludes Slllall contributiolls due to
cascade fronl tile n = 3 arid hlgller levels.
OClLebyshev Flttinq ..Par_mJ.!eter_s for Cross sections
Emi n = 3.0E+O1 eV/ainu, Ema x =' 9.OE-t-04 eV/_llu
AO AI A2 A3 A4 A5 A6
-77.2423 -I 27626 -1.33104 .105602 -. 131109 .090]017 -.0744630
The fit represents the above cross sect:ions with an rms deviation of 3.8%.Tile Illaxillltllll deviat loll 'J.S 5.8% at 3. OE+O] eV/edlltl.
See appendix for Chebyshev flt del:ai is.d
O
C-25
eH + He -> H(Lyman)
i
CirossSection vs. Energy•_p. -16IU ----m-1--r-'r-rz'rm-- , , r _ , , _,l ' , ...._m"rn_r-----"r--r-_ , , ,,,
i I , \
,--., \
E \
C©
,10-17 RecommendedDataV)
C8
L) __ _ Chebyshev Fit
10 -la _ ; " _._ I J i ,lJlll I i,_ J i J Ijii,
ld 10_ 103 1¢ 10sEnergy (eV/am u)
b
C,-2 6i
Spectra] blne _III:I.SEt.Loll Rate Coe_f[:l.u].ell|-S [oi."
H + Fie -> II (L,ylllall-c,)
Magwe11.| an -- Maxw_.ll]i_in Rate Cc]_ff:l.c,_c:_nts (Clll'_/s)
II
TslOp, Eqtla 1 fls TSlllp, (sV)
(eV) Tsmp, I0, I00, 500, 1000. 5000. 10000, 20000,
1.0E.OI 4 37E-II _ 4,37E-II A 3,O3E-IO 1.IOE-09 1 64E-09 2,86E-09 3 02E-O9 2,85E-09
2,0EtOl I 86E-I0 _ 1,56E-I0' 4,13E-I0 1,15E-O9 I 67E-09 2.87E-09 30,qE-O9 2:85E-09
4,0E+OI 4 64E-I0 3,86E-I0 6,O6E-I0 1,26E-O9 i 74E-09 2,87E-09 3 O2E-O9 2.85E-O9
6,0El01 6 92E-I0 5,84E-I0 7,71E-I0 1.35E-O9 I 80E-09 2.88E-09 3 O2E-O9 2 85E-09
8,0E_OI 8 80E-I0 7,52E-10 9,14E.I0 ].44E-O9 [ BSE-09 2,09E-O9 3 O2E-O9 2 84E-09
I,OE_O2 1 04E-09 8.97E-I0 1.04E-09 1,51E-O9 I qlE-Og 2.89E-O9 3 02E-O9 2 B4E-Og
2,0E*O2 I 61E-09 1,43E-09 [.51E-39 I,B4E-O9 2 lJE-Og 2.92E-Og 30IE-O9 2 B3E-O9
4,0E.02 2 22E-09 2,03E-09 2,O8E-09 2,26E-O9 2 44E-09 2,96E-09 3 OIE-O9 2 BIE-09
0.0E+02 2 55E-09 2,38E,-09 2,41E-09 2,53E-O9 2 64E-Og 2,99E-09 3 OOE-O9 2 8OE-09
B,OE+02 2 74E-O9 2,60E-09 2.62E-09 2,69E-O9 2 77E-09 3,0OE-09 2 99E-09 2 70E-09
I,OE+03 2 86E-09 2,74E-09 2,75E-09 2,81E-O9 2 86E-09 3,OIE-09 2 9[IE-O9 2 76E-09
2,0E+03 3 02E-09 3.00E-09 3,00E-09 3,01E-O9 3.01E-09 2,99E-09 2 90E-O9 2 67E-09
4.OEtO3 2 85E-09 2,94E-09 2,94E-09 _,93E-O9 2 g2E-D9 2,83E..09 2 "21E-O9 2 50E-09
6,0E_03 2 6_E-09 2,76E-09 2,76E-09 2,75E-O9 2 74E-09 2,64E-09 2 54E-O9 2 34E-09
8,0E+03 2,42E-09 2,58E-09 2,58E-09 2.57E-O9 2 56E-09 2,47E-09 2 38E-09 2 20E-09
1.CE+04 2,24E-09 2,42E-O9 2,41E-09 2,41E-O9 2 4OE-09 2,32E-O9 2 24E-O9 20flE-09
1,5E+04 1.88E-09 2,08E-09 2,O8E-09 2,O7E-09 2 07E-09 2.OIE-09 I 94E-O9 I 82E-09
.,'_CE+04 1 ,61E-09 I ,82E-09 1,82E-09 1 .81E-O9 I BIE-09 I ,76E-O9 1 .71E-O9 I 61E-09
Accuracyt * - PosF11ble Erro_ Greater Tl,an 10%
- Possible Error G reatel:' Tllall 1.00% O
Chebyshev Fittinq Parmueters for Rate Coefficients
EIIIJ.I1 = I.OE,IO] eV, Enlax = 2.0E+04 eV
Hs
TBmp.
(SV) AO AI A2 A3 A4 A5 A6
i0, -41,8408 1.73512 -1,00696 .107279 -.05"16945 ,0226348 -.00478217
IO0_ -4],O3'19 1.O3224 -.535100 -.134058 .0352264 -.00215004 -.00222457
500, -40.2599 .410395 -,247167 -,176225 .O0337909 ,01"17532 -.00518240
IOOO. -39,9551 .185465 -.18_562 -,151177 -.0159001 ,O155346 -I,77904E-O4
5000. -39,4938 -,156752 -.142409 -,0847522 -.0277793 -,00101284 ,002833|5
iO000, -39.4782 -.210389 -.141402 -,0104827 -._240167 -,00386296 B,g4493E-04
20000, -39,6096 -.2111997 -.135741 -.0627840 --.O213979 -,00486653 -.4.40643E-O4
Equal Temp. -41.7630 1,61688 -1.O6969 ,]47665 -.0861736 ,O380393 -.0145355
See ,]ppendlx for Chebyshev fit deLa_ls.
C-27
H + He -> H(Lyman )
M,zl:.:wellion- Maxwellian
810- _---I I w Illlll ....I t"11/,lWl I.... i I IIIII I.... I'-l I_lll_
- - He Temp,
- - (eV)
n --10,
!r '' ' i,t ,
C- 2 8
ASpect ral l.,ille EillissJ.Oll Rate Ck)el fit]ietlt's for _i_
l-lo .l H -> lie .I H (bylllall-cl)
•q ] .Bemll - Maxwol.1,.lall RaLe (,[el:fic'IOllt8 ([_lll:I/s)
H
Temp, lie l.,',llorgy (eV/alnu
(sV) I0000, 20000, 30000, 40000, 50000, 60000, 70000,
I oE_OO 2,68E-09 %,96E-09 1 49E-09 1,22F,-09 9,78E-_0 fl,15E-10 6,gBE-|O
2 OECD0 2,68E-09 1,96E-09 I 49E-09 1,22E-09 9,TilE-lO 8,15E-10 6,98E-I0
40E+O0 2,68E-09 _,96E-09 I 49E-09 1,22E-09 9,78E-I0 8.15E-10 6,98|_-_0
70E+O0 2,68E-09 1,96E-09 I 49E-09 I 22E-09 9,78E-I0 8,15E-I0 6,97E-I0
I OE_O_ 2,68E-09 1,96E-09 I 49E-09 I 22E-09 9,78E-|0 8,I5E-I0 6.97E-I0
20E+OI 2.68E-09 1,96E-09 i 49E-09 I 22E-09 9,78E-I0 8,15E-I0 6,97E-I0
40E+OI 2,68E-09 1,95E-09 I 49E-09 ] 22E-09 9,78E-I0 8,15_-I0 6,,qTE-10
70E.01 2,67E-09 1,95E-09 I 49E-09 I 21E-09 9,'/8E-,I0 8,15E-I0 6,9GE-tO
10E+02 2,67E-09 1,95E-09 I 49E-09 I 21E-09 9,79E-I0 8,|5E-|0 6,96E-I0
2,0E_O2 2.B6E-09 1,94E-09 1,49E-09 I 21E-09 9,[_0E-_0 8,16E-I0 6 95E-_0
4,0E_02 2,64E-09 1,93E_,09 1,49E-09 I 20E-09 9,81_-I0 8,17E-I0 6 90E-10
7,0E+02 2,61E-08 1,92E-09 1,49E-09 I 20E-09 9,81E-I0 8,17E-I0 ' 6 74E-I0
1.0_.03 2.58E-09 [,91E-09 I,48E-09 1 20E-09 9,80E-I0 8,13E-I0 6 58E-I0
2,0E_03 2,49E-09 l' 88E-09 1,47E-09 I 19E-09 9, /3E-lO 7,92E-I0 6 1BE-lO'
4,0E+O3 2,32F,-08 ],81E-09 1,44E-09 I 16E-09 9,43E-10 7,53E-I0 A 5 81E-I0'
7,0E,_03 2,12E-09 1,70E-O9 1,37E-09 I ,lIE-09 8,98E-I0 7,15F.-I0 _ 5 59E-I0_
,I,OEr04 I,96E-09 I, 59E-09 I, 30E-09 _ 1,06E-09 8,60E-10 _ 6,90E-I0 _ 5 47E-I0'
2,0E+04 1.53E-09 l. 29E-09 I,08E-09 _ 9,04E-I0 _ 7,54E-I0' 6.26E-I0 j 5 1BE-lO A
,Accuracyz * - Possibl.e Error Oreat.er Than 10%
- Possible Error Oreat:er Than 100% O
Chebyshev Fi_ttir_._{.....Par_.mleters fo_ Rate Coefficients
E_M n = ].OE+O0 eV, Ell_ax = 2.0E+04 eV
He
Energy
(eV/ainu) AO AI A2 A3 A4 A5 A6
10000 -39,6987 -.197802 -.134319 -,0723203 -,O304433 -,00974030 -,00251684
20000 -40,2569 -°138429 -..0956246 -.0581643 - 0310565 -,0136698 -,00449523
30000 ,.40,7530 -,0951522 -,0755129 -,0512811 - 0288118 -,013029'I -,00477600
40000 -41,1570 -, 0957055 -,0666225 -.0426726 - 0248045 -,0119141 -,00390059
50000 -41,5800 -°0821883 -.,0654040 -,0420679 - 0203976 -,00620683 2,45851E-06
60000 -41.964'I -,0972904 -.0701222 -,0364437 - 0102495 ,00215119 ,00335_03
70000 -42,3333 -.139674 ...0746309 -.0176390 00996598 ,0106575 -8,59901E-05
See appendJ.x for CI]ebyshev fit detail,';.
IIH + He -> H(Lyman )
C-30
QExcitation Cross Sections for
H + He -> H(2s,2p)
H(2s) H[2p)
Energy Cross Section Energy Cross Section(eV/a_lu ) (cm 2 ) (eV/m11u ) (cm 2)
6. OE+OI 1.43E-18 2. OE+01 1.87E-187. OE+OI i. 81E-18 4. OE+OI 2.36E-17I. OE+02 3.04E-18 7. OE+OI 4.33E-172.0E+02 6,70E-18 1.0E+02 5.22E-174. OE+02 i. fOE-17 2. OE+02 6.08E-]77. OE+02 i. 29E-17 4.0E+02 6.30E-178.6E+02 I. 31E-17 7.0E+02 6. IIE-17i. OE+03 !. 30E-17 I. OE+03 5o81E-]72. OE+03 1. IOE-17 2. OE+03 5.16E-174. OE+03 8.41E-18 4. OE+03 3.73E-177. OE+03 6:54E-18 7.0E+03 2.58E-17i. OE+04 5.51E-18 1. OE+04 !. 95E-172. OE+04 4.15E-18 2.0E+04 i. OIE-174. OE+04 3.64E-18 4.0E+04 5.16E-187. OE+04 2.67E-18 7.0E+04 4.52E-18I. OE+05 2.04E-18 1. OE+05 4.41E-18i. 4E+05 i. 59E-18
References: 46, 639, 640, 641, 642, 643, 644, 645, 646, 648, 650
Accuracy: 50% ONotes: (i) Excitation of an excited state is found by measuring theemission from that state and correcting for cascades into that state. (2)The 2s state cross sections are found from the electric-field-induced
transition (2s -> 2p -> IS). (3) If cascading is neglected the L_al_an-a
emission cross sections are equal to the 2p excitation cross sections.
Chebyshev Fittinq Parmueters for Cross Sections
H(2s) Eml n = 6.0E+OI eV/_,u, Ema x = 1.4E+O5 eV/_uuH(2p) Eml n = 2.0E+OI eV/_11u, Ema x = 1.0E+05 eV/_11u
AO A1 A2 A3 A4 A5 A6
H(2s) -80.0462 -.212388 -.933176 .333291 -.0922211 -.0813910 .00473762H(2p) -77.4567 -.447338 -1.40980 .577607 -.164863 .291318 -.0758830
The fit represents tlle H(2s) cross section wit]] an rms deviation of 2.2%.The maximum deviation is 4.3% at 1.0E+05 eVainu.
The fit represents the H(2p) cross section with a,] rms deviation of 3.8%.The nlaximum deviation is 6.9% at 4.0E+04 eV/ainu.
See appendix for Chebyshev fit details.
C-31
0_.-)H + He -> blc.__s,2pJ
Cr-oss oec:tlon vs. Fnergy-16
l0 I I I Illlll. I I I Illlll I "i I Iwllll 'l' I i'rTnTT'----'l i i lllrr
zx - H(2p)
_ \,
x - H(2s)
I"N
i_ '_ 10-'7 // "x X DeteRec°mmended
O //// \\ _ C hebyshev Fit
(,-9 \\_,\
\X,\
10' 102 103 104 105 106Energy (eV/mm u)
,,
C-32
Excitat _on Cross Sections for D
H 4 11e -> H(3s,3p,3d)-,> 14(3D-t.3d)
H(3B) H(3p) H(3d) H(3p+3d)
Energy o Energy o Erie rgy o Energy o
(eV / anlu ) ( c1112) ( eV/ainu ) ( cm 2 ) ( eV / _llt| ) (cm 2) ( eV/ainu ) (cm 2 )
1o 5E+02 1.oog-18 5.0E+03 2.41E-18 :1..og+o4 1.20E-!8 :1.5E+02 2.54g-182.0E+02 1.84E-18 5.5E+03 2.33E-18 1.3E+04 1.05E-18 2.0E402 3.28E-18
4.0E+02 4.18E-18 6.0E+03 2.25E-18 ]. 5E+04 8.64E-19 3.0E+02 4.24E-]86.0E+02 4.64E-18 7.0E+03 2.08E-18 2.0E+04 5.96E-19 4.0E+02 4.41E-]87.0E+02 4.57E-18 8.0E+03 1.94E-]8 2.5E+04 4.88E-19 5.0E+02 4.33E-18I.OE+03 3.99E-18 9.0E+03 )..82E-18 3.0E{04 4.48E-19 6.0E+02 4.26E-182.0E+03 2.74E-18 I. 5E+04 I. 38E-18 3.5E+O4 4.41E-19 7.0E+02 4.]7E-184.0E+03 i. 90E-18 2. OE+O_ 1.15E-18 8. OE+02 4.08E-187.0E+03 1.46E-18 2.5E+04 1.02E-18 9.0E+02 4.02E-]81.0B+04 i. 26E-18 3.0B+04 9.31E-19 !.OB+03 3.95E--18
2.0E+04 9.39E-19 3.5E+04 8.75E-]9 ]. 5E+03 3.70E-]83.5E+04 7.98E-19 4.0E+04 8.40E-19 2.0E+03 3.50E-18
2.5E+03 3.36E-18
References: 500, 601, 645
Accuracy: See notes
Notes: (i ) The excitation cross section is found by nleasurillg the ellllssioncross section from that state and correcting for cascade from measurements orusing known transition probabilities. (2) Excitation cross sections are ofteninaccurate due to problems with tl_e absolute calibration of the photondetector.
Chebyshev Fittinq P_r_ueters for Cross Sections
H(3B) gmi n = ].5E+02 eV/_mm, ._lllax= 3.5E+04 eV/ainuH(3p) Emi n = 5.0E+03 eV/ainu, Ema x = 4.0E+04 eV/ainu
H(3d) Emi n = 1.0E+04 eV/6m_u, Ema x = 3.5E+04 eV/_um.lli(3p+3d) Eml n = ].5E+02 eV/a]uu, Zmax = 2.5E+03 eV/_lu
AO A1 A2 A3 A4 A5 " A6
H(3s) -81.8143 -.503310 -.548175 .379377 -.]31005 .0123345 .0265299H(3p) -82.1981 -.551194 .0027572] .0217903 .00543228 .00224727 -.00356334
H(3d) -83.6281 558730 .0544644 .0648205 -.0102811 .00660745 .00511818H(3p+3d) -80.3437 .0712330 -.]98360 .0790347 -.0161614 -.00946588 .012113]
The fit represents the H(3s) CROSS sect ion with an rnls deviation of 0.5%.The maximum deviation is 1.1% at 1.0E+03 eV/6uuu.
The fit represents the H(3p) cross section with an rms deviation of 0.2%.
The maximum deviation is 0.5% at 2.0E+04 eV/ainu, l-=
The fit represents the H(3d) cross section with an rms deviation of 0.0%.The ma×imum deviation is 0.0% at 2.0E+04 eV/ainu.
The fit represents the H(3p+3d) cross section with an rms cleviation of 0.3%.The maximum deviation is 0.7% at 5.0E+02 e_/mml.
See appendix for Chebysllev fit details. W
C-3 3
0H + He > H(.3s,3d,3p>H + He -> H(3p+3d)
Cross Section vs. Ener9/-17
IU "' '' ' ' '"'_,,'i" ' ' ' ' ' '''I' , ",', '_, ,,r
- A -- H(3p+3d)
X - H(3p)
_#- H(3s)
k\_ = H(3d)
g'_ 10-le RecommendedL,'_ Data
_ \
8 -U - _,.., Chebyshev Fit
10-1£ . i i i i 1 lilt 1 i 1 i I llll i i i i l iii
102 10' 104 105Energy (eV/am@
C-34
. iiSpectral Line Emissiorl Cross Sections for
H + He -> H(Ba]mer-a,Balmer-B)
H (Balmer-c, ) H (13alnler-_l)
Energy Cross Section EJ ergy Cross Section( eV / a]llu ) ( cnl 2) ( eV/anlu ) (Clll 2 )
3.OB+01 5.35E-.20 4.0E+01 2.19E-204. OE+01 2.73E-]9 7. OE+OI 8.68Z-207.0E+0I 9.03E-19 I. OE+02 1.5]E-19
I. 0E+02 ]. 36E-18 i. 5E+02 4.00E.- 19I. 5E+02 3.47E- 18 2. OE+O2 7. ]9[,.:-192. OE+02 5. lIE-18 4 o0E402 1.88E- 184.0E+02 8.99E- ]8 7. OE+02 2.28E-185. OE+02 9.14E- 18 ]. 0E+03 2.17E-]87.0E+02 8.77E-18 2.0E+03 i. 73E-18i 0E+03 7.86E_18 2.5E+03 1.60E-182 0E403 6.22E-18
4 0E+03 4.55E-]870E+03 3.35E-18i OE+04 2.72E-182 0E+04 1.64E-]8
3. OE+04 I. 39E-I[83.5E+04 i. 35E-18
References: 500, 601
Accuracy: 50% ONotes : (1 ) The Balnler-a wavelength is 656.3nnl and the Balmer-H wavelength i s
486.1nni. (2) These cross sections are for the total line enliss]on includingcascade contributions and branching corrections. Balmer-a cross sections are the
sum of o(3s) + 0.118 o(3p) + o(4D) where tile factor 0.118 is the fraction of tlle
3p sl ate decaying by Balnler-a radiation. Ba]mer-H enlission cross sections are
for the n=4->2 transitions with the branching ratio of tile 4s to 3p transitiollbeing 0.584.
Cl.]ebyshev Fittinq Parameters for Cross Sections
H(Baliller-_) Emin = 3.0E+01 eV/ainu, Eluax = 3.5E+04 evl_mlu
H(Balnler-19) Enlin : 4.0E+01 eV/_uu, Eluax : 2.5E+03 eV/anlu
AO AI A2 A3 A4 A5 A6
H (Bahller-_) -81.8706 .929497 -1.66225 .554407 ,-.0518605 .00374127 -.0418064
H (Balmer-F]) -84.3982 2.15229 -.976804 -.0709]]4 .119448 .0571307 -.0675516
The fit: represents the H(Bahuer-c_) cross section with ail rms deviation oi 13.9%.
The maximum deviation is 35,9% at ].0E+02 eV/rural.
The fit represents the H (Balmer-f#) ci:oss sectioll with al] rills deviat loll of 3.6%.The maximum deviatiol] is 8. 7% al. l.OEi02 eV/6uml.
See appendix for ChebYshev fit details. I
C-3 5
0H + He > H_, H_
Crc-_ss"Section vs. Ener-gy-17Iz-'_
IU L ' '"'''", , ' ,,,,,,I , ', ,,,,m- ,---7---r--r-r-fTFr].f -- - 1
- / \/ ',
- / zx=H_
/,, "_
i0-_ _ /-" II!
_E - /'
0 +-'@o / / -_ DataRecommendedV)O0(./3o
U _9 ..... Chebyshev Fit10-
10-2< J J _J_lil ....l I IIIIIII I I IIiI|[.L.__Li I llill
ld ld 103 104 10sEnergy (eV/amu)
C-36
EXC.lt at loll Cross Sections [or O
H _ He -> H(4s,4p+4d)
H (4s) H(4p+4c.I)
Energy Cross Section Energy Cross Section(eV /allu) (cm 2) (eV/ainu ) (clu2)
i. 5E+O2 i. 30E-19 i. 51_LO2 3. O7E-192. OE+O2 2.60E-19 2. OE _O2 5.35E-]93. OE+O2 4.77E-19 3. OE _O2 i. O6E-184. OE+O2 6.75E.-19 4. OE_O2 1.30E-185. OE+02 8.10E-19 5.0fi]+O2 ]. 37E-186. OE+02 8 78E-19 6.0E+O2 1.38E-186.4E+02 8 79E-19 7.0E+O2 1.37E-187.0E+02 8 72E-19 8.0E+O2 ].35E-188. OE+O2 8 40E-19 9.0E+O2 1.33E-189. OE+02 7 99E-19 1.0E+03 1.31E-18I.OE+03 7 56E-19 1.5E+O3 1.23E-181.5E+03 6 06E-19 2.0E+O3 1. 19E-182.0E+O3 5 21E-19 2.5E+O3 1.16E-182.5E+03 4 62E-19
Reference: 601
Accurac Z: 50%
Notes: (I) As far as we are aware only or,e measurement has been made of then = 4 excited state formation. Thtls, the stated accuracy only includesaccountable errors. (2) These data have ignored a11y cascade contrlbutiol]s.
Chebyshev Fittinq Parml_ete[ _ for Cross Sections
H(4s) Elllin = ].SE+U2 eV/6ullu, Elllax = 2.5E+O3 eV/6ulluH(4p+4d) Eml n = ].5E+02 eV/ainu, Ema x = 2.5E+03 eV/_ml
AO A1 A2 A3 A4 A5 A6
H(4s) -84.5175 .519837 -.602123 .107056 .0399676 .00471154 -.0330016
H(4p+4d) -83.0777 .537485 -.440970 .159743 -.00409905 -.0305454 .0217549
The fit represents the H(4s) cross section with an rms deviation of O.7%.The maximum deviation is 1.3% at 2.0E+03 eV/6mlu.
The fit represents the H(4p-_4d) cross section w itll an rms deviation of 0.6%.The maximum deviation is ].]% at ].5_]+O3 eV/_lu.
See appendix £or Chebyshev fit details.
L'_-..3 7
0H + He :> H(4s,4-p+4d)
Cross Section vsoEnergy-17
10 I I ' I' I '1' I I' I J I I I I " I ! 1 I
- H(4p+4d)
x - H(4s)
8L.)
.0 ,_.
_i_ uo@i._ 10-'e-- / .. -._._--_.., _ _._ ' DataRecommended0 "
1_ ...... Chebyshev Fit
//'/
1910 ' l J l , J , _ _t J l__.x.__x_.x_11.1
102 103 104Energy (eV/a m u)
C-38 ,
Excitat ioi_ Cross SeCtions for
H + He -> He(31P,31P,33D)
lle(3'P) He(3_p) He(33D)
Eriergy a El]ergy _ Ene rgy . o
(eV/_11u ) (cll|2) (eV /6ullu) (cnla) (eV /alllu) cnl_),,
1.0E+04 5 60E-20 I.OE+O4 9.67E-]9 I.OE+04 1.60E-19I. 3E+04 ]. 16E_19 i. 3E+04 ]. 16E-18 1.3E+04 2.19E-19i. 5E+04 i. 79E-19 i. 5E404 I. ]8E-18 ].4E+04 2.37E-19
] .8E+04 2.19E-19 1.8E+04 1.04E-18 ],5E+04 2.32E-192. OE+04 2.53E'- 19 2. OE+04 8.64E-19 1.8E+04 i. 95E-19
2.3E+04 2.83E- !9 2.3E+04 7.19E-I 9 2. OE+O_ i. 62E-192.5E+04 3.14E-19 2.5E+04 5.93E-]9 2,3E+04 i. 37E-192.8E+04 3.46E-19 2.8E+04 4.92E-19 2.5E4-04 i. 17E-193.0E+04 3.75E-19 3.0E+04 4.07E-19 2.8E+04 ] .OOE-19
3,3E+04 4.01E-]9 3.3E+04 3.33E-]9 3. OE+04 8.62E-203.5E+04 4.29E-19 3.5E+04 2.72E-19 3.3E+04 7.57E-20
3.5E+O4 6.86E-20
References' 166, 678, 683, 684
Accuracy : Ux]kt]owll ,
Notes!. (]) Only one absolute tueasurement of cross sections for eKcitation oft_ese states has been made. See l Van Eck et al. (Ref. 678). Tl_ese data havebeeu corrected in the review papers of de Fleer (Ref. 166) and Thomas (Ref,684). The Corrected values are probably too low by a factor of 2-3.
Chebyshev Fittinq Parmueters for Cross sections
He(3tP) Eml n = I.OE+04 eV/ainu, Ema x = 3.5E+O4 eV/ainu
He(3"_P) Emi n = ].OE+04 eV/ainu, F.max = 3.5E+04 eV/6uuu
He(33D) EnH n = I.OE+O4 eV/6uuu, Ema × = 3.5E+04 eV/6uuu
AO A1 A2 A3 A4 A5 A6
He(3tP) -86.1894 .957985 -.222479 .0796768 --.00575983 -.0]94864 .0]2]076
He(33P) -83.6070 -.654163 -.317139 .O375222 -3. 81314E-O4 _ ,0176396 .00667369
He(33D) -86.8654 -.503446 -.290764 .103755 -.00276954 -.0224516 .0247251
The fit represents the He(3_P) cross section With an rms devlatio,_ of 0.3%.
The maximum deviation is 0.6% at 1.8E+04 eV/ainu.
The fit represents the He(3_P) cross section with an rms deviation of O.2%.The maximum deviation is 0.3% at 2.0E+04 eV/6uuu.
The fit represents the He(33D) cross section with all rlllS devJatlon of 0.4%,
The maximum deviation is 0.8% at 1.8E+04 eV/smlu.
!
See appendt× for Chebyshev fit: details.
O
", c-.'39
QH . He -> He(3'P,33P,33D)
(3_, _ . . ,'o Ct-,-,ssSection vs. F-nen]y_- 12,0
l:l'" , Z.#.._.LI I "l '1"_ I wI l-' i I _ -T-T-T'T-
. /I
10.0 - '/A -- He(3'p)
X - H(33p)
£7- H(33D)
8;0 -6'4
, ,
ov
C0
_ 6.0 - Recommended
_Dotabr)u3(ac)Ok_
U Chebyshev Fit4,0 -
2,0 -
0,0 -- l I j I l
5.0 10.0 15.0 20.0 2.5.0 30.0 35.0Energy (eV/omu) ,103
C-4 0
' _xcit ation Cross Sections [or O
4*H 4 He --> He(41S, P,41D)
He(41S) He( 41 P) lle(411))
Energy o Energy o Energy o
(eV/_llu ) (cil_' (eV/alltl) (till_") (eV/6ul|u) (cn__)
i. OE+04 2.87E-19 I, OE+04 6 19E-20 i. OE+04 5.34E-201.5E+04 3.64E-19 ].3E+04 I 30E-19 .1.5E-I04 8.41E-202.0E+04 4.09E-19 ].5E+04 I 92E-]9 2.0E+04 9.12[,/-202.5EFO4 4,34E-19 2,0E404 3 03E-19 2.5E+04 8.01E-203.0E+04 4.34E-19 2.5E-t04 3 80E-19 3.0E+04 7.68E-203.5E+04 4.27E-19 3.0E+04 4 48E-19 3.0E+04 7.72E-204.0E+04 4.08E-19 3.5E+04 5 13E-19 3.'1E+04 8.87E-20
4.5E+04 3.88E-19 4.0E+04 8.79E-205. OE+O4 3.68E-]9 4.5E+04 8.51E-205,5E+04 3.5lE-19 5. OE+04 8.48E-206. OE+O4 3,33E-19 5.5E+04 8.24E-206,5E+04 3.10E-19 60E+04 7.83E-207.OE+04 2.81E-19 6 5E+04 7.27E-207.5E+04 2.48E-19 70E+04 6.66E-208.0E+04 2.20E-19 7 5E+04 6.28E-,20
8.5E+04 ].97E 19 80E+04 6.OOE-209. OE+O4 i. 80E-19 8 5E+04 5.81E-20
9.5E+O4 ] .69E-19 90E+04 5.62E-20 _I,OE+05 1.61E-19 9 5E+04 5.47E-20
l OE+05 5.34E-20
Referellces : 166, 677, 678, 679, 684
Accuraczi E > 2xlO 3 eV/_ml - 40% IE < 2xlO 3 eV/_llU - Ullknown
Notes z (]) The, data have been obtained by measuring the line emissions for the
following transitions: (a) 41S -> 22p, 504.7nm, (b) 42D -> 22p, 492.2nm, (c)42P -> 22S, 396.5nm. (2) The cross section data have been corrected for uascaciesusing known transition probabilitles. (3) The corrected data of Van Eck et al.
(Ref. 678) - (see corrections of de Heer Ref. 166 alld Thomas Ref. 684) havebeen normalized to the data of Blair et al. (Ref. 677) at 2xlO 3 eV/mm_ for the42S and 42D states.
CJlebyshev Fittinq Par6mleters for Cross Sections
He (41S ) EII_In = 1. OE+04 eV/a]lltl, Enlax ::: I. OE+05 ev/allltlHe(41P) EMi n = I.OE+04 eV/6mlu, Ema x = 3.5E+04 eV/D]uu
He (41D) Enlin = I.OE+04 eV/anltl, Ema x = i. OE+05 eV/alllU
AO Al A2 A3 A4 A5 A6
He(4*S) -85.2953 -.236370 -.3755'70 -.0526312 .1.43777E-()4 -.00898368 .0314058
He(4*P) -85.8813 .991657 -.212955 .0558510 -,009001]6 ,00987058 -.00878]02
He(4_D) -88.1942 -.0703862 -.233023 .0274405 -.06]6908 .0587687 .028'7005
The fit represents tile He(4*S) cross sectloll with all rms deviation of 1.7%,
The maximum deviatloll is 2.7% at 5.0E-_04 eV/allh,l.
The fit representt_ the He(4 Ip) cross section w]tll an rms deviatlon of. 0 ]%.The maximum deviation is 5.0% at 1.2E+04 eV/ainu.
Tile fit represents the He(42D) cross section with an rms deviation of 3. I%.The maxJiIiUlll deviation is 5.3% at 2.9E+04 eV/_lu,
See appendix for Chebyshev fl[ details. Q
C-41
ii
t-t + He --> He(4'S,4'P,4-'D)
lO-Xi , i , i l , , l
lo+ _dEnergy (eV/am u)
, _i¸
C-42
0Excitation Cross Sections for
H . He -> Ile(43S,43P,43D)
}le(43S) He (4_P) He (43D)
Energy o Energy O Energy o
(eV /a]llt!) (Clll2) (eV /alllU) (Clll2) (eV /a]llU) (Clll2)
I. OE+04 3.69E-19 ]. 0E_04 8.78E-19 i. 0E404 i. 59E-19i. 5E+04 8.38E-19 i. 2E+04 1.08E-]8 i. 5E+04 2.06E-192. OE+04 I. OOE-18 ].4E+04 ]. 15E-18 2.0E+04 i. 71E-193. OE+04 8.70E-19 i. 5E+04 i. 15E-18 2.5E+O4 I. 33E-194. OE+04 5.43E-] 9 2.0E+04 8.82E-]9 3.0E+04 9.92E-205. OE+04 3.56E- 19 2.5E+04 6.05E-]9 3.5E+04 8.03E-206. OB+04 2.48E-19 3.0E+04 4.11E-19 4.0E+04 6.71E-20
7.0E+04 I. 79E-19 3.5E+04 3.00E,-19 5.0E+04 5.21E-208.0E+04 i. 25E-19 6.0E+04 4.36E-209.0E404 9.92E- 20 7.0E+04 3.80E- 20i. 0E+05 8.50E-20 8.0E+04 3.38E-20
9.0E+04 3.05E-20I.OE+05 2.80E-20
References: 166, 677, 678, 684
Accuracy: E > 2x103 eV/cram _ - 40%E < 2x10 "_ eV/6um! - unknown
Notes: (i) The data have been obtained by measuring the line emissions forthe following transitions: (a) 4_S-> 23P, 471.3nm, (b) 4_P-> 23S, 318.8nm,
(c) 43D -> 23P, 447.1nm. (2) The cross sectiol_ data have been corrected
for cascading using known transition probabilities. (3) The corrected dataof Van Eck et al. (Ref. 678) - (see corrections o£ de Heer Ref. 166 andThomas, Ref. 684) have been normalized to the data of Blair et al. (Ref.67T) at 2xlO _ eV/_,u for the 4_S and 4_D states.
Cheb,/shev Fittinq Par_ueters for Cross Sections
He(43S) Emi n '= 1.0E+04 eV/_ml, Ema × = I.OE+05 eV/_ui_u
He(43P) Emi n = ].0E+04 eV/ainu, Ema x = 3.5E+04 eV/6mlu
He(43D) Emi n = I.OE+04 eV/ainu, Ema x = l. OE+05 eV/_nu
AO A] A2 A3 A4 A5 A6
He(43S) -84.9236 -.910048 -.757778 .164455 .0260068 -7.50878E-04 .004685]8
He(43P) --83.6191 -.587215 -.319615 .0516334 .0108396 -.00145124 .00476885
He(43D) -87.8723 -1.03617 -.]77049 .184100 -.0530501 -.0167810 .0122418
The fit represents the Ho(4_S) cross section with an _ms deviation of 2.2%.
The nlaxllllultldeviation is 2.6% at; 8.0E_04 eV/_uu.
The fit represents the He(43P) cross section with an rms deviation of 0.2%.
The maximum deviation is 0.5% at 1.4E+04 eV/_mm.
Tile fit represents tile He(4_D) cross section with all rms deviation of 0.6%.
Tile ma×imum deviation is 1.1% ai; 2.0E+04 eV/ainu.
See appendix for Chebyshev fit; detai.]s. O
10-2c t 1 1 1 1
lo_ ldEnergy (eV/arn tj)
C-44
A
Excitation Cross Sections for i
H. + H -> H+ + H(2s,2p)
H(2s) H(2p)
Energy Cross Section Energy cross section(ev/anu) (cm2) (ev/auu) (cm')
5.0E+03 _.42E-i8 5.0E+02 2.43E-186.0_+03 5.38_-18 6.0E+02 8.90E-187.0E+03 _.36E-18 7.0E+02 1.64E-17L
8.OE+03 5.40E-18 8.0E+02 2.03E.179.0E+03 5.43E-18 9,OE+O2 2.25E-17I.OE+04 5.54E-18 I.OE+03 2.41E-171.2E+04 5.87E-18 1.5E+03 2.73E-171.5E+04 8.62E-18 2.0E, 03 2.80E-17
2.0E+04 1.04E-17 3.0E+03 2.91E-172.5E+04 1.06E-17 4.0E+03 2.97E-17
5.0E+03 3.02E-17
6.0E+03 3.06E-177.0E+03 2.98E'178.0E+03 2.78E-179.0E+03 2.56E-171.0E+04 2.40E-17l.iE+04 2.35E-171.5E+04 2.81E-172.0E+04 3.65E-173.0E+04 5.50E-17
References: H(2s) - 12, 14H(2p) - 14, 17, 712
Accuracy: H(2s) - Unknown WH(2p)- 40%
.9otes: (i) Since the cascading into the 2p state is less thal] 5%, thecross section for excitation of the 2p state is essentially the s_ne asL_nan-a emission cross section. The 2p data has not been corrected for %
cascading. (2) The two sets of data for the 2s state differ by a factorof 2 to 3.
Chebyshev Fittinq Parmneters for Cross Sections
H(2s) Eml n = 5.0E+03 eV/6ullu, Ema x = 2.5E+04 eV/amuH(2p) Emi n = 5.0E+02 eV/_nu, Ema x = 3.0E+04 eV/6unu
AO A1 A2 A3 A4 A5 A6
H(2s) -78.9900 .401365 .0930849 -.0759638 -.0649979 .00791412 .0468211H(2p) -76.6674 .854989 -.357230 .529756 -.161903 .168930 .-.136550
The fit represents the H(2s) cross section with an rms deviation of 2.3%.The maximum deviation is 4.8% at 1.2E+04 eV/m_u.
The fit represents the H(2p) cross section with an rms deviation of 3°7%.The maximum deviation is 6.3% at ].]E+04 eV/_m_.
See appendix for Chebyshev fit details.
0
C-4 5
H+ + H -> H* + H(2s,2p)
Cross Section vs. Energy.10-1_
'1 I J II I I I I I I I I I 1 I I li I I 1 I | I I I I
A = H(2p)
x = H(2s)
#
fN
E
c-O
°_
"_ - _ Recommended0 10 -17
or) _ DatafS)CS) i0l,.-
g _ - .... Chebyshev Fit
_ flO-10 ,, I I i._.j_liiil l j.. i i Jill] l i i i I.J_.Ll
ld ld 10" 105Energy (eV/omu)
C-46
Excitation Rate Coef ficient_ for O
H_ + H -> H. + H(2p)
Maxwellian - Maxwellian Rate Coefficients (cm3/s)
H
Temp. Equal H Temp, (eV)
(eV) Temp. 500. '150. I000, 1250, 5000. 100C0. 20000,
5.0E_02 1.16E-09 1.16E-09 1.39E-09 1.58E,.09 I 75E-09 3,33E-09 4,11E-09' 3.43E-09_
7.5E402 1.58E-09 1.39E-09 1.58E-09 1,75E-09 1 90E-09 3.41E-09 4.11E-09' 3.41E-09@
I.OE+03 1.90E-09 I058E-09 1,75E-09 1.90E-09 2 03E-09 3,48E-09 4.11E-09' 3.39E-09@
1,3E.03 2.16E-09 1.75E-09 1.9OE-09 2.03E-O9 2 16E-09 3.55E-09 4.11E-09' 3.36E-09_
1,5E+03 2,38E-09 1.90E-09 2.03E-09 2 16E-09 2 27E-09 3.61E-09' 4,11E-09' 3 34E-09#
1,8E+03 2.59E-09 2.03E-09 2,16E-09 2 27E-O9 2 38E-09 3.67E-09 _ 4.10E-09' 3 31E-09H
2.0E_03 2.80E-O9 2 16E-09 2.27E-09 2 38E-09 2 49E-09 3.73E-09 _ 4.10E-09' 3 29E-OgH
3,0E+03 3,48E-09 2 59E-09 2.70E-09 2 80E-09 2 89E-09 3.91E-09' _,06E-09' 3 20E-09_
4.0E.03 3.91E-09' 2 99E-09 3.08E-09 3 17E-09 3 25E-09 4,03E-09" 4.00E-09' 3 lIE-09#
5,0E+03 4,09E-09' 3 33E-09 3.41E-09 3 48E-09 3 55E-09 4.09E-09' 3.9_E-09# 3 02E-09#
6,0E+03 4,10E-09' 3 61E-09' 3,67E-09 ^ 3 73E-09' 3 78E-09' 4,11E-09" 3.85E-O9H 2 94E..O9H
7,0E+03 4.OOE-09' 3 83E-09' 3.87E-09' 3 91E-O9' 3 94E-09 ^ 4,10E-09' 3.76E-09@ 2 85E-09#
8.0E+03 3 85E-O9H 3.98E-09' 4,00E-09 * 4 03E-09' 4 05E-09' 4.06E,,09' 3.67E-09@ 2 77E-09#
9.0E+03 3 67E-09@ 4.07E-09 _ 4.08E-09' 4 09E-09' 4 lOt.09* 4.00E-09' 3.58E-09@ 2 70E-09#
I_0E_04 3 48E-09_ 4.11E-09' 4,]1E-09' 4 lIE-09* 4 IIE-09' 3,93E-09H 3.48E-09@ 2 62E-09H
1,2E+04 3 lIE-09# 4.08E-09' 4,07E-09' 4 06E-09' 4.05E-09' 3,76E-09@ 3.29E-O9H 2 48E-09@
1,5E+04 2 62E-09# 3.89E-09H 3,87E-09H 3 85E-09_ 3.83E-09_ 3_4_E-09@ 3.02E-09# 2 29E-09_
2.0E+04 2 02E-09# 3.43E-09H 3.41E,-09ff 3 39E-09# 3.36E-09H 3.02E-O9H 2.62E-09_ 2 02E-09_
Accuracy: * - Possible ErrOr Greater Than 10%
- Possible Error Greater Than 100% O
Chebyshev Fittinq Par_ueters for Cross Sections
Emi n = 5.0E+02 eV, Ema x = 2.0E+04 eV
H
Temp.
(eV) AO A1 A2 A3 A4 A5 A6
500. -39.7100 .631450 -.153568 -,0909606 -.0319929 2.01]18E-04 .0098[582
750, -39.5923 .543848 -.128283 -,0971754 -,0299354 .00227565 ,00859152
1000. -99.4997 .476362 -.113723 -.0995434 -.0281721 .00377301 .00746751
1250. -39.4237 .421755 -.105533 -.0997854 -.0264000 .00472594 ,00647274
5000. -38.9001 .0101105 -.108849 -.0609619 -.0111639 .00213821 .00143014
I0000. -38.8452 -.187122 -,]05864 -.0371107 -..00678512 2.66271E-04 5.36963E-04
20000. -39.3124 -.240533 -.0956162 -.025]663 -.00414891 -1.62169E-04 1.56753E-04
Equal Temp. -39.7457 .353158 -,421145 .-.103566 -3.86751E-04 .272186 -.00215387
See appendix for Chebyshev fit details.
C-47
Q
H+ + H-> H* + H(2p)
Maxwellian MaxwelianO
I0•-- 50.0 ....._. I I I i lllI] 'I.... I I FIIII I ....... I 'I I 'i fliT"
H Temp.
45.o (ev)z_--500.
20.0Chebyshev Fit
15.0- Equal Temp.
10,0 ____L i I I 1 llll _ .1 1 i I,I , l.J_J
10_ 103 104 10sH* Temp. (eV)
(;- 4 8
O" , Exc,it at io:_ Cross Sections for
H+ + H -> Ht 4 14(fi=2,3,4)
H(n=2 ) H(n=3 ) It (n=4)
Energy o Ellergy o Energy o p
( eV / allltl ) ( till 2 ) ( eV / alllt] ) ( C',IIIz ) ( eV / 6.ulRI) ( ell| 2)
]. 58+04 3.43E-]7 ]. 5E+04 i. 09E-17 2.5E+04 7.69E-]82. OE+04 5.22B-17 2.0E+04 ].29E-]7 3,0E404 8.68E-182.5E+04 6.64E-27 2.5E404 1.53E-17 4.0E+04 1.02E-173.0E+04 7.89E-17 3.0E+04 ], 80E-17 5.0B+04 ]. 12E-174.0E+04 9.59E-17 4.OE404 2 33E-17 60E-F04 1.18E-]75.0E+04 1.05E-16 "a.r'OE+04 2 54E-]7 70E+04 1.19E-]75.5E+O4 1.07B-16 6.0E+04 2 5.1.E- 17 8 0E404 1.18E-176.0E+04 ].07E-16 7.0E+04 2 42E-17 9 0_:+04 1.14E-177.0E+04 1.03E-16 8.OE+04 2 32E-17 ] OE+05 ].]OE-178.0E+O4 9.72E-17 9.OE-I04 2 21E-]7 i 5E+05 9.06E-]89.0E+O4 9.28E-17 ].OE+05 2 ]4E-17 20E+05 7.69E-18].OE+O5 8.90E-17 1.5E+05 ] 70E-_1.7]. 5E+O5 7.48E-17 2. OE+05 I. 36E-172.0E+O5 6.53E-17
References: "109, 710, 711
Accuracy: 40%
Notes: (1) These cross sections were determined by measurirlg the el]ergy loss
of-_--_e incident proton beam after passing through an lt target. The energy iresolution was l]Oti sufficient to separate the xi] ]Ievels. (2 ) To obL:ain absolutecross sections the results were normallzed to the Born approximatior| of Batesand Grlffing (Ref. "711) atS 200 keV.
Chebyshev Fittinq Par_lleters for Cross Sections
H(n=2) Eli|in = 1.5E,_O4 eV/ainu, Ema x = 2.0E+05 eV/ainuH(I]=3) Eluin = 1.5E+04 eV/6ullu, Ema x = 2.0E+05 eV/ainuH(n=4) Emi R = 2 .5E+O4 eV/allItl, _llIax = 2 .OE+05 eV/_lIt!
AO AI A2 A3 A4 A5 A6
H(n=2) -74.4276 ,262934 -.386115 .0616937 .0293129 -.00255599 -.0]90829H(n=3) -77.2728 .]49236 -.351549 -.0]57777 .0571627 .0247442 -00161701H(n=4) -78.4118 -.00702352 -.213691 .0080]652 .0]82541 -8. 70179E-O4 -.0053865]
The fit represents the H(n=2) cross _-ction with an rms deviation of 0.5%.The maximum deviation is 0.9% at 8.0E,04 eV/rural.
The fit represents the H(n=3) cross section with at] rms deviation of 1.2%. ,The maxilllum deviation is 1.5% at 7.0E+04 eV/_Uu.
The fit represents ,the H(:]=4) crows section with ali rills deviation of 0.2%.The maximum deviation is 0.2% at 5.0E+04 eV/_mm,
See appendix for Chebyshev fit details.-
O
C-49
0
H+ + H -> H(n---2,3,4-)Targeti
Crc_ssSection vs. Ener9y10 _s
t i t ' I " 1 'T T , i I I ' t i t t ' [ I 1
/', = H(n=2)
- X --H(n=3)
'9 = H(n--4.)
10-16_
0 i
,2 -
0 ,(D Recommendedq.)
_ -- Data
L_ 10_17- -.... Chebyshev Fit
,,
10 ,_e. L,__l l 1 I 1,1 II 1 J I _l I J l J
104 10s 106Energy (eV/am u)
C-50
0Dissociative Excitation Cross Sect lons for
I-1+ + H2 -> t-i_ + H(2s,2p) + H
H(2s ) H (2p )
Energy Cross Sect:Ion Energy Cross Section(ev IaJl_u) Com 2) (ev/_uu) (cre2)
5.0E+03 1.32E-18 4 OB+03 6 36E-]87.0E+03 3.59E-18 7 OE+03 I 84E-17I.OE+04 4.70E-18 I OB+04 2 76E-171.5B+O4 5.73E-18 1 5E+04 3 12E-172.OE+04 6.38E-18 2 CE+04 2 96E-174.0E+04 7.69E-18 4 OE+04 2 14E-l/7.OE+04 8.00E-]8 7 OE+04 1 48E-17
1.CE+C5 7.88E-18 I Oi."-k05 I 21E-I'I1.5E+O5 7.04E-18 1 5E+05 9,23E-182.OE+05 6.23E,-18 2 CE+05 7,42E-184.OE+05 4.18E-18 4 OE+05 4,34E-187.OE405 2.75E-18 7 OE-105 2,81E-18
I.OE+06 2.00E-18 I OE+06 2.14E-]8
Re.fereilces : 122, 124, 128, 649
Accuracy: 50%
Notes: (I ) The 28 cross sect io11 has been measured by f ie].d.-.irtchlced_'oz_ of byma11-_ radjatlon (2s -> 2[) -> is). If cascade is rleglected,
this is equa.t to the cross section for H(2s) formation. (2) Tile 2p cross isection was determii_ed by measuring the blauan-c, emiss,/on. If cascade is
neglected, this is equal to the cross section for H(2P) formatiotl,
Chebyshev Fittinq ParemleterS for Cross Sections
H(2s) Bmi n = 5.0E+03 eV/ainu, Ema× = ].OE+O6 eV/ainuH(2p) Emil] = 4.0E+03 ev/anlu, Ems x = ].OE-I.06 eV/amt!
AO A1 A2 A3 A4 A5 A6
H(2s) -80.1116 -.0216909 -.735933 ,i17161 -.0952706 0960395 -.0678792H(2p) -78.5492 -,910686 -,758592 .347330 -,]3]263 ,0249389 .0249642
The fit represents tile H (2s) cross sect;ion wJt:h all rills deviation of 3. i%.The Rlaxliilullldeviatioii rs 5.9% at 1.0E4-O4 eV/ainu,
The fit represents the H(213) cross sectiol_ with all rms der.rat-ion of 1.6%.The illaxill_tllll deviatioll J s 2.5% at 7.0E-t.03 eV/alllU.
See appendix for Chebyshev fit; det-ails.
C-51
0H+ -k H2 -> H. + H(2s,2p)
Cross Sectionvs. Energy-16
10 _' " I " I I -I I I III " l , I , , ,i-,i , I""r--T'TTTT"
.,,
-- H(2s)
x - H(2p)
- /QNx
t-.. _ _ \
C) ii
C0
'-_ lO-17 Recommended(.j
Lr)O9
0
_ ..... Chebyshev FitU ,9 "s'/
/'//
;J
lO-le _- J J J I i L.L.LL__L J J J I Jill
icf lo+ _d lo_Energy (eV/amu)
C-52
Dissociative Excitation Cross Sect ior_s [or
H + + H 2 -> H + + H(3p) + H
Energy Velocity Cross Section(eVlmml,) (c._,m/ s ) (_.,2,
1,5E+04 ].70E+08 I 99E-]81.6E+04 1,76E+08 2 14_-18I. 7E+04 1.81E+08 2 25_-181.8_,+04 ].86F,+08 2 34F,-181,9E+04 1,91E+08 2 38E-18
2.0E+04 I. 96E+08 2 39E-182. IE+04 2.01I,_,"-t.08 2 36E-182.2E+04 2.06E+08 2 31E-18
' 2.3_:404 2. lIE+08 2 24E-182.4E+04 2,15E-108 2 16E-18
2.5E+04 2,20E+08 2 07E-182.6E+04 2.24E+08 i 95£',-182.7E+04 2.28E+08 ] 81E-182.8E+04 2.32E+08 ] 65E-182.9E+04 2.37E+08 1,45E-183.0E+O4 2.41E+08 I. 20E-.18
Referen_ 122
Accuracy_! 30%
The cross sections for H(3p) fornlat ion deduced f£o111 elllJssiorln_easurements on the (unsubstantiated) assumption that cascade may beneglected, g
Cllebysllev Fittinq ParEmleters for Cross Sections
Eml n : 1.5F]+04 eV/c,Lm, Ema x = 3.0E+04 _V/amu
AO A1 A2 A3 A4 A5 A6
-81.5559 -.198605 -. 205491 -.O404366 -.0225806 -.0130785 -.00450361
Tile fit represents tile above cross sectioll with all i'IllSdeviatiol] of 0.2%.The ma×imum deviation is O.4% aL 2.7EI04 eV/rural,
See appendix for Chebyshev fit details.
®
C_53
a
H+ -t- PI_-> Ht3p) Target
, Cr-c,ss ._ec:tionvs. EnergyL')
24,0
A -- t-1(3p)22,0
20.O -f"_
0
C©
0 '_ 18.0 Recommended¢) -_Datat/')oo
oU ..... Chebyshev Fit '
16.0 -
1_,0 -
12,0 _ J J 1 [lS.O 17,s 20.0 22,s 2s,o 27,s 30,0
Energy (eV/amu) * 103
C- !)4
Spectral blne I_111]ssiOll Cross Sec, t iOllS for 0
H+ -f I.I_ -> ll(b_uan-c_)
Energy Velocity Cross Section(,eV/ainu) , (c,l/s ) (c.I 2)
5 OE+02 3,11E+07 6,56E-187 0[_+02 3,68E+07 9,30E-18] OE+03 4,39l_+07 1,31E-171 5E,103 5.38E407 1.86E-172 OE+03 6,21E+07 2.35E-174 0E4"03 8.79E+07 3.74l_-]7
7 0_:+03 ], 16E+08 4 ,98E-17i 0E4'04 1.39E'I'08 5,68E-]71 5E+04 1,70E+08 6,17E-17
2 OE+04 1.96E-I08 5.50E-174 OE+04 2,78_+O8 ' 2,78[_-177 OE+04 3.68E+08 1.77E-171 OE+05 4.39_,+08 1,40E-17i, 4 E-I-05 5.20E+08 i, 20E-] 7
References I 188, 194, 195, 6"16
Aocuraovz 50%
Note I Cross sections correspond t;o 121,5711111 emission resulting f rol|l
_'_ciative excitation of H2 by proton impact.
Chebyshev Fittinq Parameters for Ci:oss Sections O
Eluin = 5.0E+02 eV/_ilu, Ema x = 1.4E405 eVlaliu
AO AI A2 A3 A4 A5 A6
-76.9474 .268573 -,911806 -,036]054 .132508 ,0899171 .00698679
The fit represents the above cross section wlLh an rl;IS deviation of 4.5%.The ma×imum deviation is 10.4% at 4.0E+04 eV/amu,
See appendi× for Chebyshev fit details.
, c- 5 5
OH+ + H_ -> Lyc_Torget
t-o<'sSectioi_vs Enet'gy {,,--, 16IU- ------r---r--r-r-rT_ i'l "f' i i' t '1 i'1 i1'- i _ --i'-TTTTi 1 - I - I J-i I'TTT"
A .- Ly,_,
, ,
/'-'x
_E(D
0
'__ 17o, 10- - R e C O r_ m e _ d e d
,_ .... DorabO(,r)u)'O
Chebyshev FitU
lo-le._.__.___j !_UlJl 1 I 1 t 11111. j I 1 1 IHII, 1 _1 I__Z...L._
lo2 lO_ _o4 lo_ lo0Fnergy (eV/a m u)
C-56
Spectral Line Emissior] Cross Sections for
H+ + H 2 -> H(Balmer-a,Balnler-B,Balmer-f)
Ha ' HB H7
Energy o Energy o Energy o
(eV /6u1%t!) (cnl2) (eV /_llu) (CII12) (eV /6Ullu) (CIll 2)
i, 5E+03 2.09E-19 5. OE+03 1 •75E-19 1. OE+04 i. 00E-J92.0E+03 2.70E-19 6.0E+03 2.37E-19 1 •4E+04 i. 09E-194 •0E+03 5.80E- 19 7.0E+03 2.98E-]9 1 •5E+04 1.08E-19
7. OE+03 i. 51E-18 8. OE+03 3.53E-19 2. OE+04 9.91E-20I.OE+04 2.24E-18 9.0E+03 3.95E-19 3.0E+04 7.64E-20
1 _5E+04 2.62E-18 1. OE+04 4.28E-19 4 •OE+04 6. OOE- 202. OE+04 2.44E-18 i. 5E+04 4.70E-19 5. OE+04 4.93E-204.0E+04 1.55E-18 2. OE+04 4.22E-19 6. OE+04 4.21E-207. OE+04 9.05E-19 3. OE+04 3. OOE-19 7. OE+04 3.69E-20I. OE+05 6.50E-19 4. OE+04 2.29E-19 8. OE+04 3.29E-20i. 5E+05 4.57E-19 5. OE+04 I. 88E-19 9. OE+04 2.96E-202. OE+05 3.57E-19 6. OE+04 i. 59E-19 l. OE+05 2.70E-204. OE+05 i. 96E-19 7. OE+04 1.37E-19 i. 5E+05 1.87E-207. OE+05 i. 20E-] 9 8. OE+04 i. 21E-19 2. OE+05 I. 46E-20I. OE+06 8.90E-20 9. OE+04 i. 08E-19 3. OE+05 i. 02E-20
i. OE+05 9.78E-20 4. OE+05 7.97E-21i. 5E+05 6.72E-20 5. OE+05 6.52E-212. OE+05 5.18E-20 6. OE+05 5.57E-213. OE+05 3.60E-20 7. OE+05 4.88E-214. OE+05 2.75E-20 8. OE+05 4.38E-215.0_+05 2.25E-20 9 •OE+05 3.98E-216. OE+05 1.90E-20 1. OE+06 3.65E-21
7. OE+05 1.66E-20 I8.0E+05 1.46E-209.0E405 i. 32E-20i. OE+06 i. 19E-20
References: 133, 139, 655
5u_
Notes: (I) The data correspond to Balmer-series emission resulting fromdissociative excitation of H2, and have been normalized in the high energy
region to aata of Edwards and Thomas (Ref. 655). (2) Differences inmagnitudes of the reported cross sections for each transition are due todifferences in Calibration between the experimental systems. (3 ) The
wavelengths are as follows: Ha= 656.28nm; HB=486.13nm; H-_,=434.05nm.
C/hebyshev Fittinq Parauueters for Cross Sections
Ha Emi n = !.5E+03 eV/6ullu, Ema x = I.OE+06 eV/muu
HB Emi n = 6.0E+03 eV/ainu, Ema x = I.OE+06 eV/6mlu
H-f Emi n = I.OE+04 eV/_11u, Ema x = ].OE+06 eV/_uu
AO A1 A2 A3 A4 A5 A6
Ha -84.6647 -.627902 -1.28581 .366073 .150564 -.204615 .0536705
HB -87.6626 -1.78903 -.434179 .278457 -.129747 .0301375 .0113784
Hy -90.3588 -!.79519 -.168084 .119053 -.0545231 .0225899 -.00228634
The fit represents the Ha cross section with an rms deviation of 5.4%.
The maximum deviation is 12.3% at 4.0E+03 eV/zullu.The fit represents the HB cross section with an rms deviation of 1.4%.The maximum deviation is 3.1% at 4.0E+04 eV/_]tu.
The fit represents the H-f cross section with an rms deviation of 0.4%.The maximum deviation is 0.8% at 5.0E+04 eV/_llu.
See appendix for Chebyshev fit de_ails.
C-57
0
H* + H.,. > H_,I-I_,H>,
Cr-ossSection vs. Energy,ir-,-17IU _ , , , , 'I'_"I , " , , r-7'l,,i , , , , , , ,_
--
/J "k_ A - H,_
/ \ ×-._10-'o %
-- // -%
\ q - HT
/./'""_.,,..,, '__,_.
° x/ -.C" \\ ,_
0 +-'(.9 10 -19 -- g_"--"-... _ _'\ Recommendedqb - "" ""
" --DataC') : \,,\
- "\ " 1U') _ \
0 .. \..- \ " Chebyshev FitU \\\ "%,,
-- _X,X\ %
\
1O-2c_ -,,,,.Z "\- \
- \
lO-2 J l J J JJlJl l J J J liiil J 1 I IJ_ZJ.
_o_ lo" ld lo_Energy (eV,/am u)
c-58
,'
Spectral Band Emission Cross Sections for
H. + H 2 -> H . + H2*
160.6nm Band 418.0nm Band
Energy Cross Section Energy Cross Section( eV/_llu ) (cnlZ) ( eV/_llt_ ) (cm 2 )
7.0E+03 2.17E-18 1.5E+05 8.06E-218.0E+03 2.31E-18 2.0E.05 6.25E-219.0E+03 2.44E-18 2.5E+05 5.06E-211.0E+04 2.56E-18 3.0E+05 4.21E-211.5E+04 3.OOE-18 3.5E+O5 3.62E-212.0E+04 3.30E-18 4.0E+05 3.]7E-213.0E+04 3.69E-i8 5.0E+05 2.54E-214.0E+04 3.84E_18 6.0E+05 2.11B-215.0E+04 3.87E-18 7.0E+05 1.81E-21
6.0E+04 3.83E-18 8.0E+05 1.59E-217.0E+04 3.76E-18 9.0E+05 1.39E-218.0B+04 3.67E-189.0E+04 3.55E-181.0E+05 3.42E-18
' 1.3E+05 3.01E-18
References 194, 654
Accuracy: 50%
Note: The 160.6nra Band is the L_nllan band of H2 IS *_u+ -> x *_.g+, (4,11), (5,12)
and (6,13)]. The 418.0nra Band of H2 is for the transitions [3d *_g -> 2p IZu+(1,0)1.
_Cbeb_vshev Fittinq Para_neters for Cross Sections
160.6 nm Bmi n = 7.0E+03 eV/aalu, E a = i. 3E+05 eV/aallu418.0 nm Emi n 1.5E+05 eV/aJllu, _nl×= Ema x = 9.0E+05 eV/_im
AO AI A2 A3 A4 A5 A6
160.6 llm -80.6464 .194014 -.]81339 -.0301739 -,00212964 3.13863E-04 -.00210888
418.0 nm -94.2526 -.881302 -,0131335 .00371515 -.00433338 -6.45602E-04 -.00195489
The fit represents the i[60.6nm emission Cross section wiLl] an rms deviationof O. 2%.
The maximum deviation is 0.3% at 2.0E+04 eV/ainu.
The fit represents the 418.0nm emission cross sect ion with an rills deviationof 0.2%.
The maximum deviation is 0.3% at 7.0E+05 eV/muu.
See appendix for Chebyshev fit detaJ]s.
C-59
• ,
H+ + H; > 160,6, 4-18.0 nm
C-60
Excitation Cross Sections for O
H. 4 He -> H_ i He*(21SI2*P)
H 4 4 He*(_,IS 4 21P)
He(21S) He(21P) He(2*S + 2rP)
Energy o Energy o Eilergy o
(eV / 8111tl) (CII|2,) (eV/aUU ) (cre') (eV/m,u ) (cre_)
2.5E+04 3.79E-18 2.3E+04 2.00E-18 2.3E+04 5.38E-!83. OE+04 4.52E-18 2,5E.04 2.44E-18 3. OE+04 7.52E-]83.5E+04 5.28E-] 8 3. OE+04 3.44E-18 4. OE104 1. ]2E-174. OE+04 6.05E-18 3.5E+04 4.61E-18 5.0E404 1.47F,- 174,5E+04 6.68E-18 4_0E+04 5.76E-18 6. OE+04 1.50E-17
5. OF,+04 6.87E-18 4.5E+04 6.91E_18 7. OE+04 I. 48E-175.5E+04 6.59E-18 5. OE+04 7.65E.-18 8, OE+04 i. 55E-176. OE+04 6.22E-18 5.5E+04 7.96E-] 8 9. OE+04 1.71E-177. OE+04 5.33E-18 6. OE+04 8.39E-18 ]. OE+05 i. 79E- 17
8.0E+04 4.94E-18 7.0E404 9.39E-18 i. 3E+05 1.62E-179.0E+04 5.16E-18 8. OE+04 1.08E-]7I. OE+05 5.43E-18 9. OE+04 1.23E-17
I.OE+05 1.36E-17i. 2E+05 1.43E-171.5E+05 1.35E-172. OE+05 I. 21E-172.5E+05 I. ]OE-]73.OE405 ].O]E-173.5E+05 9.32E-184. OE+05 8.71E-185. OE+05 7.80E-18
6. OE+05 6.91E-187.OE+05 6.31E-]88.0E+05 5.88E-189.0E+05 5.52E-18]. OE+06 5.23E-18
References _ 665, 680, 681, 682
Accuracy: E < 1.5xlO S eV/_m_ - 50%
E > 1.5xlO 5 eV/ainu - 30%
Note..._.'For angular distributions see Park et al. (Ref. 681), and Kvale et al.(Ref. 665).
Chebyshev Fittinq Par6uueters for Cross Sections
He*(2 IS) Eluin = 2.5E+04 eV/_uu, Ema x = I.OE+O5 eV/mllu
He*(21P) Eml n = 2.3E+04 eV/6m_u, Ema x = I.OE+06 eV/_m!
He*(21S + 2*P) Emi n = 2.3E+04 eV/muu, Ema x = 1,3E_05 eV/8]uu
AO AI A2 A3 A4 A5 A6
Ho*(21S) -79,6082 .117213 -.178720 0616470 ,0764221 ,O0195815 -.0273944
Hs*(21p) -79.1761 .3[[8296 -.694295 .161212 ,0240083 -,00395403 ,-,0285411
Hs* (21S _ 21p) -77,9705 ,598490 - , ]90056 . 0].36"]46 ,00624072 - ,0619807 - .0440015
The fit represents the He*(2*l_) cross section with an rms deviation of 0.5%.
The maximum deviation is 0.7% at 8.0E404 eV/ainu.The fit represents the He*(2 _P) cross secti(:m w:[th an rms deviatJol] of 3.7%.
Tile II|axillltlIlldeviation is 8.4% at 'l.OE+04 eV/aillu.The fit: represents the He*(21S + 2*P) cross sec:tioll w:[th au rms devlatlon of 1.6%.
The maxlmunl dev_atiol] is 2.0% at 7.0F,+04 eV/ainu.
See appendix for Chebyshev fit details.
H+ + He ->He(2'S,2'P,2_S ..2'P)
_o ::_uctior-,vs. Enen:jy---16I0 I '1_- i -i I 1 I I I I '1 '1 I _ I' I""1 I
A- He(2'S + 2'P)
X - He(2'P)
V = He(2'S)
/--_
,(2_
co_cn_®u' 10_,7,_'-- o.,._,.,,_!_ _ DataRec°mmended
o - ,%U _ - ....... Chebyshev Fit
lO-'8 , , , , ,,,, l , ,. , L ,, ,_' 10" 105 106
' Energy (eV/am u)
C:.-6 2
_×c_L t:at :1on Rate Coc_Ji1_:1c:Lent:B _or W
lie -t It _ -.> II _ t. l-le*(2tS)
Be_ml -- Ma×wa.l.l,:l.an Rate Cc_ol_,l!_L.ctolikl,_ (ClU_/t_)
It
'i'Bmp, I1_ Euot:gy ((_V/al,U)
'(_V) 30000, 40000, 50000, 60000, 70000, 00000, 100000,
l,OEiO0 1,09F,-09 1,68E-09 2. 13E-09 2, lIE-09 1 96E-09 1,94E-09 I, 19E-09_
2,0E_O0 1,09E-09 1,68E-09 2,13E-09 2,11E-09 1 96E-09 1,95E-09 i 18E-OgH
4,0E+O0 1.09E-09 1.68E-09 2,13E-09 2,11E-09 I 96E-09 1,951,I-09 I IOE-OgH
7,0E+O0 1.09E-09 1.68E-09 2,12E-09 2,11E-09 I 96E-09 1,95E-09 1 18E-09@
I,,OE_OI 1,09E-09 1.68E-09 2.12E-09 2,11E-09 I 96E-09 1,95E-09 I 17E..09#
?_,OE+O] 1,09E-09 1.68E-09 ?.,12E'09 2,11E-09 I 97E-09 1,96E-09 I 16E-Ogll
4,0E+O1 1.09E-09 1,68E-09 2.1[E-09 2,11E-09 'l 97E-09 1,96E-09 I 151_-09@
7,0E_OI 1.09E-09 1,68E-09 2.10N-09 2,10E-09 i 97E-09 1.97E-09 I 14E-OgH
1.0E_02 1.09E-09 1,68E-09 2,09E-09 2,10E-09 1,98E-09 1,98E-09 I 13E-091#
2,0E¢02 I/07E-09 I, 68E-09 2,08E-09 2.09E-09 1.99E-09 2. OOE-09 I lIE-09#
4,0EI02 i 04E-09 1.68E-09 2,04E-09 2,07E-09 2.00E-09 ..',r)OE-09 I 07E-09#
7,0E¢02 I 04Ei09 * 1,67E-09 2.00E-09 2,06E-09 2.01E-09 _.95E-09 I 04E-09#
;i,0E403 I 05E-09' 1.66E-09 1.97E-09 2,04E-09 2.00E-09 1,09E-09' I 02E-09_
2,0"_¢03 I IOE-O9* 1,61E-09 I, 89E-09 l ,97E-09 1,91E-09 1,71E-09' 9.77E-10@
4, OEii03 i 17E-09' ' I,,55E-09 1.75E-09 1.79E-09 * I. 69E-09 * I, 48E-09 _ 9,29E-I0#
7.0E¢03 i 23E-09' 1,47E-09 I. 57E-09' I. 56E-09' 1,451!:-09' i. 28E-09' 8.75E-.10_
1.0E¢04 I 23E-09' 1 , 38E-09' I, 43E-09' I . 39E-,09' I ,29E-09' I, 15E-09 _ 8.27E-I0@
2,0E¢04 I 15E-09' I, 15E-09' i. 12E-09' I, 06E-.09 _ 9,fl3E-IOH 8,92E-I0# 7,02E-I0#
Ac(:uracyt * - Possible Error Oreater Than ]0% Ifl - Possible Error Greater Than ]00%
Cilebyshev Fittinq Par_uueters for Rate Coefficients
Eml n = ].OEiO0 eV, X_max'_'=: 2.0E+04 eV
He
Energy
(eV/amu) AO A1 A2 A3 A4 A5 A6
30000. -41.2314 .0438795 .0359901 °0113183 -.01831772 -.0298761 -,0164179
40000, -40.5478 -,126080 -.0918486 -,0530702 -,0226281 -.00730499 -,90342970
50000. -40.2209 -,240437 -.148187 -.0739185 -.0283797 -.00898769 -8.65703E-04
60000. -40.2314 -.246864 -.171734 -.0935161 -.0372433 -.00687580 .00536462
70000. -40.3601 -.241292 -.189416 -,108326 -.0372244 .00170975 ,0115451
80000. -40.4485 -.303064 -.213746 -.0974470 -,0150845 .0124774 ,00596267
100000. -41,3985 -.220781 -.0969877 -.0320398 -,0136188 -.00923349 -,00545964
See appendix for Chebyshev fit: det:aLls.
C.,-6 3
+ l,_.H,e + H ....",H* + He(2::,)
10.0..... Chebyshev Fit
5.0 1 J I llliJl l i I 111111 l ! 1 111111 ;.L_LJ.J_LJ._L___L_I I illli
100 10' 102 103 104 10sH* Temp. (eV)
|
C - 6 li
l_xciLat:l.¢m Rat:e ' Cl_eI I:.l,c,.i._-:nt:_, l-ul: I
lie -t I-I_ -> I-I_ .t. I-Ie*(2LP)
Beam - Max_,/ell:l.al| Rat:e l;oe[llj.c_.t.elit:_J (Clll_/_j)
II
'£emp, IIs l,.'m_r g y ( sV/al,u )(eV) 30000, 40000. 60000, 600O0° tO0000, 20000O. ,100000,
t,oE_00 8 2BE-10 1,60E-09 2,86_I-09 4 241_-09 5,97E-09 1,5;!B'-09 1,65P,-09
2,0E.00 8 28E-I0 1,60E-09 2,86E-09 4 24F,-09 5,96E-09 7 52E,.09 ',',65E-09
4,0E000 8 29E-10 1,60E-09 2,86E-09 4 24E-09 5,96E-09 7 511!',-09 "1,65E-09
7,0E_O0 8 29E-I0 1,60E-09 2,86E-09 4 25E-09 5,96E_09 7 51E-09 7,65E.-09
l,OEtOi 8 30E-|O 1,60E-09 2,86E-09 4 25[':-09 5,95[':-09 7 51F,-09 7.65E-09
2,0E_01 8 32E-I0 I 60E-09 2,86E-09 4 25E-09 5,941_-09 7 51E-09 7 65E-09
4,0E+01 8 36E-I0 ) 61E-09 2,86E-09 4 25E-09 5,93F,-09 7 51E-09 'I 65E-(}9
7,0E_01 8 41E-I0 I 61E-09 2,87E-09 4 26E_09 5,92E-09 'l 51[.':-09 "/ 65F.-.09
1,0E*02. B 41E-lO 1 61E-09 2,87E-09 4 27E-09 5,91E-09 7 5[E-09 7 65E-09
2,0E_02 8 60E-10 I 63E-.09 2.89E-09 4 28E-09 5,89E-99 7 51E-.09 7 65E-09
4,0E402 fl80E-lO | 65E,-09 2,92E-.09 4 %_E-09 5,07E-09 7 50E-09 7 65E-09
7,OE.02 9 14E-I0 I 67E-09 2,96E-09 4 36E-09 5,84E-09 7 51E-09 7 65E-09
I,OE+03 9 51E-lO 1,69E-09 2,99E-O9 4 41E-09 5,82E-09 ? 50E-09 7 05E-09
2,0E+03 I 07E-.09 1,78E-09 3,12E-09 ,I 51E-09 5,77E-.09 7 50E-09 7 65E-09
4,0E_03 1 30E-09 1,97E-09 3,33E.-09 4 63E-09 5,73E-09 7 48E-09 7 65E-09
7,0E_03 } 63E-09 2,28E-09 3,58E-09 4 75E-09 5,70E-09 7 45E-09 7 64E-09
1,0E404 i 93F,-09 2,57E-09 3,78E-09 4 85E-09 5,69E-09 7 41E-09 7 63E-09
2,0E_04 2 79E-09 3,32E-09 4,29E-09 5,O9E-09 5,74E-09 7 27E-09 7 60E-09
Ac:curacy| * - Possible El;ro[ (Jreate[ Thau 10% /fl - Possible Error O[eater Than J00%
Chebyshev F fttiI]q l'a[amet:erf_ for RaLe Coe:fficJeiltiS
Elll.|.ll= ]. OE-I'O0 eV, gllla x = 2, OE-t. 04 eV
He
Energy
(sV/amu) AO A1 A2 A3 A4 Ab A6
30000, -41,2504 .486127 ,299576 01283u0 .0302620 -,00574350 -,00993827
40000, -40,1898 ,273759 .181714 .0905572 0_22161 .00429196 -,00603203
60000, -39,1561 ,16267_ ,0999502 ,0424831 00981070 -,00141938 -,00247916
80000, -38.4598 ,0783748 .0416546 ,0129989 00102165 -5,19012E-04 6,56879E-04
100000, -37,9111 -,0245920 -,00529346 ,00275039 00343274 ,00202306 8,64146E-04
200000, -37.4242 -,010222V -.,00738113 -,00482593 00Z85436 -,00141545 -4,70357E-04
400000, -.37,3788 -,00169868 -.00]56122 -,00125546 -8 18521E-O4 -4,46724E-04 -1,48377E-04
See appendix for Chebyshev fit: det:a:[ls,
i
C-65
t-t,-!:..... t- t--t_ - ', I--I_ -t- He(2_P)
, _hl iii
C_-6 6
l_Jxc_lLat; t ¢.)N Clo_l_l Hoc'L.I c)11_, {'c)r
I-I_ .t. I-le -> 1.1' .t 1-1_*(31_0311>13tD )
fie* (3iS) tie* ( 31 p) It0' (]LI))
Elle t'c.Jy (s Erie 1.'clY o Ellel;qy o
( eV/aillti ) ( elil _ ) ( eV/_Ullti ) (C:lil_ ) ( e V/alllti ) ( Olli l )
.5,0 E,t+0 3 6 81 E - 2 C) 2 0 I!;.t.O3 7 4 ;1E - 2 ;l J h E.i-0 ] 4, b ;i lr,--2 0'6,0I_]103 I 08E-1.9 4 01_.t03 4 38E-20 : 4 0[_,.I.()3 (i,.lSE-207,0 I_]-I.03 [ 65 E - 19 "l 0 E-I-03 .I 90 E- .I.9 7 0 I!2.I.03 J .I.;[ E- .I.98,OE.tO3 2 26E-19 ] OI!H.C)4 b 04E--19 .l 01,.I.t.04 3 90_-1.990E'I.03 2 e,,, 9,_F!,-J9 .I !il'7,-lOd i 04l_]-;1.8 t ..5E.I04 4 30E-]9£, 017,+04 3 65E-1.9 2 C_,-i()4)' I 251];-.18 2 01];-I.04 7:I /4E.-.191, b E-i.04 6 fl 3 E- 19 2. 7 E-i.04 I 2 ;t I,_1- l 8 2 8 IS-I.04 2 B3 l!;- ! 92.0171.t.O4 ' 9 53E-.[9 4 C)E-1'-04 [ 56E'.,-.18 4 01]',-t.O4 _t b'IE-I.93,0EI04 ] 30E-18 70E-l.Od 2 501,.1-[fl 5 5E.I.04 3 82E-.[94.0 E.t-0 4 I 4 3 E- .t8 1 0 E.I-0 b 3 () b1_-18 "7 0 E.t.0 4 3 4 "1E- ;I.95,0E-1-04 I 39E.-18 l 3E.I-0!$ 3 27E-18 I Om105,_. 2 68E-19'4,0N+04 I 29L,I-18 20L,..()._"ir' 3 .l.3E-.If+J 1 5[!',,lOb 2, 021!I-;19
r.. i_, OE-t.O4 1 21E- 1.8 40E-lOb 2.3 .d0-.l f.I8, OE-t-04 J J.2_-18 70Et-O!) .1,6/l_-J.fl9,0E4.04 I 03E-18 1. OE-I-06 1,30E-.]8;I, OE-l.Ob 9,63E- t9.1., 5E+05 6,92E-1.92, OE+05 5,07 Iri- ] 92,5E.I.05 ,3,91E-19
Re£erenceal 6BO, 68b, 686, 681, 6fl8_ 689, 690
Accuracy_ L 40% @
Not#a i Nolle
CJhe!Tyell'lev [_'J.LL;lllq U'al;_llneLei;,9 £oi: (;r,o_t_ SecL.{ollel
-"= 50E'tO] OVl_71111tll Ir' '-" 2, i rtie* ( 3_ ) Ent.tn _ _nla× ,E 'OJ eV/anltttie* ( 3i F') Elll_I. I = 2. OE-t.O] (-)V/ilII1H_ EiilttX = 1, OEtO6 . eV/allltlFie* (3tD) I_,Iii.iiI = 3, DE-lO3 ovl£tliltl I EIII_Ig =: J., 5E.I-05 eVlallltl
AO A.1 A2 A3 A4 A5 A6
He* ()_S) -.84. 4433 ,77656.1 -1. 05948 .110960 ,02;1.9972 -.00305073 -.. 00996104He*(3_P) -84.5124 2,50!i29 -1.632J1 . 183239 -.02"17337 -..0862483 . ].68352lie* (3ii)) -8.5,9726 , !$03209 -. "IdfiB.14 ,283442 -.-, .187874 --,036229B , ;I 23942
The fi t: rel)Zrenel-iI:.[I t;he lle*(;!ll_ ) oVril3f_l _to(.!t. It)ii w:lLh _7111rlilFi dev.l.at;j.Oli of .1,6:1-,,The IllaXJ.liltilll devJ._:ll:[on .lf:t 3,9t ai; 5, OEi ();I (-_V/_:lllltl,
Tlio f l.i: rot)rof:t(_.lll;l:-i t:ho I-le* (31P ) (;.'i"oi_l_.] <n,.i(.I.Io1_'• wJ l:ll _lll I;11113clf._v.t.at; | (.iii o[: 9, I:t_t-,,The llia×:tliltilll dt:]vJ.al;],oii ;l.tJ ].B, "l-'t-, iTiL 2,7E-I 04 cW/aliitl,
The f;'.t.i: rel:JreBent:f-_ l;h(-, Ilo ^ (:1_I)) r_rr)fJf:l _iec_l: iori w:l I:11 ftll rlllFt (.h:;v.l,:lt:.[(.)11 (:Itr O, 2.&,Tl'lO IIIfAX.[IIIt.llll dov .t _11..tOli i pJ ] _l, 9_ i.ll; 2, BE-I 04 oV/'_UIItl,
i
_tT:e appel_d.l× [or C_liel)ynllev f.ll: del;a.I Iii,
@
e-6 7
Pl* + He -> HeC31S,31P,31D)
i
....ross Sectlon vs, Energy17
IU :------"_--T rr _r-r-r'n-.... i ,_:i , , , , ,'1 .........F---r--r-r-r_-n
,..fs.-- ----_.
10-le_ _ :<= He(3iS) '- q = He(3iD)
- "_,_
P'I
E
c©
o 10- _ Recommended@ .... Datac/) .-:
OF)
U')8 _
' - ...... Chebyshev Fit
U iI
10-_c /"
i
I OI 2 1 J I J [ I I LL.iJJ__L__L____LIII____L__L__LI_L_
lo_ ,lo_ lo_ ,lo_Energy (eV/om u)
r
0
' C- 6 8i
l_:xoJ, tat l_n Cro_] Sect.Lol_s for 0
I-I' + lle -> I-I_ .t-I-le*(41S,41I:,t41D)
lte* (4 i S) He* (4 ] P) , l.le* (4lD)
I_hlergy o Bne rcjy o F,118rcjy c:,
(ev/mm_) (mm_) (eV/a,l. ) (sm_) (eV/reina) (c,i _)
.1 0_.t.03 2 09E-22 1 01_.t.04 1 19E-19 20_H.03 2.21l']-212 0_+03 1 64E-21 1 5[_._04 2 63E-19 4 0E-t-03 '2,14F]-213 0Fj+03 2 98_-21 2 0E.I.04 . 3 .19E-19 7 0El.03 7.63E-2040E-t.03 2 02[_-21 3 OF,+04 3 61E-19 .l OE+04 1 52_-194 5_+03 1 70E-.21 4 0E+04 4 49E-19 I 3E+04 1 79E-19
7 08+03 3 94E-20 5 0E-t04 5 12E.-19 2 0E._04 1 18E-19] OE+04 8 88E-20 6 01!:.I.04 6 92E-]9 2 61_-1.04 1 05E-191 5E+04 ]. 34E-19 70E-I,04 'I '13E-,19 4 0l_-l-Ofl .I. 3OE-]92 0E+04 2 15E-19 8 OB+04 8 43E-]9 50E-104 1 38E-194 0E+O4 4 94E-]9 90E-t-04 9 14E-19 7 0E.I04 ] 3]E~]9
4 48+04 5.15E-]9 ] 0_4.05 9,721'.','-19 ] OE+05 ] 07E-.197 0E+04 4,01E-19 1 3E+05 [,06E-]8 1 5E.I05 7 17E-201 0E+05 2.87E-'_L9 1 5E-I05 ],05E-.L8 20E+O5 5 ].2E-20
1 5E-I.05 1.93E-]9 2 0E-I.05 I,OOE-18 4 0E+05 2 42E-202 0E+05 1,41E-19 3 0Et-05 8,79E-19 4 0E_05 2 42E-20
4 0E't05 6.74E-20 4 0E-t.05 7 84_,I-19 7 0E.t'05 1 34E-2070E+05 3.94E-20 50E.IO5 6 81E-19 ii OE+06 9 00E-21i 0El06 2,69E-20 6 0E+05 6 07E-19
7 0E+05 5 46E-198 0E+05 5 0OF,-199.01!:+05 4 50E-]91,0E+06 400E-19
ReferelloeS I 680, 685, 686, 687, 688, 689, 690 O
N.otes_._._! Nolle
Chebyshev Flttinq Parameters for Cross Sections
fie* (418) EIIlt.I1 = 1. OE+03 eV/allltl, Ellla x = ]. 0I_+06 eV/anlu
He* ( 4' P) Elllil/ =: ]. OE-t-04 eV/alllU, Elila x = ]. 0a+06 eV/al|iu
Fie* ( 41 D) Ell|t.I1 = 2. OE.t.03 eV/allltl, Ellla x = 1.0E-t'06 eV/anlu
AO Al A2 A3 A4 A5 A6
He*(4*S) -90.7744 2.47036 -2.373]5 -.112038 .549272 -.0385738 -.2646116
He*(41P) -84.4673 .568166 -.658688 -.0606377 , .061516] .0857392 -.0897306
He*(4_D) -90.3972 .468672 -J.92730 .452357 7. 32888E-04 -.125659 .29()]53
The fit represellt8 the He* (4_S) (::rosa af::cl..lol, wit.;tl ali rms devtat.Lon oil 60.6%.'Pile nlaxiluum dev.t.atioll is 217.9% aL; 4.5E+03 eV/alllu.
The [11: represent;-] the He* (4 _P) croaF.I sect [[)11 wtt-h ali rills der l.at t on of 2.4%.The maximum deviation is 4.9% al: 3.0E+04 eV/_.uml.
The fit represents the He* (4lD) or oas sect:ten wttll 6Ill rlll[_ deviation oi. 25.2%.
The IIIaxIIlluuldevlatloll is 50,7% at 2.6E+04 eV/alllU.
See appendt× [or Chebyahev Ii.|., details, O
O-69
H+ + He -> H+ + l-le(@'St¢IP,4-'D)
C-70
Total Vacuum Ultraviolet Emission Cross Sections for O
H* + He -> v.u.v. (_ = 20-140nra)
Energy Velocity Cross Section
(eV/mnu ) (cmls ) (cm 2)
4.2E+03 9.00E+07 1.05E-185.0E+03 9.82E+07 1.25E-186.0E+03 1.08E+08 1.49E-187.0E+03 1.16E+08 1.70E-188.0E+03 1.24E+08 1.89E-189.0E+03 1.32E+08 2.05E-18
I.OE+04 1.39E+08 2.20E-181.5E+04 1.70E+08 2.73E-18
2.0E+04 1.96E+08 3.00E-183.0E+04 2.41E+08 3.21E-184.0E+04 2.78E+08 3.30E-185.0E+04 3.11E+08 3.33E-186.0E+04 3.40E+08 3.34E-187.0E+04 3.68E+08 3.32E-188.0E+04 3.93E+08 3.31E-189.0E+04 4.17E+08 3.28E-18I.OE+05 4.39E+08 3.25E-_181.5E+05 5.38E+08 3.14E-18
Reference: 654
Accuracy: 40%
Note_ Values shown ill the graph correspond to values of measured cross sections
for v.u.v, emission which have been corrected for the photoelectric yieldintegrated over the wavelength range of sensitivity of the detector (approx.20-14Ohm).
Chebyshev Fittinq Parameters for Cross Sections
Emi n = 4.2E+03 eV/_nu, Ema x = 1.5E+05 eV/_nu
AO AI A2 A3 A4 A5 A6
-81.1574 .502834 -.275390 ,0508166 .00293296 -.00661360 .00122541
The fit represents the above cross section with an rms deviation of 0,3%.The maximum deviatioT] is 0.5% at 3.0F_+04 eV/ainu.
See appendix for Chebyshev fit details.
O
C-71
H. + He-> v.u.v. (20-14-0 nm)
C <ectio Energy°-' I DSS .J FI VS.I0+-" 35.0 ' ' " '''I .... I , , , _ I _1
, ",X" / ' ' , T-, , , ,,,
32.5 / \ _/ \\
3O.0 -
27.5 -
Eo25.0 -
k_/
c-O
o22.5 - _ Recommended
br) Data
co20.0 -8
(_) Chebyshev Fit
17.5 -
15.0 _.
12.5 -
10.0 " 1 I J | J I I iii 1 I 1 I I Iii
103 104 105 10_Energy (eV/a m u)
C-72
Excitat loll Cross Sections for @
He + + H -> H(n=2)
Energy Velocity Cross Section
( eV / ainu ) ( cm/s ) (cm 2)
3.8E+03 8.56E+07 5.98E-174. OB+03 8.79E+07 6.01E-175. OE+03 9.82E+07 6,07E-]7
6. OE+03 ]. 08E+08 6.13B-177. OE+03 I. ] 6E+O8 6.16E-178. OE+03 i. 24E+08 6.19E/I 79. OE+03 ], 32E+08 6.18E-] 7l. OE+04 ]. 39E+08 6.17E-171.5E+04 1.70E+08 6.17E-172. OE+04 ]. 96E+08 6.27E-173. OE+04 2.41E+08 6.59E-174. OE+04 2.78E+08 7.52E-175. OE+04 3. lIE+08 8.96E-] 75.2E+04 3.17E+08 9.30E-17
Reference: 716
Accuracy: 50%
Note These data were obtained by measuring the energy loss of the He +` ion
after collision. The resolution of the energy-loss spectrometer was notsufficient to resolve the 2s and 2p states.
Chebyshev Fittinq Par6ulleters fqr Cross Sections
Emi n = 3.8E+03 eV/anlu, Ema x = 5.2E+04 eV/ainu
AO AI A2 A3 A4 A5 A6
,74.4909 .160714 .0943278 .0580551 .0178172 .00276895 -4.72682E-04
The fit represents the above cross section with an rms deviation of 0.3%.The maximum deviation is 0.5% at 3.0E+04 eV/mllu
See appendix for Chebyshev fit details.
C-73
He* + H -,> He* + H(n-2)
Cross Section vs. EnergyIo_- 95/0. , , I , ,, ,Tr , , --r---r--_--T-m-v-
90.O - / -I A - H(n:2)
85.0 -
/--,.
_E80.O -(.3
c-O
Q "_075.0 - Recommended@ ----Ibr]taCnOoIn
070.0 -U Chebyshev Fit
65.0 - / -
.,J60.0 - a//
55.0 l L I l l l I ii L 1 I 1 1 LJ_L
103 104 105 I
Energy (eV/o rnu)
C-74
Excitat :Ion Cross Sections for O
He _ + H -> He' 4 H(2s,2p)
H(2s) H(2p)
Energy Cross Section Energy Cross Section(eV /6ural) (cnl2) (eV/ainu ) (cln2)
i. 5E+03 ]. 04E-17 i. 3E+02 9.03E-182.0E+03 6.59E-18 ]. 5E+02 1.36E-172.8E+03 4.60E-18 2. OE+02 2. ]8E- 17
3. OE4-03 4.61E-]8 3. OE+02 2.95E-174. OE+03 "7.95E-18 4.01,]+02 3.22E-174.7E+03 ]. 12E-]7 5. OE+02 3.39E-175. OE+03 i. lIE-17 6. dE+d2 3.51E-17
6. OE+03 5.82E-18 I. 0E+O2 3.60E-.176.6E+03 4.51E-18 , 8.0E+O2 3.66E-17
9. OE+O2 3.72E-17I. OE+O3 3.75E-17]. 5E+O3 3.85E-172.0E+03 3.90E-173. dE+03 3.96E-] 74. OE+03 3.98E-175. OE+O3 4.02E-I 76.OE+O3 4.04E-177.0E+03 4.07E-178.OE+O3 4.07E-179.0E+O3 4.08E-179.6E+03 4.08E-]7
References: 70], 712, 715 O
Accuracy: 30%
Note_: , The data for tile excitation of tile 2p state are (within thee×perimental error) tile stone as the byman-_ emission cross section.
Chebyshev Fittinq Paremleters for Cross Sections
H(2s) Emi n = ].5E+03 e V/_11u, = 6 6E+03 eV/6mlUH(2p) Eml n i 3E+02 eV/ainu Eulax "= • , El]lax = 9.6E+03 eV/aalltl
/
AO Al A2 A3 A4 A5 A6
H 2s) -78.9847 -.124567 .214965 -.358545 -.199857
H 2p) -76.1170 .522520 .318078 .]79576 -,09214]4 .04558119 -.0220305
The fit represents the H(2s) cross section wit;la ata rms deviation of ]0.1%.The maxiluum deviation is 25.2% at 6.0E+03 eV/ainu.
The fit represents the H(2p) cross section with an rms deviation of 0.5%.The maximum deviation is 0.8% at 1.5E+03 eV/ainu.
See appendix for Chebyshev fit de[ai]s.
e
C-75
0
He+ + H->He + + H(2s,2p)
Cross Section vs. Energy10-16 I"" I I I I I'"'}"l 1 I ' I I _ I 1 I'"1 I"
a = H(2p)
x = H(2s)/
- f/
_ - /E /o /_- /o /(j 10 -17 Recommended
--Data
Of) - _lUI _
0 - i
U .. _*\ , ...... Chebyshev Fit
- ×
0 le i ._...._ J , 1.1lJ ._ J i 1 _ J l.....L102 103 ' 10'
Energy (eV/am u)
O
O- 7 6
eExcitation Rate Coefflclents for'
tle* + H -> He _ 4 tl(2p)
Ma×welllan - Maxwelllan Rate Coefficients (Cln3/s)
11o
Ts.lp. Equal lH Tel_Ip. (eV)
(sV) Temp, 100. 200, 500. i000, 5000_ 10000, 20000,
1,0E_02 3,27E-10' 3,27E-I0 _ 6,34E-IO 1,24E-09 1,88E-O9 2,52E-O9' 1 57E-09@ 7,49E-IO_
2,0E_O2 6.98E-IO 4,12E-I0 6.gSE-IO 1,28E-O9 1,90E-09 2 52E-O9' I 56E-09# 7,48E-].0#
3,0E_02 9,74E-I0 4,91E-I0 7,59E-.I0 1,31E-09 1.93E-09 2 51E-09 A i 56E-09# 7,47E-I0#
4,0E+O2 1.2OE-09 5.65E-I0 8.17E-I0 1,35E-09 1,96E-09 ,2 51_-09 _ I 56E-O9_ 7,46E.-I0_
5,0E+02 I._9E-09 6,34E-I0 8,72E-I0 1,39E-09 1,98E-O9 2 50E-09' I 55E-09# 7.45E-I0_
6,0E*02 1,56E-09 6,98E-I0 9.24E-I0 1.42E-09 2,01E-09 2 50E-09' 1 55E-09# 7,44E-I0_
7,0E+02 _71E-09 7.59E-I0 9,74E-IO 1,46E-09 2,03E-09 2 49E-09' i.54E-09_ 7,43E-]011
8,0E+O2 1,85E-09 8,17E-I0 1 02E-O9 1,49E-09 2,05E-09 2 49E_09' 1,54E-O9# 7,42E-I0#
9.0E+02 ].98E-09 8.72E-I0 1 O7E-O9 1 53E-09 2,08E-O9 2 48E-09 _ 1,54E-O9# 7,41E-10#
1,0E.03 2,10E-09 9,24E-I0 1 lIE-09 1 56E-09 2,10E-09 2 47E-09' 1.53E-09# 7,4GE-ION
2.0E+03 2,76E-09' 1,35E-091 1 49E-09 I 85E-09 2,31E-09 2 42E-09' 1,50E-09@ 7,29E-10H
4,0E_03 2,53E-09' 1,96E-09 2 05E-09 2 31E-09 2,61E-_9 2 31E-09# 1,44E-09# 7,08E-I0#
6,0E+03 1,99E-09# 2,38E-09 2 45E-09 2 61E-09 2.76E-09' 2 20E-09@ 1.38Ei09# 6,88E-I0#
8.0E_03 1,57E-09_ 2,65E-09 2 68E-09 2 76E-09' 2,81E-09' 2 09E-O9# 1,3E-09H 6,69E-I0#
1,0E+04 1.27E-09# 2.78E-O9' 2 79E,-O9' 2 81E-09' 2.79E..09' 1 99E-09_ 1,27E-09# 6,51E-I0@
1,2E.O4 I,O4E-09# 2.82E-09 _ 2 81E-O9' 2 79E-09 A 2.73E-09 k 1 90E-09# 1,22E-OgH 6.34E-IOH
1.5E+O4 8.1OE-10# 2.75E-O9' 2 74E-O9 ^ 2 68E-09' 2,58E-O9' 1 76E-09# 1,15E-09@ 6,O9E-IOH
2.0E+O4 5,71E-IO# 2.51E-.09' 2 49E-09' 2 42E-09' 2,31E-O91_ 1 57E-O9_ I.O4E-Og@5,71E-IO#
AAccuracy: * - Possible Error Greater Than ]0%
- Possible Error Greater Than 100%
Cl!ebyshev Fittinq Parameters for Rate Coefficients
El_lin = ].0E402 eV, Ema x = 2.OE+04 eV
H
Temp.
(eV) AO AI A2 A3 A4 A5 A6
100. -41.3676 1.16527 -.I03922 -,]32163 -.0348422 -.0167981 -,00106673
200. -40.8770 .821004 -.0109340 -,127376 -,0485804 -..O120056 7,63058E-04
500. -40.2738 .442909 .00923768 -.0979]47 -.051944]. -.0]12276 .00362652
I000. -39,8495 ,187131 -,0287907 -,0768304 -.0399746 -.O0851390 .00286700
5000. -39.8387 -.195041 -.IO4148 -.0404533 -,0115750 -,00220721 -2.40196E-06
i0000. -40.7661 -,170203 -.0865943 -.0313220 -.00824330 -,00148203 -7.88573E-05
20000. -42,1667 -,113121 -.05794_I -,0213073 -.00583215 -.00116246 -1.36085E-04
Equal Telnp. -41.3902 .353784 -,866]54 -.123235 ,00687538 ,0519228 -.00558678
See appendix for Chebyshev , f tt d_.talls
c- '11
0He+ + H->He + + H(2p)
L
C-78
fie + .t I1;_ -;' I I([,ynlan-+,,t_ylllal]-D)
+1-1(bynlan-c, ) 1-1(l.,7malt-n ) ,..
l]llle rc.j7 Cross ,g(-'JCI: :[ Oil I!llle i:cJ7 (..'tI::lEiEl _{_17t: .l.Oll( _.V/alil{I I ( C;lill ) ( eV/alilti ) ( till 2)
7,71_.i.00 4 331,1-18 i, 217H.01 :I 06[_I-:I.8B, 0B+00 5 :l6t_- 1'_ 1, bI_;-i01 2 15 I_-.i f]1.0 El.,-t+01 :l 05 t_1-11 2,0 I!.l-t-0:1 3 6f.11_-:lB2.0B,4.01 3 39B-..17 3 01_.i.0f 5 821.P,-.IB4,0B4.01 5 511_-:17 40l]]+i,01 7 07L+-ll]7.0B+01 6 1917l-:17 5 01++01 7 Bll+-..t81,0 !_+02 6 0 :LI,.1-17 6 0 tj:-i.01 8 2;l I_- :l82,0.B+I'02 4 571!I-17 7 01.",.I.01 8 571]l-:184.0 l_-t.0 2 3 56 Ii;- .1.7 8 0l!;-t.0:1. 8 64 I;t- ;1LI7.0E+02 3',20F,-;17 90E-t-O] B 561_-]B1.0 E-t.0 3 3, ] 31t',- 17 i 010-t.0 2 8 4 6171-] 82,0 g +03 3,3 5 I_- 21.7 1 5}l]',-t.(}2 '1 6 7 l_- :l84,0E-i,03 4,45F,-17 2 0171-1-(}2 6 78l!1-:L85,0 t_+0 3 4,6 1I_',-177.0B.I+03 4,53E-:177,4E+03 4,481j1-17
_rei]cesi 188, 195, 199, 700
Accuracyi 40%
..N.OteBi ( 1 ) The [,7nlall-(_ tl:al'lSitJoll ].s at 12], 571]111 alld tile /,7lllall-/J tralls:Ltiol] :l.sat 102.57nra, ( 2 ) Data oil pol.ar:l za|:tOll oi ellliSF3J.Olla Iilay be founcl ill 1Bier aridNathan (Ref. 199) and Youllcl et al. (Rc_f, 700).
Chebyshev Fittlilq ParallleLers for Cross Sections
li ( [,ylllal] -'n ) EIIItl] = 7.7B-t.O0 eV/allltl, t!;lllil× -: "7.4f!I+03 eV/alllLIFl(l,ylllari-B) EIIWI.Il = I. 21_+I-0.[ eVI_ulIU, gllla× -"' 2. OE-I'O2 evl_lilltl
AO A:[ 62 A3 A4 A5 A6
H (l,ynlal]-c,) -76.0522 .584543 -.527735 .5870B5 _.202654 -.0240480 -.0420581H (byman-8) -79.7592 .790251 -,524833 .]14100 -,0482"161 .0226572 -.00698738
The fit represeilts the H(b_llat].-u ) cross sect:J Oil w.t.t:h ai] rills deviat.t+on o.f 2,5%,The iIlaXillltllll dev.t.ak:[on .tB 3,5% at '1, "7E-t()0 eV/_.IIIILI, _-
The fit rel:)i:eset+lt:s tile H( L,ylllall-.£1) c:i:oas sr.-:ct::[ol] witll ali l:ilif-s devt at:i(:>l] of O. 5%.The lllaXililLIIll devJ atini_ Js 1.0% at: 6, OF,-t.01 eV/miiu,
See append[× for CllebyrJliev Ill: de.t:a.t]._,
E
}
(_- '1.9
He+ -t- k-lt--> I--i(Lyn-lan-c_,Lymarl--f.b
_--_-" ..rgy(::l-,:,ss.::,u.ctlol-ivs. En_....}0-I_ 1--T-rTT-rq--'-r--r-r-r-r'ml .... i ,- r--rTrrrF----T---r_--r"r-rl_
10- 4__L.Z.4,11JJl 1 I I 111,LLJ._, 1 1 1 L4JJJ
lo° 1o' lo_ ld_ lo'Energy (eV/aBU)
,I
l
(_-[tOr
" " C_L.X._c._i: lm ]. l,J.t le 1,111.1I:1Lt] o11 t:c)[1f-.I Sect ].OH_ f:Ol
l.le_ 4 II,_-> ll(l:i_.l.ill_r-_ol]al,iller-/])
ll(BaIme L_-.) i.l(l!m].m_I._-0)
_11(9L'(.j_ CLOHFI _(:i(.:tt..Loi'i I]',H(:_l:_jy CL'OU£1 _O(.:_L.[(ill(eWlamu) (_111_) (,vi alllU) (c::111z)
.L 0_-I.0] 8,811.1!:-:I9 .I 51!',.I()] 2, O01_v',-:I92,0E+01 4 ,79E-:IH 2 0l.,i'-I(.).I. 5,60 I!',-.I9
6 " P " . $4 0I_-I"01 7 .l 8 I.,- .IH 4 0I!:'l0 :l 'I. 3 3I]', .I87 013-1'Oi 6.361!',-] 8 5 01!I-IO:[ I , 4 :II!',-:I8
p •i 0121'1'02 5, ] 6PI-].8 "I 0I.,'I'0 _I. I 34 L!',-I LI, I" T'2 O12]-1.02 3 O9E-]8 .[ Ol!',r(}2 .I .LOI.,-I.8
40E+O2 2,26g-Lt} 2 ()l_',-t02 5, '_u0 I.,- 19"10 E402 :L,99 I!',-.I8 4 O1!',t 02 3,4 "11!:- .l 9] OEt'O3 1,93E-]8 "/ (Et02)' 2,98E-1192 OB-r03 2,12E-18 .10E403 3,.12E-t940l_-r03 3,OC)1,]-]8 ' 2 op].103 3,91I!:-119l Oi!',.t03 3,391];-18 4 ()1!',tO3 b, b61!',-.1910lg-l.04 3,291!',-].8 b O1!',+O3 5. IBF,- 19
"10 g.t.03 5,2 f-IE- :L980 I!',-rO3 4,8312;- 19
RR_.[_lce8,_...__l 166, 199, 461, 464, 693, 69'-I, 695
,Accur acy t l.Jilkt_own
Notesz (I) The Ba.l.l]ler-c, _ml:l.eIH._(._ll :l.s [i:oi11 the 11=13->2 t[allB:Lt.l.ol] ( 656. 2111"1111). ( 2 )The l..la]lller-P elllJ.Bl-J:[.Oll I[I frC)Iii tlm 1I=4->2 l:ran_]:ItJoll (486,.LSnlll), t:]) Data OllL)O].arlzat:[ol] of elllJ.ss.tOllS may he fOtllld :li1 Isle[ al]oi Nathal] (Re.l:.l:4, 199 al_C[ 694), It
C!mbyuhev 1_"tLLI ngl F'al:allle Le r B fol: CL'OSel SectlOliB
H(Ba].lller-c_) l']ln.tn -_-'. I, Ol!;'rO.I eV/ainu, Ema× = .l, OE-t04 eV/_ml= , _ _' ' = 8, ()1!]-I'03 (_V/alUtltl(Ba].lller-.fJ) EIIIJ.I 1 ] _I.,'I0] eV/allltl, ElllaX
AO AI A2 A3 A4 Ab A6
I-I( l]ahue r-_ ) -80,7189 ,O329782 -,J73449 ,60831]] -,365301 ,01179.L38 -,O168644" _ , 662311 -, 4136982 -.00"'::1445 479Fl(Ball]ler-fJ) -84 11,448 -- 135846 OB2()8.].._ 5, , -, . -_2 -, O131
The .,I-ltrepresent:B t:he H(LiaJ.Iller-,) c[oss sc_ct;l.on w:Ltll an rm_ devtat:.lc:)v_ oi 2.2%,The nlaxlmum dev.t.al:J.Ol] :lH 4,5% al: 2,01];.r02 eV/altar,
'l'l_e .[Jt: represetlts the It(Ha]mer-_) croae_ r._e¢-:t:ton wit:li an rms dev.lat::l.on of 2.9%.The iI|a:)fillltllll deviat:.t.on .Is 4,9% at: 4,01!].t 0.l eV/ainu,
See apperlcl:ix for Chel-)yshev t:.l.l: d(_:t:a :l .Itl,
c- I._.i
O
He+ -t- i-I2 --> H(Balmer-_, Balmer-/_)
O
C-8 2
O•_ ._ .D.[ssc)c,:LaLive L_xc_.ltat 1Oll C'rt)s_l SetL.IollS fol:
tie' .t. 112 -> lie,' ;t. 11(2_J,2p) .t. II(Z)
H ( 2_J) H(2.p)
E11er_ly C!t OEIB Sect,.ioll El]el:'gy CITc]t_ts Sect J.Ol_( oV/ailiti ) ( till _ ) ( e V/aliiU ) ( Clli _ )
1 410+03 4 92F,-;18 .1 3g-lO1 2,:L;L_-17.1. bE.F03 4 93E-18 2 0f_:1-01 3,621_-_171 7 g-i-03 4 9 :l t.,- l [3 4 01.'I+ 01 5,59 I,.;- 1 72 0I!H03 4 92_-_1B 6 0t_-t01 5,El11_-122 5B-t'03 4 93E-18 70I_.HO]. 5,80t!],-].73 OB-lO3 4 91I_-;18 1 0t!1'1-02 .)", 61E-173 5N+03 4 93E-18 20F,-t.02 4.75E-174 OB-t.03 4 91B-18 4 015-t02 3,75P-174,'51,34.03 4 91[_-.[8 l 0I_4.02 3. 311]1-1.'1b,OE4.03 4 91.t,.I-.18 ' 10F,-I-03 3,24g-.t75,5Bt03 4 91E1-113 2 0I,'J.t.03 3,32I_-]76.0E-103 4 91E--18 40FA.03 3,731_J-1"16 4l_+03 4 921?, t8. '.. 5.0_-t 03 3,81 l_- 1.7
7,0 l!;.t.03 3,7 5 IJI- 17I. 4 I_-r03 3,72 I_- 17
Referellces I 183, 1915 700, 701, ,,, ,, t
Accuracyl W.tth.L1l a [ac:t:ol: of: '
Not;es I ( 1 ) The e×ct tat.ion crosEl aect.ioilsl tor H(2s) and I-1(21.)) aredeter[i{ined by the field-induced ellltsslorl of 5ylllall,c, (2S -> 2p -> lS)0 arid Uby hynlan-rx emission (2p -> ls), respect.tvely, If cascade can be negl.ect:ed,these are equa.1, to l:he cross sections for tlm formation of the H(2s) anctH(2p) states, (2_ Tile notation lt(t:) ciesicjnat:es 'al.|. possible st:at:es for tileother 17ragment: (unspeclfied),
Chebys!.iev F.ttt;;l.ll£L parailleters tor Cross Secttiol,S
H(2s) _nltn = ] ,4E-i-03 eV/allltl l# = 6 4E-t-03 eV/allltl= " _ i # :'lli61X '
H( 2p ) t'.]lll;t,n 1,31.,,-.O1 eV/aiuu, F,nla× = "7,4E+03 eV/ainu
AO A1 A2 A3 A4 A5 A6
H(2[_) -79,7066 -,O01602B2 l,SFJ249E-05 7,60977E-04 2,44985E-04 6,18338E-04
, , " ,,r , .)B9.) -.0206130 .-. 009839'13H(2p) -75 6225 O09620.,.) - 178354 ,293814 -,ll" r
The fit: repreaent:a t:he H(2s) crcms _ec:t::lon wit:l_ an rms deviat:lon of 0,1.%.The IllaXilllLilli dev.t.at.Lon .[ s 0,2% E!L; ], 01!',.t.03 eV/allltl,
The [lt repre.sent:s the H(2p) cross rmct:J oil wit:li an ClllEi cleviat:Jol_ oi' 0,8%.The IllaXillil.llil dov.t at.l.Oli l.s 0,9% at; 7.0l_-t.()] eV/aliltl,
See appencl.t× for Cllol)ytihev lit det:.at.ls,
O
He+ + H2 -> He+ + H(2s,2p)+ t-ICE)
Cross Sectionvs. Energyi 'l I I I 1 1 )"l' I I ''T-"_- i i-i i i ...... I I "j ''1' C-FIT"-
-._ j/'--'m_ × = H(2s)
tN
Eq)
x,,_,../
c-"0
0 "_ 10-17 _ Recommended(1)V') _ Data
oq
U _ >_ _ Chebyshev Fit
10-18 .. I 1 I L_L_U_EI__L, I 1 I 1 ! 111 ___ I . .1 I,_LJJ._U
10' ld t0s 1¢Energy (eV/cimu)
C-84
Dissociative Excitatfoll Cross Sections for O
He + + H 2 -> He _ + H(3s,3p) + H(z)
H(3s) H(3p)
Energy Cross Section Energy Cross Section(eV/_l_u) (cm 2) (eV/al111) (cm 2)
2.5E+03 2.16E-19 2.5E+03 2.36E-183.0E+03 2.28E-19 3.0E+03 2.29E-183.5E+03 2.34E-19 3.5E+03 2.32E-184.0E+03 2.37E-19 4.0E+03 2.41E-184.5E+03 2.37E-19 4.5E+03 2.55E-185.0E+03 2.35E-19 5.0E+03 q.70E-185.5E+03 2.33E-19 5.5E+03 2.77E-186.0E+03 2.28E-19 6.0E+03 2.76E-187.0E+03 2.19E-19 7.0E+03 2.56E-18
7.6E+03 2.29E-18
References: 183, 702
Accuracy: 50%
Notes: (I) The H(3s) and H(3p) cross sections are deduced from spectral-emission measurements on tl]e (unsubstantiated) assumption that
cascade can be neglecued. (2) The notation H(z) designates all possiblestates for the other fragment (unspecified).
C__hebyshev Fitt/nq Par_ueters for Cross Sections O
H(3s) Emi n = 2.5E+03 eV/_uu, _ = 7.0E+03 eV/_uuuH(3p) Emi n = 2.5E+03 eg/_l_u ,:lllax= 7 6E+03 eV/_l_u' -III HX "
AO AI A2 A3 A4 A5 A6
H(3s) -85.8579 .00631068 -.0437007 -2.23538E-05 -1.27246E,04 5.58521E-04 6.28175E-04H(3p) -81.0948 .0512586 -.0390305 -.0692130 -.0155312 .00341300 -5.63877E-04
The fit represents the H(3s) cross section with an rms deviation of 0.1%.The maximum deviation is 0.2% at 5.0E+03 eV/6ullu.
The fit represents the H(3p) cross section with an rms deviation of 0.3%.The maximum deviation is 0.5% at 6.0E+03 eV/_llu.
See appendix for Chebyshev fit details.
O
C-85 i
Q
He,* + H2 -> He+ + H(3S,3p)+ H(>-)
Cross Section vs._Energy.. IU "l , ' '' , ,' , , . , ..._
a H(3p)
x - H(3s)
,, _-.-------. _tI__ -
I.NE.0
c-O
"_ 18o 10- - Recommended(1)
£/3 _ Data03O00
l__ _ - .... Cnebyshev Fit
10-19 I I 1 I, 1 l ,, ,__
103 IGEnergy(eV/ornu)
C-86
i •Projectile Exc_tatlon Cross Sections for
He + + H2 -> He+(2s) 4 H 2
Energy velocity Cross Section(eVlamu) (cmls) (cre2)
2.5E+03 6 95E+07 ].38E-20
3.0E+03 7.61E+07 2.18E-203.5E+03 8.22E+07 3.25E-204.0E+03 8.79E+07 4.58E-20
4.5E+03 9.32E+07 6.18E-205,0E+03 9.82E+07 8.10E-205.5E+03 1.03E+08 1.04E-19
6,0E+03 1.08E+08 1.30E-197.0E+03 1.16E+08 1.92E-19
7.6E+03 1.21E+08 2.31E-19
Reference: 706
Accuracyz Factor of 2
Notes: None
Chebyshev Fittinq Parmueters for Cross Sections
Elllin = 2.5E+03 eV/_llU, Enlax = 7.6E+03 eV/anlu
AO AI A2 A3 A4 A5 A6
-88.6255 1.42095 -.00467445 -.00728965 -,00322271 -.00472755 -3.43794E-05
The fit represents the above cross section with an rms deviation of 0.1%.The maximum deviation is 0.1% at 6.0E+03 eV/_llU.
See appendix for Chebyshev fit details.
C.'-87
Q
He* + H2 -> He*(2s). + H2
(._.IL..-..._o....,_'_-Section vs, Enel-gy-18
I0 , , " , , , , , ,
- a - He+(2s)
IN
E(D
c-
O '_o 10-;9(D - RecommendedqP _Ootac/)m
8L) Chebyshev Fit,
i
10-_ l I i 1 , I ii, , ,io_ lo_
Energy (eV/am@
C-88
Excitation Cross Sections for O
l-le _ He -> Fie+ + He*(218,21P)
He* (21S) lte*(21P)
Energy Cross Section Energy Cross Sectioll(eVl a111Ll) (C111z) (eV /aJ11L!) (ell|_')
7.0B+03 2.98E-18 6. OB+03 9.41E-188. OE+03 2.41E-18 7 .OE+03 7.3 IE-189.0E+03 2.03E-18 I. 0E+04 4.60E-181 .0E+04 i. 76E-18 ] .5E+04 2.90E-] 8] .5E+04 i. 09E-18 2. OE+04 2.52E-182.0E+04 9.39E-19 4. OE+04 4.97E-182.5E+04 i. 09E-18 7 .OE+04 9.22E-183 .OE+04 i. 41E-]8 ] .OE+05 i. 08E-17
i. 5E+05 1.13E-172.5E+05 I.07E-]7
References: 203, 684, 697, 699, 704, 705, 707, "717
Accuracy: 40%
Notes: (I) For relative cross sections see Re fs. 697 705, and 707. (2) Forcross sections He+(is) + He(is2)IS -> He+(is) + He(is2p)1,3P see Bordenave-
Montesquieu et al. (Ref. 704). (3) See Thomas (Ref. 684) for more details.
Chebyshev Fittinq Pareuneters for Cross Sections O
He* (21S ) Elllin = 7.0E+UJ eV/alllU, Elllax = 3.0E+04 eV/a]lltl
He* (21 P) Elllin = 6.0E+03 eV/aJllu, Elllax = 2.5E+05 eV/a]11u
AO AI A2 A3 A4 A5 A6
He*(21S) -82.0676 -.438515 .304992 .0789808 .0643720 -.0146204 -.0063977"7
He*(2*P) -79.0520 .385720 .388654 -.432765 -.004"74225 .126047 -.0106668
The fit represents the He*(2*S) cross section with an rms deviation of 0.0%.
The 111axilnunl deviation is O. 0% at ]. OE+04 eV/rural.
The fit represents the He*(2 IP) cross section with an rms deviation of 3.4%.
The maximtml deviation is 5.8% at 2.0E+04 eV/aim].
See appendix for Chebyshev fit details.
C-89
t
t-le+ + He -> He+ + He(2'S,2'P)
Cross Section vs. Ener9y-16
. _ - He(2'P)
x - He(2_S)
10 -17 _IN
(D - "I
C:
O O - "_'+---; Recommended(Dq) _ Data
0")©_- Chebyshev Fit
U 10_18_
10-19__J i i J [litl l 'i I I I iill I i i I illi
103 10" 10s 106Energy (eVJQm u)
C-90
OExcltal ion Cross Sect lolls for
He _ + He -> He 4 + He*(23S,2_p)
J
He* (23S) He* (23p)
Energy Cross Section Energy Cross Section(eV/allltl ) (Clll 2) (eV/mlltl) (till 2)
6.4E4"03 2 •82E-18 6.5E+03 4.4 9E-187. OE+O3 3 •22E-18 7. OE+03 5.91E-188. OE+03 3 •92E-18 8. OE+03 8.72E-189. OE'I'03 4.57E-]8 8.4E+O3 9. lIE-J8in 0E+04 5. O7E-18 9. OE+03 8. ] 9E_18i. 5E+04 5.8iE-18 i. 0E+04 5.45E-182.0E+04 4.77E-18 ]. 5E+04 3 •23E-182.5E+04 3.38E-18 2. OF,+04 2.53E-183.0E+04 2.20E- 18 2.5E+O4 2. OIE--18
3. OB+04 i. 18E-183.2E+04 ]. OOE-] 8
References: 61"7, 684, 697, 699, 704, 708, 717
Accuracy: E < 7.5xi0 _ eV/amt! - 75%E > 7.5xi03 eV/ainu - 40%
Notes: (1 ) For relative cross sections at lower energies see Bordenave-Montesquieu et al. (Ref. 704) and Dworetsky et al. (708). (2) For crosssections: He_(Is) + He*(Is) -> He+(Is) + He(is2p)l,3P see Ref. 704. (3) For moredetails see Thomas (Ref. 684).
Chebyshev Fittinq Par_ueters for Cross Sections
He*(23S) Emil] = 6.4E.I03 eV/allltl, Elllax = 3.OE-IO4 eV/alllU
He*(23P) Eml n = 6.5EI03 eV/_u1|u, Ema x = 3.2E!04 eV/_]|tl
AO AI A2 A3 A4 A5 A6
He*( 23S ) -80.2166 -.0867600 -.430158 -.O323601 ,00266805 -.00483153 ,00172788
He'_(23p) -80.5638 -.8972"75 -.226853 ,0854789 -,228846 .0840]60 .0168192
The fit represents the He*(23S) cross section wit:li ali rms dev:latlon of 0.]%.The maximum deviation is 0.2% at ].OE+04 eV/ainu.
The fit represerits the He*(23P) cross sectiol] with all rms deviation of 6.8%.The maximunl deviation is ]4.1% at 1.0EI04 eV/aullu.
See appendix for Chebyshev _it details.
0
C-9.1.
@t-le+ + t-le --:> He+ -t- He(2_c<c'3P)
C-92t
l_xc I t:at,l.on Cro_se_ Sc_t: .tOllfJ for
tle _ -r lIe -> lie _ .t I-le_(31S,31Pt31D )
I-1o* (31S) 'fIe* (31 P) Ile_ (3lD)
Energy o , El]el:cJy ' o EIH:"rCJy o(ev/_uu ) (c_m_) (eV/aluu) (oiu_) (eV/am) (r_'.l_)
30E+O3 2,96E-]9 1 8E-IO3 4 84E-.i9 2,51_.I.03 3 98F,-]93 5F,-I.O3 2,78F,-]9 2 OE+03 5 24E-:19 3,O1!I+03 5 ]6F,-193 71LIO3 2,75E-]9 3 5F,.r03 6 6]I!',-.19 4,OE-I03 8 2 r-,_,__[!,-,:l.94 01]]-1-O3 2,938-].9 4 01_-IO3 6 50E-.[9 5,0E-I.03 1 O2E-.[B4 58+03 3,33E-19 5 0E+03 6 28r_,;-:19 6,01!',.i.03 ] 04E-.t85 01].,'-1.03 3,64E-]9 I OI!H.03 8 ]9E-:[9 7, OF,.103 ] O31]]-:185 5E+03 3,8317,-19 9 01.,I+C)3 9 ]8E-;L9 7,6E-I-03 :l ()2E-186 0E-I-O3 3,98[_-19 ] OE-IO4 9 O4E-]9I 0 I_+O3 4, O3 F,- ;] 9 I 5 I_-IO4 6 73 I!',- ;[ 9B 0E4.O3 4,02E-.]9 2 0F,404 5 62E-19
40F,4.O4 ;[ 49[,]-]8"I 0 F,404 2 34 [._;-..IB:1 01_+05 2 B.IE-;[8:I 5E-t-05 3 07E-.18
' 20[,]4(J5 3 3.41_-1830EIO5 2 90E-18
Refereilces I 204, 696, 697, 69B, 705, 708
Ac,,curacyl30%
Notes l (]) For re.l.at ire. croill_l sect'.lOllS 6it: .lower ellOl.'cjJ.6#s f.tc:e Refs , 69"1, 705 ' /slid 708. (2) For lliore details s6_e Ref. 684, (3) Acceptable polyllOlllia] fits werenot possible for tile He*(31P) data.
CI]ebysliev Vtttirlq ParalileLei:[:l for Czo_l Sect;:l.ons
lie* ( 3'S ) Eiilill :: 3,0E-t03 eV/allltl, F,llW:lx :: [I, (]E.t-03 eV/allltl
fle* (]ii]) Enl:l.i ] = 2,5E-t.O] eV/alliU, Eilla)_ = 1,6E-i.0] eV/aliUi
AO Al. A2 A3 A4 Ab A6
He* (3iS) -85.0346 .210040 -. 00809700 - 06.[8979 .O267187 .00449587 -.0321214
lle*(3*D) -83.4873 .49.1131 -.]74973 -..O270949 .0308684 .00653934 -.[)0951236
The f.t t represents t:he tie* ( 3iS ) creels sect:] oil w:l.Lll ali l;lrlttl deviat.t orl cir O. 6%,The lllaxillltllU deviatioll iEI 1,2% at 3,71i',-i03 oV/allitl,
No fit: t;o fle*(31P) data,
The tT:l.t: rc_presel]t:s t:ho fie* (3tl)) cross filoCt:.toll wJ l;ll ali rlllt_:l d_:_vial: lori o.f O, 0%,The Illa×illlUlll tier]at:[eli t.s 0,0% aL 0,017_,i-t00 eV/aliitl,
See aPtmi-ldi)_ f.ol: Cliebyshev ! l I. dc:_tal, if:l,
0
(:!.._:1
He+ + t-le. ......::,He t --t-.t--le(3_S,31Pt.3iD.')
i ..... I .... o
( i-,lS c " t_,L.[IE.)I-I "--' @/-Cj.... :, .:,='...."" vo, Ei-I y17
'1© - '_ , , -_-r-l-rr_-_--r--T--rr--r-r-m .... 1----r--r-T-r-r-rr
A : t-le(3_D)
× : He(3tp)
- _ q = He(3'S)
C2©
'._ lao 10"' - Recornmended¢_ - -__ Data
o'1u1 .,0 ' "'---J"
U Chebyshev Fit
'10-19 _ 1 i J i JJHJ__.__L__L___LJ I t I i 1 _1 _.L_L__LLLL
lo:' _o' lo_ lo_Energy (eV/a m u)
c',. 94
I!',XtJ[I:ilL [(111 (.!lT(;)filH 8;{_(.!1..[C)llt:l [(i_1 i
Ihep' .t. II/:, -.::, Ilii! _ t II(:i_ (..1;I,q, 3_1,_ .11l))
ills* (3;'8) IIo* :,I:'I') lh:,* (:I'II:))
[-",I1_ i' cJ_p c, l!',lII._r c:.iy _., IgI 1(_,r!;ElY C'
( eVI_LnlU ) ( _'ill _ ) (_V I_:UUU) ( _'_lll_ ) (_:V lalnu ) ( c._ill_ )
bl!l.l.03 6 2.1.1_-Ig 2,51!1102 20bl!',-.19 2 '#_I]',i.02 I 4.CJl!l-.lBI 01_.I.03 !_ 841!I-]9 3 21;4.1-02 .I B.c.II!l-.19 ] 'II!H02 .I 231!I-IB3 51_-l.03 b 93L_-;L9 4 0_',.l,02 2, ;191!',-i9 4 01_Ii.02 1 241!',-.Ifi4 01!I-I.03 6 5fll_l-;L9 70l!',.i.02 3 2131!_-19 6 01_-I02 ii 441_...If.I4 bl_-t03 7 441!I-;19 "1 41_t0J7 3 301!I-.19 7 Ol!Ii02 .1 lBl!l-Ill50I_],iO3 13 491_-19 ;I fJi!J.t.03 1 931#l,-I.9 .10l_'.i.O3 9 '141_-19!i BI!].t.03 9 2].l!I-]9 ,I. ] Ii',.t{i;I ] 7111!',-19 .l bt!',-I.O3 l 92111-] 9
' 60 l_-t 0 ;71 9 {t 71!I- ;[ fJ 1 !._Ig.i.03 71 ] 7 I!:-. i 9 20 I!I t 03 90 7 I_',-I _J'7' OI!l.t.O3 .l O!]I]]-.I.B 20l_.l.(J] 4 301!I-.19 3 01,.I-t.03 'l f) tJill.- .i _-J7 7 I!I-t.03 l (IB!#',-,;i{1 ;t 7 I!',-t.0 3 b 7 li I_- I 9 40 l_-i 0 i-I 9 !i 0 I!I.- I 0
40l_-t,('J.3 b (;!)R-I9 (i Ol!_.l.O..l 1 471_-;111 ,!$ 0 I!]-tO;i b ] 2 I!]- .1.9 7 0 l!l t O3 ;1 3 0 I!I~ ;I I.I7 01!]103 6 (]BI]',-I!J { 01!',-I,O4 B 731_)- 19I (ili;.iO4 9 B!$Id:-]9 2 O1_,104 3 361!_-19.1 2,1!HC)4 .[ O'/l!)-.lll 4 O1_.t04 I 3BI_-1.92, O1!i-t.O4 I1,, .19R-l 94 O1_-I04 4, Obl_l-,l 9
It .n.£e lei_{_e_t I 204 _ 696, 69'1 _ 70b_ 70'/_ I()B
AI_c t,ll: (I ,_,7L I.Illk II[JWll
iiNolsea I (1) Re].at:t ve e:_['c__l_s _le,ct lc:_n_s illay be# [ouil(;l :l.xl Ilel:a, 69'7_ 7()!_ _ '107_ ailcl"_08, _-( 2 ) Aont.lramiet.:i i:epol:l;_Jcl til It{#l;'_, 204 _ill(:l 696 __liti!l EtyFlt:f.-_.lll_il;[C_ (:trite.lr < [O%1
f_lldOlll error < 5l Ol1 eaoht tlc]W_-wei:_ re.f._tl]t:rJ el.lfr, el: by _1 If aet;or elf 2 al: i.:iC}llleeller.f.jj.elC;l OOllllllOll l;o bol;h e_pl_r,'l.lllt31ll;l_i, ( 3 ) Acc'_:_pl;iible t.)o1 yllOlll;la]. [ Ii;til l;cl t:ll/),I-I_*(3_1 'j) allcl l-lt3*(]_D) c]_"ii;f.I wer.'[-._ llnl lJl)lil-I:ll)I.t_,
_el:ly_llle v F'J.L;L]liC I [_lr _illle L(7!I; l;i [o[ [', ro _ f.i <elrdc:L .[.Ollfl
Fie * ( 3 :_ ) I!;llI] II 7, bl_l 03 c'V/allltl, lglllC_ 7 71, '03 f_,V/_llllil
AO A.L A2 A:] A4 Ab All
Ite*(3_} -.[13,406J ,336147 ,O620301 -,O'lfi3959 -_, 00323 13{3 ,016947!;I -, O019264!_I
'l'he 17.tI: repreBelll;B l;lle I-le* ( 3:18 ) (:llrLIHei f_._cJt:.lon w;l i:h _.111 l:lll_t clev l_lt:i.rJil r.l! O, :.1_,Th(] IIl_iX.[lllUlli rJev.l al; ;[oil J.l!J O, P.]t, al; 4, bl_-t O] _V/_lllltl°
Nc_ fit: i:o 11o*(3:_P) del;a,
No [].I-. t:o I+le_ (3lD) civil;a,
_ee _tt)pf-_ncl:l× [:oi: (._tl_-_l_yFJll_V !.1 I: tlc, t.a.I 1_,
lt
C?-t)B
3 3 3 ,,)He+ -t- Pie --:::', t--le" + PIe(33S, P,3" D.
IN
E
,s \ '_
i
c-
O o 10-1 .-. Recommended
" r) _Data09 -
0 - 'U _ Chebyshev Fit
10-' ___L--L_LL,,,, i .! 1 LLJ._LLI 1_ I ,__J_ .__ I J J JJ
_o_ Io_ lo" lo_Energy (eV/o m u)
O
d
c- 96
I!:_(_[ t:at: | oll Crr)H[J _(:,('t:Jorlt4 [of O
Ilr_ t i lie -> lie _ i 11(-._*(4i_i04i1_,4i1.))
lie* (418) iIt_* (4 t l') I1(!_*(4 l l))
l_lle 1:cjy cJ 14;ill_1.cj y (_ L,IIu::Lcly o( _V/allltl ) ( CJlll2) (eV/allltl) ( (!111<) ((_V/alllU) ( (!111_ )
5,O1_-1.02 '7 341!;-2.1 3,Ol!1.10] 2. Oil!', 19 2 51P,t()2 I.l,.]91!l-2,()5, {3l!l-t-02 6 87 I_- 2.I t, 5I;l.iO;I 2 631;',- 19 .I OV,.iO2, 9,3 5V,- 2070 l_-iO2 fJ 2I]V,- 2..I 4 ,' OF,+O3 ?. 9 ) I.:--].9 3 5l;l,I,O2, 9, J81!:- 20! OI_.i-0"1 I 4 9In- 2,0 4 5I_-t.03 ;I O'11_- I 9 4 0l!l.t.0 2 {I, z,",,o1!',.- 20
it . ) i_ " + t i'_I 21!;+O3 [ {l.11_,-20 50l_-i.O.] 2 (:i51__19 5 (l.,-.(J2. 6 4li_, 2,0.1 51!:-t03 .i 721,.1-20 b 51.,I-tO3 2, 7OL;',-.19 (; O1_.tO2 5,931_-2020B#03 3 22E;-20 6 ()1_iO3 2 44F,-J9 "l OI_q-I-OI 5,9212-.20
ii " 1'2 "l_.t.03 4,40_I-20 6 61.,+C)_1 2 ;I._1_,-.I9 .I 01_-tO3 6 '/.t.)I_-2C)3 5F14,03 4 211_-20 70l_,l.OJ 2 43F',-.J.9 ;I r._,:_l.,.l.O.#- 6 27f_1--2C)4 0III+O3 4 2"/t_- 20 8 C)1!;-iO3 2 {I 2F;- .l 9 20 l;:.tC)3 7 ;15F;- 205 O1_-tO3 4 921,_'I-2,0 9 01!',.t03 3 .I2.[_:-19 30P,-I.O] ] 031J',-.l9
• ) ,_ " 55I!',-- 96 01_',I'0] 6 041_-20 I 01!',I04 3 :191!',-:19 4 (.I.,I0.I .I .I'l C)1!','tO3 6 " _' 2 4._BI.,-20 .1 5F,IO4 601'3-._19 7 Ot7."1tO3 IOI!:-.19.i., 01,]-I.04 9 651!:-20 2 01#:-I.04 2 1llg-.[9 f] 51!3i.03 4 921_:- 1.9
, l+;I 31.,+04 .l .171!; Iii .10l_;.iO4 4 3.11!:-;192, OF,-iO4 9 491_'I-20 ;I 51_.i.O4 2 021!',-:194,0I_i04 2 371_-J9 2 01!1.1.O4 .1 2]I!;-L97, Ol_-i-O4 2 99_- J9 2, 3Iii-i.O4 .I .161!',- 191,0 l!:t C)5 2 l]2V,-] 9 3 01!',-t.O4 I 716I_- ;I92,0 I,G.i0 5 ;I 95E,]- 19 4 (.)Ii:.I.04 ] 74 i!',-- i 93,01_-105 ii 411_:-.19 5 5E-I.04 I 901_-19
7 01!:-I.04 I fJ21!;-.19J. 0I!',-I0 5 I !$J I!;- .I9I 51!',405 .1 IOE--.[92 O1{',-tO5 13 421!:-2(J30 f!:'iO5 5 94 Ii',- 20
Refe[etii:;esi 204 _ 696, 69[i, "103, '105
Acmu[acy I tJl]krlowil
Notesl ( J ) Re].at;[ve ctoss sect; J.OIIIL4 Illay I;]e it:itllld iii Re [, 705, ( 2 ) Acc;:tll-acJJ.c-JEtreporiTed irl Refs, 204 arid 696 ai;ni f_yiiteiliat;.t.c ei;'rof .< ]0% ; [ai]dolil ei-rol; < 5%Ol1 each} however, rSsultl9 di [J:er by a factoi: of 2 at: SOllle enelrcjies co111111Olll-.(-)both eXperilllelltB, (3) Aoceptable l;)oJ.yilOlll.ia] fits to the tie* (4lD) data were notpossible,
Cl'iebyahev l_'ltt}.llcl Pal:alueLel:rJ .[oi.- C_oss Sectl.olls
lle* (41S) I_111;[I1 = 5, Oli:t 02 (!'V/ allltl _ lP = 3 O1']-tO5 eV/alll[I"lll_.lXHe* ( 4i P) EIII.[II =: J00 .F.,-tOI eV/allltl, l'_lUaX _-- 2,0l.,]-t.O4 eV/alllU
AO A] A2 A3 A4 A5 A6
lle*(4_S) -88,4744 J,V2074 - 628284 -.,.L85014 -, 131545 -,0287194 ,O855418He*(4*P) -85,6466 -,048[JO9-J -. 2044b{I -,0516457 -.,0B5.3529 ,]20960 ,09JOSJl]
The f Jt repr E,t_JelII;S the fie* ( 4 I S ) CI()EtS flC.-_c:t;].(}11 w;i t:II _:ill Illlft (JeV.i al: .i.oll c)|: I 3,5%,The lllClXilllt.llll dev.Lat]Ol] .iEl 3l_, .._"% at. 2, O1_1()4 £,V/iTIIIlil
The fit 1T'epKOEtellL_ l;he tlc-,* (4 i P) (Ji'C)l-JiJ _i(_(..:tloli w.t l:h al_ i:lll[-] ct_;v.l al: :loil iJf {] . O%,The IllaX]llltllll dev.l aL ]Oli Js 5, ] % al; ;I, 01#',-I04 _-.,V/_-uiIti,
Nn [.tt I;o He*(41D) data,
See appelldi× Inr Cl'iebTshev £:l.t: det;a:l lEi, V
c".-9'1
Pie+-t-.He -> He* + He(4-'S,¢'P_4.1D)
Cross oect onvs. Energy-"--'w"'l_'i"'h I Illl "t'''l F-1'"TTiij I ; f ;"; IIJl " ;"' '1' V 1-q-rl'l"
Z_= He(4 lp)
- × = He(4 IS)
,lO-lg_
E -\-J -
c
,_o -o - Recommended(t)
L/') _ Datac/)oo8
U 10_2c - Chebyshev Fit
,,
1021_ l .I I I I I l LL___L.LLLI tt I 1 t. I J I I1!1 ,______J l_I t _.ll I
1o' lo_ lO_ lO"_ lo_Energy(eV/am u)
'i
C-98
Excitation Cross Sectlons for I
He _ + He -> He 4 + He*(43S 43, , P,4:_I>)
He*(43S) , _ He*(43P) He*(43D) .
Energy o Energy o ,, Energy a
(e,V/_im)"' (c.l2) (evla_.L1) (cre2) (evlamu) (cre2)
I. 2E+03 2.24E-20 2.5E+02 2. ]5E-20 2.5E+02 2.91E-19!. 8E+03 4.12E-20 3.3E+02 2.30E-20 3.6E+02 3.48E-192. OE+03 3.93E-20 4. OE+02 2.13E-20 4. OE+02 3.37E-192.4E+03 3.38E-20 4.7E+02 ]. 96E-20 6. OE+02 1.96E-19
3.6E+03 7.03E-20 7. OE+02 2.97E-20 7. OE+02 i. 82E-194. OE+03 6,50E-20 i. OE+03 2.06E-20 9.5E402 2.06E-19
5.2E+03 4.84E-20 i. 5E+03 2.63E-20 i, OE+03 2.05E-19
7. OE+03 6.87E-20 2.0E+03 3.87E-20 i. 5E+03 i. 59E-19i. OE+04 i. 28E-19 4. OE+03 ]. 15E-19 2. OE+03 i. 36E-19i, 5E+04 1.96E-19 4.5E+03 I. 17E-19 2.2E+03 i. 33_-192.0E+04 ' 2.54E-19 5.5E+03 ].13E_]9 3.0E+03 1.53E-19
2.6E+04 2.25E-19 7. OE+03 ]. 24E±19 3.7E+03 i. 50E-19i. OE+04 ]. 84E-]9 4. OE+03 i. 54E-19
1.5E+04 2.60E-19 7. OE+03 3.55E-192. OE+04 2.06E-]9 8. OE+03 3.73E-192.7E+04 1.4 lE-19 1. OE+04 3.40E-19
3.2E+04 ]. 70E-19 2.0E+04 i. 57E-!93.7E+04 ]. 4]E-19 3.5E+04 6.48E-20
References: 204, 696, 703, 705, 708
Accuracy: Unknown
Notes: (1 ) Relative cross sections may be found in Refs. 705 and 708. (2 )Accuracies reported in Refs. 204 and 696 are: systematic error < 10%; randomerror < 5% on each; however, results differ by a factor of 2 at some energiesconmlon to both experiments. (3) Acceptable polynomial fits to these data werenot possible.
Chebyshev Fittinq Parmne%ers for Cross Sections
No fits to the cross sections.
See appendix for Cheblshev fit details.
O
C-99
eHe+ + He--> He+ + He(4-3S,4-3P,4L3D)
10 -2( ........ J i iJ JJJJl , L J i l J_qll. i t i I Jiil
10_ 103 10' 10"_Energy (eV/omu)
C-lO0
Projectile Excitation Cross Sections for 0
He _ + He -> He+(n=2) + _t-le
Energy Velocity , Cross Section(evl_,lu) (clef,/s) (cre2)
1.0E+03 4.39E+07 3 84E-181.7E+03 5.73E+07 8 16E-182.0E+03 6.21E+07 7 62E-183.0E+03 7.61E+07 5 30E-184.0E+03 8.79E+07 4 35E-185.0E+03 9.82E+07 3 80E-186.0E+03 i. 08E+08 3 43E-187.0E+03 i. 16E+08 3 16E-188.0E+03 I. 24E+08 2 96E-18
9.0E+03 i. 32E+08 2 80E-18i. 0E+04 1.39E+08 2.68E-182.0E+04 i. 96E+08 2.30E-182.5E+04 2.20E+08 2. ]IE-183.0E+04 2.41E+08 ].91E-184.0E+04 2.78E+08 I. 55E-18
References: 699, 704, 705, 713, 714
Accuracy_ i E < 70%
Notes: (I) See Ref. 705 for relative cross sections for excitation of He .
22P. (2) For confined excitation of target and projectile see Ref. 714.
QChebyshev Fittinq Parameters for C[oss Sections
En|in = 1.0E+03 eV/6mlu, Ema x = 4.0E+04 eV/_11u
AO A1 A2 A3 A4 A5 A6
-80.4224 .-.698320 -.116751 .174729 -.194669 .0663496 -.0346561
The fit represents the above cross section with an rms deviation of 1.4%.The maximum deviation is 2.7% at 3.0E+03 eV/ainu.
See appendix for Chebyshev flt details.
C-lOl
He+ + He " He+-_.- (n--.2) + He
Cross ._ectlon vs. EnergyI0,r--- 9,0 i i T-" , i i'", I I i i I i "l ,'l T-"
o0 It--\
// A - He+(n-2)I
7,0 //
i -_ 5.0 Recommended
' bqcnoUO_ _ _ _ , , --Data
L 4,0 - Chebyshev FitU
3.0
2.0 -
1,0 ........ ' 1 I j__J i J_ J !1 J t. .l .I I I J [
' 1# 104 ldEnergy (eV/a m u)
C-102
, •projectile Excitation Cross Sect:ions for
lte 4 + He -> fte_( n=, / + l-le '
Energy Velocity Cross Section
(evl_llu) (cm/s ) (cm2)
7.4E+03 _ i. 19E+08 2.93E-198. OEr-03 i. 24E+08 4. J3E-.199. OE+03 I. 32E+08 6.76E-19I. OE+04 I. 39E+08 8.88E-] 9
1.5E+04 i. 7OE+08 ]. 66E-182.0E+04 ]..96E+08 ' 2.43E-182.5E+04 , 2.20E+08 3.54E=18
References I 705, 713
Unknown
Note__._./..'Ref. 705 gives relative cross sections for excitation of 3'P level.
Chebyshev Fittinq Par_m_eters for Cross Sections
Emi n = 7.4E+03 eV/_ml, Ema x = 2.5E+04 eV/_llu
AO A1 A2 A3 A4 A5 A6 O
-82.4466 1.12862 -.190981 .124483 -.0202534
The fit represents the above cross section with an rms deviation of 1.4%.The maximum deviation is 2.9% at 8.0E+03 eV/amlu.
See appendix for Chebyshev fit details.
O
C-i03
@He+ + He -> He+(n=3)+ t--le
, Cn:_ss oect on vs, EnergyL_)'-40.0 i -7 _ _ T T uv'-" _ -- .........
35.0 n = He+(n_3)
3O.0 -
d
_E 25.0 -
_ ,C
© /
L_ Recommendedu 20,0@ --- Data
(J")COLO
L0 15.0 - --'-.- Chebyshev FitU
10.0.-
5,0 -
0.0 --'-- j J _ 1 L __ l L_ J,6,0 7,5 10,0 12.5 15,0 17,5 20,0 22,5 25,0
Energy (eV/arnu) • 10_
O
C-i04
Spectral Dine Emission Cross Sec,tions for O
He -t 112 -> H(Ba]nler-.,[]almer-H)
H (Balmer-a) H(Balmer-8)
Energy Cross Sectloll Elle/gy Cross 8ectloJl(eV/_uuu ) (cxuz) (eV/ainu ) (cnl2)
J
].5E+02 6.77E-19 ] 2E+O2 6.93E-202.0E4-02 7.82E-19 1 5E+02 [.34E-193.0E+02 9.61E-19 20E+02 2.18E-194.0E+O2 1.08E-]8 30E+02 3.34E-]95.0E+02 I.]8E-]8 40E+02 4.1]E-196.0E+02 1.26E-18 50E+02 4.56E-1970E+02 1.34E-18 60E+02 4.85E-1980E+O2 1:40E-18 70E+02 5.07E-1990E+02 1.45E-18 80E+O2 5.25E-191 OB+03 1.51E-18 90E-I02 5.35E-192 0E+03 ].8OE-18 ] OE+03 5.44E-193 0E+03 1.89E-18 1 3E+03 5.52E-]94.0E+03 1.89E-]8 20E+03 5.47E-.195.0E+O3 ].84E-18 3 0E403 5,24E-196.0E+03 1,76E-18 40E+03 4.97E-]97.0E+03 1,65E-18 50E+03 4.'15E-197.6E+03 1.58E-18 60E+03 4.54E-19
70E+03 4.36E-]98 0E+03 4.20E-19
Reference : 46]
Accuracy: Unknown
Notes : (1 ) The hydrogen Balmer line emission results fronl dissociative
excitation of H 2. (2) The Balmer-_ emission is the n=3->2 transition (656.28nlii).
(3) The Balnler-8 enlisslon is the n=4->2 t:ransitlon (486.13nlU).
C_beb_shev Fittinq Parmlleters for Cross Sections
H(Balnler-a) Eillin = 1.5E+02 eV/6mlU, F.max - 7.6E+03 eV/mliU
H(Ba]nler-B) Eml n = 1.2E+02 eV/_llU, Enlax = 8.0E+03 eV/mllU
AO Al A2 A3 A4 A5 A6
H(Balmer-a) -82.3960 .472324 -.197315 -.0438413 -,0176366 -.00308248 5.34250E-05
H(Balmer-B) -85,1264 .678943 -.561863 .182560 -.0716643 ,0321037 -.0158573
The fit represents the H(Salmer-a) cross section with an rms dev:iation of 0.3%.The maximum deviation is 0.5% at 2.0E+02 eV/ainu.
The fit represents the H(Balnler-B) cross section wlth ali rills deviation of 0.9%.
The maximu|u deviation is 1.4% at 2.0E+02 eV/_m.l.
See appendix for Chebyshev fit detail's.
He +H 2 -> H(Balmer-o_, Balmer-/2)
Cross Section vs. EnergylO' 17 - 1 I 1 ' '1 I 'I q---i-:i i i "'1" I .......I I 1 1_
- _ - H_
_ X=H_
10-18 1tt0 -
0 <D - Recommendedr t
¢> -_, Datatr)
Lr)o9
8u 10-19 ...... Chebyshev Fit
10 -2( I l _J l J L_ J I ,I _i 1 J J I J l
lo_ lo_ 1¢Energy (eV/orau)
0-106
Exc.i.t. at: tem (?rottt_ SocL .i.oll t:t [of O
He l lie --> llo.(2tst2rp)
He (2tS) He (2 t I.')
Enetcjy C,tot_[-t Sc-._c_t:.[cltl I!;tl(:,,l:e.:ly Ct-os[t Sect..toll(eV/altttt ) ( (:!iii_ ) ( t:tV/allttl ) ( tllll _ )
J 6E+01 1,00E-19 I 3E-tO] ,1 8LIE-ItJ20E-t-O] 6.25E-_[9 .1 51!;+OJ 7 flSE-182 5E+01 ],.17E-1£ 20E+01 1 52,1_-1.730E+01 1,52E-.18 2, 5E-OO.I 2 39t!',_.173 b E+ O.1. .I., 73 E- 1£ l _ 0 E-t.O _1 3 03 E ,. 1 '140E-t.O] ' J,90E-J,_:_ 3 5E+O.I. 3 59E-1'I4 5E4.0J 2,07E-1.8 4 [)l!;-00.l 4 05E-1750E:I.OI 2,2OE-18 50l_iO] 4 701']-175 5E+O1 2,33E-].B 60EIOI 5 251.';-176 017.;+0;I. 2,44E-]8 '10E+O] 5 621!:-177 0 F,.i-0.1 2,65 E- ]8 8 01!;401 5 95 E - 217'l 4E+OJ 2,72E-18 90E-o01 6 19E-17
L OE+02 6 39E-17] 5E4.02 7 24E-17
Refe_-encea _ 719, 72.1., 722
Accuracy;, U_known
Notesl (.1) Tile dat:a . for 2 ts st: ate are Lllc-,orel:.lcal data of O]._.otl et: a;I,
(Ref, 72.l), The 2 _P stat:e data are t:lle exl)er_t.ment:al dat;a rJf Kempt;er et. al.(Ref. 719) and are appro×/lnateJ.y a l:act;of of 2 great.ct tllali t:llose c)f_ Olsollet at, (2) The er, per:lmenta.l c.lat:a were dc-,t:ei:mt.tlecl by t)leasui:ing ent.l.t_st.otl1 the t nt:ensJ.t t es and cc_ir er;l; :l.rlg for l_t-anchJ rig rat: .l.orJ tlsi ncj knowntransition probabilities. Wlt:h lie, ca<J(2aclitlg , conLl::l.buti.ojl,,_ _zhoulc:l 19_, leasthan 3%,
Chebyshev Fit:tJ_nq Pat'ameters ._of Ct:ose_ Sections
He(2 tS) Elntn : 1 GE.tO]. o.V/alml F = "/ 417;-t.01 eV/ainu, l _III_IX '
lie ( 21 P) Fillil. i = ], 3E-t 01 eV/aim.l, Eilla x = .l, 5B-i.02 eV/aiut.I
AO AI A2 A3 A4 A5 A6
He(21S) -82,742"1 1.3033[ -,5"19333 ,299"139 -,J. 33372 ,O473667 -,0.142447tte(2iP) -76. ]505 ],2353] -,420131 . 1],608;I -,O158.137 -, O016"1796 -,0033629
Tlle £:l.t:. represeilt:n the Ile(21S) mi:(:l_l<j ,.-;ec'.t:.l.oll wt.t:ll ali i:lili_l c.levl.at.:toil cJf 0.5%,Tl'ie ' nla×J.nil.inl devJat;J.on j t:l O, 9% _11; 2, !$_-t OI ic_Vtallltl,
The f.[L ropteseilts the. He ( 2 _F') c'[c;_Js z:_::c_t::l.oli w:t.Lh ,_111[lil,'J dev:i.at: lc)ii t_t_' .1,2si.,The Ilh:.q.xilllLIIll cloy] at .t.ola I.£_ .], 0% ,i-lt: P., Ol_ t0 I eV/allll.I,
SHe al)pel_cl:lx for (.'hel._yshev fil ¢let:,:ill[_.
O
O- 107
0He -I-,He --> ble(-_'S o'p')
J_
C- ] 0 [4
l_Ixc.,.l.t._lt: I Oll (_.!['(._trJ _r_c_i: t oil tol
lie .t tlo -> 1t_(3iP,311"_,]:II,,3_L) )
Ile ( 3 t p ) IIo ( 3t l/) lie (3 :_I' ) IIc:-_( 3 :_[J)
l!llle rqy o llllle l:c.Jy o l!',ll(_r.q y o ' I!lllO l'cj y o( _.V/_Ullti ) ( (_lll"_) ( eV/_'Uliti ) (Ulli _ ) ( [-!V/_lliliJ ) ( Clli _ ) ((.tV/alilti) ( (.!111_ )
' 2 !5_It 0 2 2 27 IJl- ;I 13 2 f_ _' ,, , ,_l.,.t.OJ. ,l J21_,-.1.9 2 blJl+iO;I .L,491._l-.19 2 !$l{li.O_l. .l 671!I-.L93,0B.I.O2 2,121!l-;I.8 3 01_-I0] 2,23P,-.19 '4 01_1I.O1 9,971._l-.I.9 30l_l.lOl ,4 6i]l;l--,J94,0B.t.02 1,931_-J.8 40L,1-i.01 5,211_,..19 7 0t!,i,0] 2,4hl_'-.llj, 40l!i.iOl ;1 O9L_',-185,01,3:t-02 :l,t.13r_-]8 5 Oli].t.C)] 9,0.1t_-L9 I 0I_.l.02 2,6f.11!I-]8 .iS 01_-t.0] ] 5!$I1J-386 , OLd+02 .[,771_1-]8 6 0L_-t-OI ] , 331.,-.18_ 2 OE-t.02 2,201JI-ilLI 6 Ol_.t.O] I 981!I-187.017]-I02 [,76E-,18 / Ol{.l.l,O]. 1,7]I_]-J.8 40E-I02 .L,581?l-JO 7 01_,-I(]] 2 39B-1880E-I'02 ] 161_-18 8 01._H.OJ. ], 921_'- LB 7 _' 5E-' . -, . 01.,i02 ]-,3 .18 80l!',+OJ 2 601_-109,013:-t'02 1,761_,]-]8 90lllt,(]] ], [I]1_- I[I .I 01_',+()!1 .1,47L!l-.113 90I!]-t.C).l 2 801!1-;18.I., 0I!',-t'03 ], 771_-J[1 ] O1!l-t.02 ;l, 741Jl-Jll ] 2l']-i0] .I, B4[_,--.18 .1 01!:-t.02 2 77t_-]81,21_-t.03 ],801,.1-,.L8 ;I ;1._].t()2 .1,74P,-]8 ] 5FI-i.02 2 441!:-]8
] 5[_-i.O2 2,311,.I-] II
RO f c_i;e rlne r:t i 718, 7.19, 723
_CC_tli._aC7 i Unknown
The recollUllellcled dat:u l:or 3:_1, nt_ll:c_, linvt7 b[7_[-:ll J.nte_l:l_O.l_ltc_d bfJl:.w{:J_ll l;he
d_ita of K;[Illtlra et a.l., (Re£, 7]8) (!._I > 2,5X10 _ E_V/[III}tl) and t;llt) .low-ei]ercjy clataof Kolilpte].- el:. _1, (Rof, 7.19), Thil=l e×t:eapo]ai;:loil j._t tlilCer.ta]ll clue t;o c.ltf£_'_tlltenei:g 7 tie pe i1cl_.,n c_.t.e _l,
Clleby,sl]_v L_±tttllcl, ,[Tar.ailiete_-,<J .[or Cross Seet;tOll_.t
ile(31P) Eliii = 2 " _' ' ;=ii , ._I.,-I,02, _.V/ailltl, Elllal4 |, 217l-t.03 r-_Vtaliltl
fie ( ] l D) t_iii.t n "-_ 2,51_-t-01 eV/alllU _ l'llila x --- .[, 51_]-t02 [:_V/_UlltiHe ( ] 3p ) _lil;[ll 2 51_-t.0] 17)V/allltl, i, _-_-=' ' I.,III_IX ]. 2P,-t.O] f:_V/alllll
= 2 5I_tO.1 eV/aillu, =-" ] 5l!l.i-()2 eV/aillulte ( 3 _1) ) E'llli 13 ' 17_illaX '
AO Al A2 A3 A4 A5 A6
fle(]iP) -81,5965 -,116911 , ()57 ] 16"/ {I, 081.64E..O4 -,00354047 6, I 1'163L_b.O5 ,00 L{17028
1-1e( 3 il)) -83,4302 1,37998 -, 506774 , Ot3 7{G 31] .] ,0986308 , O77 lll[i, r) ], 46(Ti2flP,-O4
Ile(33P) -82,5431 ,625566 -, 782070 ,54521ll -, ).O0] 4 (i ,O31OO14 , ()(.)4595 ].]
tlo(33D) -82,5242 1,15604 -,6C)2651 ,11"1602 -, O53t105($ ,O613126 ,0230997
[I -. f:l.t Irep_'e_]C:.;ilt_ ] the Ile( 3 _P) (;'r¢:_-i_:l s_c;'t ion w:l.t:h all l'lllfTt ¢]eV.l at::t(m oi O, It,The. lll_l×]llltllli devJ.at[on tt!l 0,]% at t'J,OE-102 oV/allltl,
The l]t tr_l:)re_,l_l;rj the l.le(Iii)) (Jr(-Jf]s fi[:(;_t.l.on w_ith nii rlll[i clr-,v.t.aL_.Oli oi I, 9%,Tl_e. Iilax.hiltilll (](:_.vJat.[oll ;If:_ 2,8% at; 9, O[_-t()l (:-_V/aliltl,
Tlic-: f Jt: rep,1;eserit:_] tile lh!:( 7:_I') (;i.(J_JfJ soc, I;.I (.iii w.l i.h 7111 1111t71cl(-,v.laL.l.oll (_f: O, 7%,The lila×].niuiil d_:vJ.at;] [Jll .t.f] ], ] % al: I, O1!I+02 oV/almi,
The .l;t.t r(-:presents t:li_, t-1_.:,(3:_D) (:_l;(:)_i[l sri,el. :l.(:_ll w] Lli illi i-llllt (Jev [ {ii: ] (:)11 (:ii (), ] %,Tlir._ lll_iXillltllli clev].al;.I Oli :1s O, ]% _il; 9, O1!',+01 (,V/aillli,
Sen, appericl].×. 17or Cheby,.qh_,v [.1 i. d(.!i.a I. I,g0 _ I
p
i
q
(._-:1,(3g
Iit-ie + He --:> Flet3'P,3'D,4 ,..._j
10 _ .... :'.-] _ ,,,_J_L_, , ,,,,.,L- _ ,.z_t.__ld ld _d to_
Energy (eV/o m u)
hJ
_;:xc:;It;at' 1i311 c'rc:)_l SPut: ] C_li_l [cii
lie -t. lie -> 11¢,,,(4=S,4iF,)
I.le(41S) ite(41S) c_ollt,, He(41P)
E 1119r£1y o i!',lle t"£ly o IPol1e t'cjy o
(eV/_ml) (am2) , (,'_V/amu) (am_') ((_v/a.lu) (a.l' )
].TF,.t.O]. 200L_-20 50l!;+O] 2 96E-;L9 b Ol!l+O'J 3.65E-192,0L_.l'O] 2 98E-20 6 01!',-t.C)3 3 371!I-.19 5 5p,+03 ],B8E-193, OLq.i01 9 531!;.,-20 70E-I.O] 3 7SE-:L9 6 0E+03 4,06E-19
4,01_-_0.1 2 37l!;-19 8 0I_403 4 .ltl_-;19 70E+03 4,23I_-]95.OE-t.01 4 7tt_-.19 90E-I03 4 40I!:-.19 80E,i.03 4,06E-196.0E+0] 7 061,3-19 I 01!1-t.04 4 61E-]9 90L,;.t.03 3.85E-]97, O_-,.O;t 8 9:tE-19 :1. 5E.i.04 b 1]E-.19 1 C)E+04 3,6OE-;I 97,91g.i.0;1. ] 05E-18 2 0E-i04 4 12E-J.9 J 5E.t04 2,61E-199,OE+01 ] 19t!;-118 2 5E+04 4 221,.i-.19 '2 Ot!l-t.04 ],881_]--191,017,+02 ]. 33E-.18 2 4E-t04 1,50E-191,5Et.02 J. 90F,-181.8E-I.02 2 .15E-18
Refere!Icesl 703, "119, 12'.I
,AcCLtI" acY !, tlllklloWllI
Note___..!i TIle 4iS data ii1 the low and h ].c]la c-uaergy fancies are plot:t; .o,dlrldivlc]ual].y to illclic.a t e t;I-le problelil_i .I.nVo].ved irl t;:Olllpa r i ilc] alaclinterpolating betweel] low and h.l.gh elle r(.jy data, IJ_Je these clara wit;la
caut :Loll. O
Chebyshev Fitttliq l:'aiTallle te ta for Cross Seut,[oll_l
I-le ( 41S ) El%lil.I ---. 1.7E-t 0]. eV/alllU, Eilla x = 1.8E-i.02 eV'/allltl= 5, OE.t.0t eV/allltl, EiIla x . .lle( 4_s ) Elllil_ = 2 5E+04 e..V/alilU
I.ln(4tp) Elll.tl 1 = 5,0E-t.O] eV/_llti, Elila x =: 2,4E+O4 eV/_llti
AO Al. A2 A3 A4 Ab A6
He(4*S) -85.2188 2.4]50] -.48759"I -,07271179 ,1].1514 -, 0038] 50;1 -.0352846lle(4_S) -84.6731 ,]96616 -,]60691 -,0239012 ,00732614 .00447306 .0C)338388He(4*O) -85,4091 -,479796 -,]91704 ,0341683 -,0126641 .00116120 ,009"17808
qJhe fit; represents the Ite(4*S) croFIs aeration with till rills cleviattoll o£ :L,2%.The nlaxilllUlll dev:Lat].on ].FI 2,3% at; 4, OE-tO.[ eV/alllU,
The .f.tt represents tile I-le(4_S) ci:'o_f3 sec'L.loll w;it;h an rills clev;lat:.toil o17 0,2%,Tile IllaXilllUlll deviation is O. 4% at; 7,1E.t.03 eV/ellt.I,
'Pile fit represent;s the He(4*P) cross section with an t'iiis deviat]oll o17 0,3%,The iliaxilllUlll dov.tation i[:t O.6% at 8,0E-i.03 eV/alllti,
See append.ix for Chebyshev fit: clet:a.l,t_j,
@
c:_.-.l.lI
t-le -t-.,hie --.> t-le(.l._<'J_4._p)
..... k-"
( I-<-:_!_;S ."_:.,@(L[ior7 \./s. _17c Ic.].y.-_- .i0-r/
& = t-le(4 _S) '
- ,_ x = He(4 IS)i
q = He(4 lp)10-_o_
_.-., -E -
C: /f'"\X
,o - _Xx i
+-' Recommended(D0 ---Data
, Lr)Locf_
0 ..... Chebyshev Fitu 10-ig
10-2(__ i i __lJJll .l _ sJ_Jl 1 I LJJ_lJl 1 La--_.U.ld 10_ 103 104 105
Energy (eV/ar-nu)
C-112
Excitation Cross Secttolls For 0
He + He -> He(43S,43P)
He(43S) He(43S) cont. He(4_p) '
Eriergy o Ehe rgy o E ne rgy o
( eV/ainu ) ( chi 2 ) ( eV/ainu ) ( chi 2 ) ( eV/ainu ) (cm _"
2.4E+01 2.53E-20 5.0E+03 4.37E-19 2.5E+02 2 18E-182.5E+OI 2.90E-20 5 5E403 4.47E-19 4.0E4 "2 ]. 38E-] 8
3.0E+OI 5.97E-20 ' 6. OE+03 4.66E-19 7.0E+Q2 8.79E-193.5E+OI i. 07E-19 7. 084.03 4.90E-19 l. 0E+03 8.23E,194. OE+OI i. 59E-19 8. OE+03 5.29E.-19 2.0E403 "l.68E-194.5E+O] 2.08E-]9 9.0E+03 5.47E-] 9 4. OEr03 7.14E-]95.0E+0I 2,62E-19 1. OE+04 5.14E-] 9 7.0E+03 7.07E-19
5.5E+01 3.15E-19 1. lE+04 4.88E-]9 ] .0E404 5.62E-196.0E+01 3.65E-]9 ].5E4-D4 5.30E-19 ] 5E+04 3.]]E-19
7. OE+OI 4.61E-19 2. OE+04 6.12E-19 2. OE+04 i. 95E-198. OE+Ol 5.43E-19 2,5E4-04 6.77E-] 98.8E+O] 5.95E-19
References: 703, 718, 719, 720, 723
Accuracy: Unknown
Note___._!:No attempt has been made to interpolate between the low and highenergy data for the 4_S state. Use these data with caution.
Chebyshev . Fittinq Pareaueters for Cross Sections O
He(43S) Eml n = 2.4E+01 eV/aul_u, En|ax = 8.8E+O1 eV/aJllu
He(43S) Eml n = 5.0E_03 eV/aJmi, Ema x = 2.5E+O4 eV/atom
He(43P) E,,in = 2.5E+O2 eV/a311u, Ema x = 2.0E+O4 eV/ainu
AO A] A2 A3 A4 A5 A6
He(4aS) -86.5334 1.57661 -.301332 .0231287 .0]47011 -.0218801 .0]03488
He(43S) -84.1641 .186801 .027462] .0565092 -.00857002 -.q283410 .0102453
He(43P) -83.4554 -.954640 -.0267074 -.366176 -.0251284 -.0183797 .0210686
The fit represents tile He(43S) cross section with an rms deviation of 0.4%.
The maximum devi-tion is ].0% at 4.5E401 eV/_uu.
The fit represents the He(43S) cross section witll an rms deviation of 2.]%.The maxinlum deviation is 3.6% at ]. ]E+04 eV/a]llU.
, The fit represent s. the He(_P) cro_s section with an rms deviation of 3.5%.The maximum de\ ation is 6.2% at 4.OE+03 eV/6ullu.
See appendix for Chebyshev fit details.
C-I13
He + He -> He(.4-'_S,4-3p)
Cross Section vs. Energy-17
10I I 1 I I'FT-I' I I I' 1 1 IIII I I I I"11'J"Jl I I I IT-_
[
_ = He(4 3S)
x - He(4 _S)
q-- He(¢ 3p)
10-le-
E - u(D
'_J -- ' 4c"
O
"+" Recommended(,,.,.) --
r_ Datatj'-)
03030
U Chebyshev Fit10-19_
0 2c l l I I l'llll t. 1 1 1 lllll _L I I l 1 lJll l l 1 l I I1
10' 102 1(_)3 104 ,, 10sEnergy (eV/arn u)
r
!
C-I14
Excitation and Ion-Pair Production cross sections for Q
He 4 'Fie -> Aut°i°nlzing States
2S 2 IS 2s2p 3p 2p z *lD ,2s2p Ip He--(is2sa)ZS
Enslgy O Energy o Energy o Energy O Ellergy O
(eV/amu) (cre 2 ) (eV/ainu) (cre 2) (eV/al,u) (el, z ) eV/al,u) (cre 2 ) (eV/ainu) (cre;')
2,5E+O3 6,83E-20 2.5E*03 1,72E-20 2,5E_03 2,01E-19 2 5E_03 1,13E-19 3.7E+O3 2,45E-19
3.0E+O3 8,84E-20 3.0E+O3 2,04E-20 3,0E.03 2 55E-19 30E+03 i,52E-19 4.OE+03 '2,6'0E-19
40E+O3 1,32E..19 4,0E.O3 2.70E-20 L4,0E.O3 3 57E-19 40E+03 2,27E-19 5,OE_03 3 05E-19
5,0E+O3 1,8OE-19 5.0E.O3 3.37E-20 5.0E.03 4 ,12E'19 5 0E_03 2,91E-19 6.OE_O3 3 43E-19
6,0E.03 2.28E-19 6.0E+03 4,OIE-20 6,0E+03 5 18E-19 6 OEr03 3,48E-19 7.0E_03 3 76E-19
7,0E.O3 2.82E-19 7.0E.O3 4,74E-20 7,0E+03 5 74E-19 7 OEr03 4,05E-19 7,7E+03 3 83E-]9
8,0E.03 3.37E-19 8.0E.03 5 42E-20 8,0E_O3 6 16E-19 80E+03 4,53E-19 8.0E+03 3 80E-19
9,0E+03 3.90E-19 9.0E+03 6 16E-20 9.0E_03 6.49E-19 9.0E+03 5,05E-19 9,0E+03 3 41E-19
1,0E+O4 4.33E-19 I,OE_O4 6 96E-20 1.0E_O4 6.72E-19 10E+04 5.49E-19 1,'OEr04 2 80E-19
1,4E.O4 5,2OE-19 1,5E_04 1 3OE-19 1,2E404 6,89E-19 1 3E_04 6,18E-19 1,5E_04 8 38E-20
1,5E+O4 5.19E-19 2.0E.04 2 53E-19 1,5E+04 5.58E-19 1 5E+04 5,92E-19 2.OE404 3 76E,-20
2,0E+O4 4,54E-19 3,0E_04 4 28E-19 2.0E_O4 3,42E-19 20E+04 4,82E-19 3,0E_04 2.22E-20
3,0E'_O4 3.31E-19 3.5E404 4 92E.-19 3.0E*O4 1.57E-19 3 0E604 3,38E-19 3.5E+04 1.99E-20
3.5E+O4 2.86E-19 3,5E+O4 1.22E-19 3 5E+04 2,89E-19
References: 724, 725, 726
Accuracy: Unknown
Note: The is2s 2 2S state is the autodetaching state of He-.
@* Cheb__,shev Fittinq Par_ueters for Cross Sections
2S 2 1S = . , = .Eml n 2 5E+03 eV/_ml Ema x 3 5E+04 eV/ainu
2s2p 3p Em in = 2.5E+03 ev/aJllu, Ema x : 3 .5E+04 eV/aJml2p 2 1D = , = .Emi n 2.5E+03 eV/aauu Ema x 3 5E+04 eV/aJuu
2s2p Ip El]lin : 2.5E+03 eV/a]ml, Elllax = 3.5E+04 eV/aIlluHe-(Is2s2)2S = , 2Eml n 3.7E+03 eV/ainu Erllax 3.5E+04 eV/ainu
, AO A1 A2 A3 A4 A5 A6
2s _ IS -85.8524 .799247 -,526341 -.114359 .0439092 .0371210 -.00499344
2s2p 3p -87,8698 1,74012 .165859 -,0382066 -,0794670 -.0352277 ,0132924
2p 2 lD -85.2799 -,217724 -.729656 --.0810841 '_ ,0662609 .0581753 .00536077
2s2p rp -85.2994 .497649 -.530222 ~.06_0468 .0249202 .0444313 -5. 43766E-04
He-'(is2sz) 2S -87.4403 -1,52170 -.498463 .350749 .]57944 -,0929551 -.0455722
The fit represents the 2s _ IS cross section witl_ an rms deviation of ].1%.The maximum deviation is 2.2% at 2.0E+04 eV/am_1.
The fit represents the 2s2p 3p cross section with all rills deviation of 2.4%.The maximum deviation is 5.2% at ].5E+04 eV/ainu.
The fit represents the 2p 2 lD cross section with an rms deviation of 2.0%.The ma×ililtlilldeviation is 3.6% at 2.0E+04 eV/alllu
The fit represents the 2s2p lP cross sect ion with an rms deviation o£ ].8%.The nlaxiluum deviation is 3.7% at 2.0E+04 eV/ainu.
The fit represents tile He-(]s2s2)_'S cross section with au rms deviation of 1.9%.The maximunl deviation is 3.4% at ].5E+04 eV/ainu. ,
See appendix for Chebyshev fit details.
C-I15
He + He -> He(2a2p2P, 2s2p_P, 2s_'S,2p2'D)He + He -> He-(Is2s_S)
Cross Section vs. Energy10-18-- f i t t '1 i I I"l l ..... I' I I I 1_-1"'"'1-
A -- He(2s2p 3p)
x = He(2s2ptp)
V = He(2s_'S)
_ -He(2p_,D)E0 • = He'_ls2s_2S)C0
'__ lgo 10- - Recommended® - ----.Databr)
8 -U - - ..... Chebgshev Fit
10-2¢__ i l J i J i i ii ,.... t 1 , i i _j llo_ lO• lO_
Energy (eVJQrnu) ,
C-i16
Excitation Cross Sections for Q
He _ 4. H -> H(2s,2p)
H(2S) H(2p)
Energy Cross Section Energy Cross Section(eV/_ml) (cm2) (ev/_m ) (cm2)
2.5B+04 1.41E-16 2.5E+04 1.68E-163.0E+04 1.16E-16 3.0E+04 1.75E-164.0E+04 8.70E-17 4.OE+04 1.84E-165.0E+04 6.97E-17 5.0E+04 1.92E-166.0E+04 5.77E-17 6 0E+04 1.97E-167.0E+04 4.98E-17 7 0E+04 2.01E-168.0E+04 4.37E-17 8 0E+04 2.05E-169.0E+04 3.86E-17 9 0E+04 2.06E-]6I.OE+05 3.50E-17 10E+05 2.08E-161.5E+05 2.35E-17 1 5E+05 2.07E'162.0E+05 1.79E-]7 20E+05 ].97_-163.0E+05 1.22E-17 3.0E+05 1.69E-164.0E+05 9.42E-18 4.0E+05 1.45E-1650E+O5 7.75E-18 5.0E+05 1.31E-165.6E+05 7.06E-18 5.4E+05 1.29E-]6
Reference: 174
AccuI_cy: Unknown
Note: The curv?s are results of theoretical calculatiorls for tile excitation ofby He 2 inpact. Ref. 174 compares the results of calculations usln_
alternative basis sets together with a full explanation of the estimatedaccuracy at different He 2_ energies.
.Chebyshev Fittinq Parmlleters for Cross Sections
H(2s) Eml n = 2.5E+04 eV/mau, = 5 6E+05 eVainuH (2p ) Enlin 2 5E+04 eV/aJ11t! El|lax "= • , Enlax = 5.4E+05 eV/aJllU
AO AI A2 A3 A4 A5 A6
H(2s) -76.0595 -!.50152 .0300296 .00522842 00296312 -4.05387E 04.001596].7H(2p) -72.5902 -.122617 -.180664 -.0249549 .0157733 .0139456 .00499314
The fit represents H(2s) cross section wit.h an rms deviation of 0.2%.Tile maximum _l,_viation is 0.5% at 6.0E+04 eV/_ml.
The fit represents H(2p) cross sectlon with all rms deviation of 0.2%.The maximum deviation is 0.3% at 4.0E+04 eV/6mlu.
See appendix for Chebyshev fit details.
C-i17
0He_++ M -> H(2s,2p)
/
/j' ,, Cross Section vs. Energy
-15"lU;r' L , , , _ i ' _ ; I , " '_ , ,....I , , ,
= H(2p)
x : H(2s)
10-16_ \
E _ \\
o \\
c. \\0 "\
O - \ Recommended(1.) -,.
or) \,,. Data
O9
o
U 10-17- , "_..x.x Chebyshev Fit
J
I
_o_ lo_ lo_Energy (eV/am u)
C-I18
Projectile Excitation Cross Sections for O
He(23S) + He(11_) -> He(3*P) + He
Energy Velocity Cross Sectioll(evl_lu) (cmls) (c,,,2)
5.0E+OI 9.82E+06 3.44E- 186. OE+OI 1.0BE+07 4.55E-187. OE+OI i. 16E+07 5.27E-188. OE+OI i. 24E+07 5.66E-189. OE+OI 1.32E+07 5.84E-18I. 0E+02 1.39E+07 5.93E-181.5E+02 1.70E+07 4.63E-182. OE+02 i. 96E+07 3.94E-182.5E+02 2.20E+07 4.44E-183.0E+02 2.41E407 5.57E-]84.0E+02 2.78E+07 6.82E-185.0E+02 3. IIE+07 6.97E-186.0E+02 3.40E+07 6.76E-187 .0E+02 3 .68E+07 6.35E-188.0E+02 3 .93E+07 5.88E-189 .OE+O2 4 .17E+07 5.35E-]81 .OE I03 4 .39E+07 4.80E-18i. 2E+03 4.81E+07 3.50E-18
References: 728, 729
Accuracy: Unknown
Notes: (i) Results from Ref. 728 corl_espond to pro]ectile emission Imeasurements and no corrections were made for contmuination of metastable
atomic bemll wit]] ground state atoms. Results have been normalized by theauthors to previous results on excitation. (2) Experimental details ofRef. 729 are unknown.
Chebvshev FittiI_q Par_ueters for Cross Sections
Bmi n = 5.0E+OI eV/6uuu, Ema x = 1.2E+03 eV/_u
AO AI A2 A3 A4 A5 A6
-79.7131 .0521928 -.176441 -.0874202 -.203462 .0710365 .0424143
The fit represents the above cross section with an rms deviation of 4.9%.The maximum deviation is i0.5% at 2.0E+02 eV/_uu.
See appendix for Chebyshev fit details.
i
c-.L 1.9
QHet2:JS_+- He(I $) --> He(3_P)' + Pie
(LtrossGection vs. Energy--17
lO L , , , , ,"r',, t' ' T , ,, , i, i I ' ' _ '- ,'" , ," r, ,',
_ ,_ - He(3_p),
- ,,/Z /,,'l_ / ,,\ /,' ,_
\ I
1 "t '1E
,_UoC - lt "-" '1'-_ Recommended¢_ - Data_.f')ct)cn0L
U Chebyshev Fit
10-1_ _ i i J li*li ,,, l J J ,J Jill 1 1, J J JJ*J
10' 102 103 104Energy (eV/amu)
0-120
Projectile E×citat:l Oli Cross 5ect.l.ollS for
He(2:_S) .! He(J.lS) -> He(33P) -I, Hu
Energy Velocity CroBB SecL:l.orl(eV/am{i) (cm/s ) (ClU _ )
3.5Ei.01 8,22Et-06 3 5]E-].74.0E-l.01 ;8.79E-i06 4 07l,.i.175.0E+OI 9,82E+06 5 05E-]76. OEt.01. 1,08El-,0, 5 9f,1';--177.OE+OI 1 16E+O7 6 61E-178.OE+01 1 24E-I.O7 7 23E-179.OE.I-OI 1 32E4.()7 7 70E-17
1.OE+02 ]. 39E-iOI 8 11E-],71.5E+02 ] 7OE-tOl 9 36E-.[72.0E+02 ] 96E+07 9 94E-]72.5E4-02 2 2oE-r07 1 02E-]6
3.0E+02 , 2 41E4-07 1 03E-.[64.0E+02 2 78E+07 l 02E-165,0E+02 3 I]E+07 100E-166.0E+02 3 40E+07 9 93E-:177.0E+02 3 68E+07 9 82E-178.0E+02 3 93E-I07 9 68E-]79.OE+02 4 ]7E+07 9 49E-17i. OE@03 4,39E+07 9 35E-]71.3E+03 5.01[.;+07 8 48E-17
References: 728, 729
Accuracy t UllkllOWll i
.__es__L (1 ) Results frolll Ref. 728 cot re spol]d to projectile elllissiol]measurements and no correctioils were ,lade for COiltmulnation of metastable
atomic be_ll with ground state atollls. (2) Results have been normalized bythe authors to previous results o11 excitation. (3) Experimental detailsof Ref. 729 are unknown.
_gv .....Flttinq Parmueters for Cross Sectiolls
EÁllin = 3.5E+O1 eV/anlu, Elila x = 1.3E+03 eV/_lltl
AO A1 A2 A3 A4 A5 A6
-74.2632 .3993}4 -.30048] .052598] -.0111543 -.00859422 -.00474980
The fit represents the above cross section with an rms deviation of .0.4%.The maximum deviation is 0.8% at 5.0E+OI eV/6um].
See appendix for Chebyshev fit details.
cJ-] 2:L
• '
i-te(123S/-t- t-le(.l'S)-:> He(33P) + He
. _,(-n-)'=_"_ _Jst:: ectionvs. EnergyI
'-- I I,0 "----_'-r'r'T_r--'--r'--'T"-'r"-r"r__ i ' , ", I ,' ,', T"
lo:o- /_''\ - _: .o(3_p)
9,0 -
s._a,o -
c-O
0 "_ 7,0 - - Recommendedq) __ Data(7)
o 6,0 -U ...... Chebyshev Fit
5,0 -
4.0 -
3,0 , i_ LL_Z_LU.I___Z._Z-L__I_LI__L , ,_LLLL
10' ld i03 104Energy (eV/Qm u)
C- [22
Projectile Bxc,:ttat.lOli C_ os[:J Serif::l.olls l:or 0
I-IB(2;_S) + I le(.l, lS) ..> 11o(4-_S,4;11]) -t. HD
He ( 4"_8 ) I.le (4ti" !
Energy cross 8oct:.{on IJlne r c.17 cross Section( eVlaliiu ) ( Clii _) ( o.V/aliltl ) ( Sill _ )
7 OE-t-OI ] , 17E-18 6 . OB-tel 6 . 961U-1188 OB+OI 9.49E-19 7.0E'IO] 7.98B-1.89 OB+Of 8.39E-19 8 OLi.O]. 9 ()IF, ]810E+02 7.81B-]9 9.0E+OI 9.94B-181 5L']+02 1.22E-18 I.OE-t'02 1 07L_-1720E-I-02 .1.62E-18 1.51_-i02 1 36B-173 OB+02 1.991_-18 2.0E.I.02 1 49B-171 OB+04 2,701_-18 2.5L']'t02 ,[ 52B-171 5 E+ 04 2.16 E- 18 3.0 l!',-iO2 ] 4 2 Ig- 172 OB+04 1.76E-18 4.0E-IO2 I ]6E-]72,5E+04 I,49B-18 5.0E-i02 t. 05E-172.7B+04 I. 39P-18 6.()_1+O2 I. 09B,-17
7. OE-I:O2 ]. ]6B-178, OE+O2 1.21E-179.0[",'I'02 ]. 26E--] 71. OE.I-03 1 • 29E-] 71.51/;-i-03 1 •39B-172. OE+O3 1.39E-171.0E.t 03 1.33B-:[74.0 E+0 3 1.2 2 B .-175. OB-l-03 1. llE-176. Otl;+O3 1. OOg-:1. 77.0E+03 9.02E-188. OE+03 8.13E-18
9. 017,+03 7.36B-181.0E4"04 6.61E-18.l. 5E+04 3.87B-182. OB+04 2.28E-].82.5E+04 I. 4 I.B-18
Referencesl 727, 728, 729, 730
Unkllown
Notesl (i) Results froni Ref, 728 c.orres[_ond to projectile elllissJ.ou crosssections and no oorre0tlon was lliade for corltalllil]atlon of nletastable atomic
beam with ground state atonls, (2 ) Results have been normalized by theauthors to pre,vious results oi] excitation. (3) Experilltel]t:a]. details of
, Ref. 729 are ullknowll, (4) Dotted curve for 4"_S exc.ltatloll between .3 and
iO keV/6mlu represel]ts _111 int:erpolation between tlle data of Ref. 727 andRef, 729, and has a 1,ai:ge uncertail]ty,
_Chebyshev FittinoL._Parm_letei:'s for Cross Sections
He ( 4 3S ) Enlin = 7. OE+O1 eV/allltl, Elll,:]× = 2.7F,-t-O4 eV/allltlHe (4 3D) Elllil] = 6, OB+Oi. eV/EIIIIII, EIIITIX = 2. 5111-t.O4 eV/allltl
AO Al A2 A3 A4 A5 A6 A7 A8
He(438) -81,7091 ,309903 -,473244 -°0741860 .O175929 -,]12721 ,O812889 -.0416811 ,0437011
He( 43D ) -78,8400 -.637167 --.7]9668 -,l8B.,_r,.,.),.-,,198706 ,0689624 ,0[16222 -,0618008 ,0358345
Tlle fit: represents the He(4:_S) cross se(:l:ioil with an [Ills (]eviat:[oll of 2.6%.The Illat× imtllll der 1.at ioi] i s l. 0% at ]. OF,-t(] 7 eV / aillti,
The fit represelits the He(43D) cross sect.i.oli wltli 6111;:lllSdev:[atJon of 3.7%,
Ttle illaxinll.llll devJ.ation is 9.8% aL 5, OE-IO2 eV/aliltl.
See appendix for Chebyshev fit det:a.l.ls, qp
i
C-123
, He(23S) + He -> He(4-3S,4-3D)+ He
CrossSectionvs. EnergylO- ;--1{_ _v t v t t iii 1 .... t 'i -_:, t I"tl'V't V "_'"'l I'"V'lVll ' *-"l_q _ i i 1'vi
£_
- _ = He(43S)
X -l,-te(4 3D)
r'l --
F- -_ -c-
,_(2 -4-' Recommended
lO -
U lr._IB - Chebyshev Fit
lO,-,__ , t 1 illlil i i i ILI._ J..l 111111 . I i i LL!!i
10' 10_ 103 104 105Energy (eV/em u)
,. C-124
ii'at .qe t EXc.i t:at:. J C)ll C'rosss Sec:; t: Lotls for 0
Fle(23S) + K'le(.llS) -> I.le + I-le(4:'S,4:_D)
l-le ( 43S ) Fte(4-_D)
Erlergy CROSS Sect iol_ Elle l:gy Cross _ection( eV/_,u ) (e,I _ ) ( eV/_l_u ) ((:m _ )
5.0B+03 6 41_,-18 50E.F03 ] ]7F,-]76.0E+03 7 20E-].8 60E+03 .t 39F..;-177.0E+03 7 72E-18 70E+03 1 48L'I-178,0P.+03 7 92E-18 7 5E403 I 49E-179.0E+03 8 01E-18 80E+03 ] 47E-]71.OE+04 7 89E-18 9 0[_403 1 38E-171.5E+04 5 87E-18 10E+04 I 22E-172,0E+O4 3 35E-18 1 2E+O4 6 16E-]82.5E+O4 1 50E-18 I 5E+O4 3 51E-18
20E+04 ] 74E-182.3E404 ] 28E~18
727, 730
_c_zi 40_
Notet Data are for exclt:ation of the ground state }le target atom by thelueta"-'_t able He (23S ) projectile atom.
Chebysl]ev Fittin q Par_ulleters for Cross Sections
He + He(4_S) El1_in = 5.0E+03 eV/6uml, Ema× -_ 2.5E+04 eV/ainu
}le 4 He(43D) Emi n = 5,OE+03 eV/aloe, Eloa× = 2.3E+04 eV/aJllu
AO Al A2 A3 A4 A5 A6
He { Hs(438) -79.6926 -.631297 -,445191 -.0910388 -°0216050 -.0046"/890 .OO182959
He . He(43D) -79.4099 -1,23537 -,4231"/3 .177025 .0609486 -.O517149 -.0270941
The fit represents He + He(43S) cross section with an rms deviation of O.2%,Tile illaximum deviation is 0.4% at 8.0E+03 eV/aJ11u,
The fit represents He 4 He(43D) cross section wit:h al] rnl8 deviation of 4.4%.The maximum deviation is 10.7% at: 1.2E404 eV/a]ml.
See appendi× for Chebyshev fit detal]s.
I--Ie(23S)+ He(I'S)->He(4:3S,4.SD)+He,
Cross Section vs. Energy-16
10 , i --, _ ,-- , ,', ,'f ,....... T'---F'T--'r _i i_-
a = He(4 3S)
x = He(4 SD)
EL)
C:O
o 10-17- Recommended¢) " -_ Data
(/1
03_o -
U _ '....... Chebyshev Fit
I0-le_ , _ I i h _ l i _I !_ ..J .-L A i J LA
103 1¢ 105Energy (eV/am u)
I
k
i
k
C-126
Excitation and Spectral Line Emisslon Cross Sections for O
H+ + t,i(2S) -> I{_ + bi(2p)
-> H* } bi(670.8nm)
Li(2p) bi(670.8Jlm)
Energy Cross Section Euergy Cross Sectioll(eV/anu) (cm 2) (eV/m_lu) (cm 2)
5.0E+02 9.56E-16 2.0E+03 2.97E-157.0E+02 1.20E-15 2 5E+03 3 35E-15I.OE+03 1.50E-15 30E+03 3 69E-151.5E+03 1.91E-15 40E+03 4 04E-]52.0E+03 2.25E-15 50E+03 4 27E-154.0E+03 3.06E-]5 6 0E+03 4 43E-157.0E+03 3.62E-15 70E+03 4 53E-15I.OE+04 3.96E-15 80E+03 4.60E-151.3E+04 3.99E-15 9.0E+03 4.65E-152.0E+04 3.88E-15 I.OE+04 4.69E-154.0E+04 2.38E-15 1.5E+04 4.73E-157.0E+04 ].42E-15 2.0E+04 4.55E-]5I.OE+05 I.O3E-151.3E+05 8.17E-16
References: bi(2p) ; 257, 285Li(670.Snm) emission; 258, 732, 734
Accuracy : Unknown
Notes: (I) The ground state of Li is tile 2s state. (2) 'Pile resonance line of ILi is the 2p -> 2s transition at a wavelength of 670.8nm. (3) Myers et al.(Ref. 734) have also measured emission cross sections for this reaction ill theenergy region 100-1500 eV/ainu. Their results are more than an order ofmagnitude lower than the recolluuended data ]u the energy overlap region.
C_.hebyshev Fittinq Par_]leters for Cross Sections
Li(2p) Emi n = 5.0E+02 eV/mllu, Ema x = 1.3E+05 ev/_llULi(670.8 nra) Enlin = 2.0E+03 eV/ainu, ElllaM = 2.0E+04 eV/_uu
AO AI A2 A3 A4 A5 ' A6
Li(2p -67.943? -.00943077 -.745522 -.II_088 .0453106 .0512591 .0]5508]
LI(670.8 nm) -66.267] .208208 -.0976231 .00780915 -.00712239 -.00227550 .00106025
The fit represents b,i(2p) cross section with ali rms deviatioll of 1.9%.The maximum deviation is 3.6% at 4.0E+04 eV/_uml.
The fit represents Li(670.8 nnl) cross section with ai] rms deviation of 0.3%.The maximum deviation is 0.4% at 2.5E+03 eV/_ml.
See appendix for Chebyshev fit details.
C-127
0H+ + Li(2s) -> Li(2p, 670.8 nm emission)
Cross Section vs. Energy-14-
rliJ '! I I I ,ICTI----" , , l Ill'Iii ' '"' II"lllt ' I | "1 I 1111
_ /_ A = Li(670.8nm)
x = Li(2p)
r-, - // __ /
E /
0 o 10-'5 X//"-_ Recommended(..)¢_ - Data
O0
0L.U - - ..... Chebyshev Fit
10-" L I I llllll I ._tt llilll I I I IIIIII l 1 I Jill,
10_ 103 ,10' 105 106Energy (eV/urnu)
C-128
Total Spect ra.l Line Endss.ion Cross Sect.lons for
He _ + L,i(2s) -> lie _ _ L,i(610.Snm)
Energy Velocity Cross Section(evlamu) (c;mls ) (c:m_)
5.0E402 3 lIE+07 5.58E-166.0E+02 3 40E{07 6.55E-167.0E+02 3 68E+01 7.48E-]68.0E_02 3 93E+07 8.43E-1690E+02 4 17E+O7 9.33E-.16I OE+03 4 39E407 1.03F-]5] 5E+03 5 38E+07 1.47E-]52. OE+03 6 2]E-I07 1.93E-152 5E+03 6 95E407 2.43E-]53 0E+03 7 6]E+07 2.90E-]54.0E+03 8 79E 1.07 3.39E-]54.5E_03 9 32E t-O7 3.51E-]55. OEr03 9.82E+07 3.52E-] 5
References: 267, 132, 734
Accuracy: Unknown
Notes: (]) The 2p -> 2s transition at: 670.8nm is the resonance t:ransition(2) The emission cross section includes cascading into the 2p state
from the upper levels., (3) As far as we are aware no data for t:.he cross
sections for tile 2p state excitation exist. (4) Myers et al_. (Re.[. 734)obtaiI_ed data for the emission cross sections in tile energy range 50_375eV/_mlu. Thei f measurements are an order of magnitude less t:han tile Ireconmlended data at 400 eV/ainu.
Chebyshev Fittinq Paranlete/s for Cross Sections
Eml n = 5.0E+O2 eV/ainu, Ema x :-- 5.OE.03 eV/rural
AO Al A2 A3 A4 A5 A6
-68.2494 .976730 .-.0528574 -.0520709 -.0299645 .-.00494558 .0067]922
The fit represents the above cross section wJtll an rillsdeviation of 0.5%.Tile InaxinIunl deviation is 0.8% at 2.0E+03 eV/aluu.
See appendix for Chebyshev [Jt deta.i.ts.
C-129
Q
He+ + Li(2s) -> Li(2p) (670.8 nm erniss,on)
Cross Section vs. Energy_f.,-14.IU , '_ --r'- 7 ,,, ',-l , ,' ,' , -
i
4 //
E /fO /
x._/ /Jc- ,,'
O 1_o !0- Recommended(1) --Data
Or)or)OO
LO Chebyshev FitU
I0 "I' J I __L _ _J J J I I L L._.L_ !_ J J L1
10_ 103 104Energy (eV/om u)
,,
C-130
,IDExcitation and Spectral biile Bmisslon Cross Sections for
He 2+ + Li(2s) -> He _'+ i Li(2p)
-> He z* + b.i (670.81"1111)
bi(2p) Li(2p) (cont.) l_i(670. 811m)
Energy o Energy o Energy o
(eV/aral) (cre2) (eV/auu) (cre2) (eV/euml) (cre2)
1.4E+02 3.90E-17 3.8E+03 2,79E-15 3.7E+03 2.92E-]52.0E+02 6.43E-17 4.0E+03 2.94E-15 4.0E4-03 3.]3E-153. OE+02 i. lIE-16 7.0E+03 4.93E-15 7.OE+03 5.21E-154.0E+02 1.62E-16 I.OE+04 6.57E-19 I.OE+04 6.96_]-155.0E+02 2.18E-16 2.0E+04 7.93E-]5 I. 5E4,04 8.45E-156. OE+02 2.73E-16 2.6E+04 8.12E-15 2. OE+04 9.07B-157.0E+02 3.28E-]6 4.0E+04 "2.50E-'15 2.6_]+()4 9.21E-158.0E+02 3.84E- 16 7. OE+04 6.04E-]5 4. OE+04 8.69E-159. OE+02 4.36E-16 ]. OB+05 5.10E- 15 7. OE+04 6.94E-15l. OE+03 4.90E-16 2. OB+05 3.25E-15 I.OE+05 5.81E-151.5E+03 7.52E-16 4. OE+05 I, 82E-15 l. 5E+05 4.70E-152. OE+03 9.89,E- 16 7. OE+05 I. 09E-15
]. OB+06 7.68E-]62. OB+06 3.93E-162.7E+06 2.95E-16
References: Li(2p) ; 73], 733, 735Li(670.81]nl) eiiiissiol]; 259, 733, 735
Accuracy : Unknown I
Notes: (1) The 2[9 -> 2s is the resonance transition of Li with × = 670.8nm.
(2 ) No attempt has been made to join the low energy data of Barrett andbeventhal (Ref. 259) to the data of Kadota et ai. (Ref. 733). (3) The data ofKadota et al. have been extended to 2.5xi0 (' eV/rural using the theoretical data
of Ermolaev et al. (Ref. 731).
C_hebyshev Fittinq Parameters for Cross Sections
[,i(2p) Eml n = ].4E+02 eV/ainu, Ema x : 2.0E+03 eV/6mlu
Li(2p) Enlin = 3.8E+03 eV/aJnu Ema x = 2.7E+06 eV/aJuuLi(670.8 nnl) Fmi n = 3.7E+03 eV/aUllu, Ema x = 1,5E+05 eV/_mlu
AO _1 A2 A3 A4 A5 A6
Li(2p) -72.1632 ].62490 -.0826001 -.0]]0092 .00206946 .00278599 -.00427450Li(2p) -67.5365 -i.31752 -.867548 .198289 -.0106036 .00118819 .0110240Li(670.8 rim) -65.6114 .210669 -.460311 .0351576 .0330529 -.008"14795 .00505234
Tile fit represeHts [,i(2p) exc]tat:ioll (:ross sectloll with an rms devtat-.tc)n oil0.2%.
The maximum devJatioi_ Js O.4% at 4.0EI02 eVainu.
The flt represents bJ.(2p) cross section w.iLh an Ims deviat|on of ].. 1%.The illaxiilltlnldeviation is 2.3% ai: 7. (}E-lO'{ eV/ainu.
The fit ,:epresellts Li(6/0.B nra) ,:;1:osm seut.ion w]Llt a_l ,:ms deviat. Jon of 0.4%.The illaX J.llltllll der] at iOll i F] O. !5%, 6:lt 7 . OB-t 04 6!V/[lllltl.
It
C.--l ] 1.
He:+ + Li(2s) ", Li(2p,-i 670.8 nm en-lisslorf}
i
D. Cross Sections for Ionizationand PrOduction of Charged Particles
(* denotes rate coefficient data also)
Page
H + H2 -> Total Slow Positive Ion Production , , , D-2-> Total Slow Electron Production ..... D-2
-> H + H2 * + e ................ D-4
H + + H -> H+ + H_ + e ............... D-6*
H+ + H- -> H2 + + e ............... D-12
H+ + H 2 -> Total Slow Electro]] Production .... D-14
-> H + + H 2 + e .............. D-16-> Total Production of H2 + ........ [3-].6-> Total Production of H + • ........ D-16
H+ + He -> Electrons and H- , ........... D-18*-> H+ + He + + e .......... D-24"
i " "-> (H + He +) or H_ + He + + e) ...... D-24"-> H+ + He 2+ + 2e , , , ........ D-34"
-> (H- + He 2+) or (H + + He 2'_ + 2e) ..... D-34"
He(21S) ' + H -> He + H+ + e ............ D-42
O -> Hell+ + e ..............D-42
-> (He + H_ + e) or iHeH _ 4-e) .... D-42
He(23S) + H -> He + H + + e ............ []-44-> Hell+ + e ........... ].]--44
i ' "-> (He + H + + e) or Hell+ + e) .... D-44
He(23S) + H2 -> Total Ionization ......... D-46-> Rearrangement Ionization ..... D-46
He(21S) + H 2 -> Total Ionization ........ [)-48-> Rearrangement Ionization ..... D-48
H + + He + -> (H' + He2_ + e) ........... D-50*
-> (H + 4 He 2' + e) or (H (_ + He ,!t) .... D-50*
}le' + He_ -.> (He' + He21 + e) ........... Ii)-58"
-> (}le + He _'' ) or (He" + He 2_ + e) . . . [)-58"
He + H 2 -> Total Slow Positive Ion Production , , D-64-> Total Slow Electron Production ...... D-64
-> He 4 H2 _ + e .............. D-66-> Total H i Production .......... (3-66
He + He -> Total Slow Positive Ion Production , , , D--68
O -> Total S]ow Electron Production ..... [)-68-> He + He_ + e ...... ........ D-70
-> He + He2_ 4 2e ............. 13-7()
D. (Cont'd)
He + + H -> Ile+ + H+ + e .............. D-72"
He + + H 2 -> Total Slow Positive Ion Production . . D-76-> Total Slow Electron Production .... D-76
+He + + H 2 -> (He + H2 +) or (He.' + H2 + e) ..... D-78
-> Total H+ Production .......... D-78
-> He + + H _ + H+ + 2e .......... D-78
He .+ + He -> Total Slow Positive Ion Production . . D-80*
-> Total Slow Electron Production .... D-80*
-> He + + He + + e ............. D-90*
-> He + + He 2+ + 2e ............ D-90*
He 2+ + H -> He2 + + H + + e ............. D-96"
He 2+ + H 2 -> Total Slow Positive Ion Production . . D-100
-> Total Slow Electron Production .... D-J00
-> Total H+ Production ......... D-102
-> H + Production by ionization Collisions D-102.|
-> Total H 2 Productio1: ......... D-102
-> H2 + Production by Single-Ionization . D-102
QHe 2+ + He -> Total Slow Positive Ion Production . . D-104*
-> Total Slow Electron Production .... D.-104*
-> He 2+ + He' + e . ........... D-II4*-> He 2+ + He 2+ + 2e ........... ]3-1].4"
H+ + Li -> H + + Li _ + e . . . ........... D-]22.
He + + Li -> He + + Li° + e ............ . D-126
He 2+ + Li -> He 2' + Li' + e ........... D-128.
D-2
Cross Sections for Slow Positive-lon and Electron Production in Col]Islonsof ,:ydrogen Atoms with Molecular Hydrogen
H + H 2 -> Total Slow Positive Ion Prod.
H + H..:-> Total Slow Electron prod.
Slow Positive Ion Productioll Electroll Production
Energy Cross Section Energy Cross Section(eV/amu ) (01,I_) (eVl eauu) (cm 2)
4.0 F.+01 5.51E-19 8.0E+01 2.83B-197.0E+01 i. 65E-18 1.0E+02 5.7 iE-.19I. 0E+02 2.51E- i8 2.0E+02 2. 65E-182. OE+02 3.37E-18 4. OE+02 9.67E-183.0E+02 3 17E-18 7.0E+02 2.38E-174.0E+02 3.26E-18 1,0E+03 3.98E-177.0B+02 4.73E-18 2.0E+03 9.33B-17I.OE+03 7 28E-18 3.0E+03 1.24B-16
2.0E+03 1 97E-17 4.0E+03 1.29E-164.0E+03 5 06E-]7 5.0E+03 1.32B-16
i. 0E+04 I 27E-16 7.0E+03 i. 50E-16" 2.0E+04 1 75E-16 l.OE+04 2.00B-16
4.0E+04 1 60E-16 2.0E+04 2.90E-16i. OE+05 1 15E-16 3.0E+04 3.08E-162. OE+05 8.14E-17 4.0E+04 2.98E-1640E+05 5.02E-17 7,0B+04 2.56E-]6
I, OE+05 2.26E-16
2.0E+05 i. 58E-164.0E+05 1.02E-16
d
References: 28, 30, 143, 287, 315, 323, 324 i
Accuracy. 20%
Notes: (i) The slow positive charge formation cross section is the sum of the
ionization cross section and the electron capture cross section, o_ = oi (H2 +
+ e) + o0-i (H" + Hz+). The dissociative ionization cross section (H + H2 -> H
+ H + + H + e) is only 2-5% of the HZ_ formation cross section in this energy
range. (2 ) At low energies most of the H2 + arises from electron capture
collisions. (3) The electron production cross section is the sum of ionizationand the electron loss or stripping cross section o = ol (H2 . + e) + o01 (H + + e).
Chebyshev Fittinq Pa rmileters for Cross Sections
Positive Ions Eml n = 4.0E+OI eV/6mm, Ema x = 4.0E+05 eV/cmlElectrons Emi n = 8.0E+01 eV/mms, Ema x = 4.0E+05 eV/mllu
AO AI A2 A3 A4 A5 A6
Pos. Ions -77. 2533 2.45645 -.972849 -,533057 -.0537388 .365771 -.]54454Electrons -75.9790 2.77048 -1.73727 .139659 -.062490] -.00991[339 .0680936
The fit represents the Positive Ions cross section with an rms deviation of 6.7%.Tile rtlaximu111 deviation is 14.9% at 7.0E+0I eV/6mlu.
The fit represents the Electrorls cross section with an rms deviation of 8.5%.
The maximum deviation is ±7.8% at 7.0E+03 eV/muu.
See appendix for Chebyshev fit detai_s. I
f.............IIl_............l_..........llll[lllIIllllll..........................................................................
D-3
tiH + H?.-> SLIm of Slow Positive Charges
H + H2 -> Surn of Electrons Produced
Cross Section vs. Energy-15
IU -- i ,i i 1 i iilt - 1 'T r-T-l fill i i i t ii iii r- l i 1l Ill I i --T--T-T"TTr
10-1_-_, J Jt_LLU.L_ _J..I lliilll ,J I lillJJl I _ I IJllll _L_LZJJ.ZI.
10' 102 103 10'_ lO5 106Energy (eV/am u)
ib
D-4
OIonizstlotl Cross Sections for
4-
H + H 2 -> H + H 2 + e
Ezlergy Velocity Cross section(eVImlm ) (cmls) (cm2)
2. OE+02 i. 96E+07 4.04E-194. ON+02 2."78E+07 i. 42E-187. OE+02 3.68E+07 3.32E'18i. OE+03 4.39E+07 5.48E-182. OE+03 6.21E+07 i. 49E-174. OE+03 8.79E+07 3.71E-177. OE+03 i. I_E+08 6.72E-17I. OE+04 i. 39E+08 9.30E-172. OE+04 I. 96E+08 i. 45E-16
2.8E+04 2.32E+08 i. 54E-164. OE+04 2.78E+08 i. 46E-167. OE+04 3.68E+08 i. 23E-161. OE+05 4 _39E+08 1.08E-162. OE+05 6.21E+08 8.13E-174. OE+O5 8.78E+08 4.99E-17
References: 28, 30, 143, 308, 315, 323, 325
Accuracy: 30%
Notes: (i) The ionization cross section is determined from either of two4
relations: oi = o - _01 or 0i = o - o0_le where o is the cross section for
fornlation of electrons, o01 is the loss or stripping cross section, o_ is
the cross section for slow ion fornlation, and o'6-i is the electron capture
cross section. (2) There is considerable scatter in the data _uong thevarious investigators.
Chebyshev Fittinq Pareulieters for Cross Sections
Enlii] = 2.0E+02 eV/mm l, Ema x = 4 0E+05 eV/_uu
AO A1 A2 A3 A4 A5 A6
-77.1205 2.47663 -1.43551 -.126243 .100447 .0662]20 -.0477593
The fit represents the above cross section witll an rms deviation of 2.7%.The maximum deviation is 4.1% at 7.0E+04 eV/ainu.
See appendix for Chebyshev fit details.
®
, D-b
O d '
t..
, H +,H 2 -> H + H2 + e
Cross, Section vs. Ener9y,[_ I ..... I 1 'r'llll' I , "1 i _i i i111 I _...... 1 i iiiii I '1 1, i i i i'1'
i
10-,6_
/_
__ -O
E©
'-_ t_- 17 Recommended/L) -
(u .... Data(/)Cn(./3
£- ..... Chebyshev FitLP
10-_1
10-1_ _ , i i llllll I 1 I 1 fill] L f 1 i",_[.. . i l I Jill
10_ 103 10' 1C_ 106Energy (eV/o m u)
J
D-6
Ionization Cross Sections c 0J_or
4. 4' +H + H --> H + H + e
Energy Velocity Cross Section(eVl_llu) (cmls) (cre2)
9.4E+O3 1.35E+08 1.62E-17I.OE+04 1.39E408 1.84E-171.5E+04 1.70E+08 4.21E-172.0E+04 1.96E+08 7.20E-173.0E+04 2.4]E+08 1.21E-164.0E+04 2.78E+08 1.39E-164.5E+04 2.95E+08 1.41E-165.OE+04 3.11E+08 ].40E-166.0E+04 3.40E+08 1.37E-167.0E+04 3.68E+08 1.30E-168.0E+04 3.93E+08 1.23E-1690E+04 4.]7E+08 1.16E-]61.OE+05 4.39E+08 1.fOE-161.5E+05 5.38E+08 8.72E-172.0E+05 6.21E+08 7.14E-173.0E+05 7.61E+08 5.14E-174.0E+05 8.78E+08 4.04E-177.0E+05 1.16E+09 2.54E-17I.OE+06 1.39E+09 1.88E-171.5E+06 1.70E+09 ].34E-17
References: 4, 261, 335, 336, 3137, 338, 339, 340, 34], 342, 383, 586
Accuracy: E > 4x]O 4 eV/_uu - 25%E < 4xlO 4 eV/_llu - Unknown
Notes: (i) Data above 4x10 _ eV/rural are the reconuuended data of Rudd, et al.
(Ref. 335). Below this energy, tile recent data of Shah et al. (Ref. 336 )indicate a ,larked departure from the evaluated data of Rudd. The data plotted
here in the low energy range are the recent results of Shah et al. (Ref. 336).(2) For a hydrogen atom target, the cross sections for slow electron production(o') are equal to the ionization cross sections (oi). For slow ion production
(o.) the cross sections are the sum of the electron capture cross sections (o01)-
and the ionization cross sections at high energies o = o = o i.
Chebyshev Fittinq Parameters for Cross Sections
Eml n = 9.4E+03 eV/_|lu, Ema x = 1.5E+06 eV/muu
AO AI A2 A3 A4 A5 A6
-75.5053 -.409785 -.996553 .355360 -.049000 -.0349984 .0437825
The fit represents the above cross section with an rms deviation of ].7%.Tile maximum deviation is 2.7% at 4.0E405 eV/_ml.
See appendix for Chebyshev fit details.
D-7
H+ + H-> H* + H+ + e
Cross Section vs. Energyo,e--'-- ,
._. 16,0 1 I I 1 I'111[ 1 I I I I Ill I ......... 1 I 1 1 t II11 I I I I I II
14,0 - ,_"_tl -
12.0 - _I
10.0 -E0
c-
O ,_o-_ 8.0 - -k)
br)O9O3
0 6.0 - - RecommendedU -- Data
/4.0 - - '.-!_ uY _'''e_'-s_evFit
/2.0 - /
/
0,0 ____.L.. I I I I1111 I 1 I I 111t[ 1 i I I II111 . 1 1 11 1111
103 10" ld 10' 10'Energy (eV/a m u)
q
p
D-8
AIonization Rate Coef f.icierlts for I
4 # "41t + H -> 1t -! H + e
Maxwell.ian - Maxwelllan Rate Coefficients (cm_/s)
H+
Temp. Equal H + Temp. (eV ) !
(eV) Temp. I000. 2000. 4000. 7000. i0000. 15000, 20000.
I.OE+03 9 60E-II# 9.60E-1i@ 5.16E-I0# 2.35E-09 _ ' 6.44E-09' 1.08E-08 1.74E-08 2 25E-08
1.5E+03 5 16E-I0# 2.59E-I0_ 8.64E-I0_ 2.96E-09 _ 7.18E-09 1.16E-08 1.79E-08 2 30E-O8
2.0E+03 i 29E-09' 5.16E-I0@ 1.29E-09' 3.61E-09' 7.92E-09 1.23E-08 1.85E-08 2 34E-08
2.5E.03 2 35E-09' 8.64E-I0@ 1.79E-09 * 4.29E-09 A 8 66E-09 ].29E-08 ].91E-08 2 38E-08
3.0E.03 3 61E-09_ 1.29E-O9' 2_35E-09' 4.99E-09 _ 9 40.E-09 1.36E-08 1.96E-08 2 42E-O8
3.5E_03 4 99E-09' 1.79E-09' 2.96E-09' 5.71E-09 A ] OIE-08 1.43E-08 2.OIE.-08 2 46E-O8
4.'0E_03 6 44E-09' 2.35E,-09 i 3.61E-09" [i.44E-09' I OI{E-08 1.49E-08 2.06E-08 2 50E-08
4.5E_03 7 92E-09 2.96E-O9' 4,29E-09' 7.18E-09 ] 16E-08 ] 56E-08 2.11E-08 2 54E-O8
5.0E+03 9 40E-09 3.61E-O9' 4.99E-09' 7.92E-09 1 23E-08 _* 62E-O8 2.16E-08 2 58E-O8
5.5E+03 I 08E-08 4.29E-09' 5.71E-09' 8.66E-09 1 29E-O8 I 68E-08 2.21E-08 2 6]E-O8
6.0E+03 i 23E-08 4.99E-09' 6.44E-09' 9.40E-09 1 36E-08 i 74E-08 2.25E-08 2 65E-O8
8.0E.03 .74E-08 7.g2E-n9 9.40E-09 1.23E:08 1 62F.-08 1 96E-08 2.42E-08 2 78E-08
I.OE.04 2.16E-08 1.08E-08 1.23E-08 1.4cJE--08 1.85E-08 2 16E--08 ?,58E-.08 2 90E-O8
1.2E¢04 2.5OE-08 ._.36E-08 1.49E-08 1.74E-08 2.06E-08 2 34E-08 2.72E-08 30IE-08
1.4E+04 2.78E-08 1.62E-08 1.74E-08 1.96E-08 2.25E-08 2 50E-08 2.84E-08 3 IOE-O8
1.6E+04 3.01E-08 1.85E-08 1.96E-08 2.16E-08 2.42E-08 2 [,5E-08 2.95E-08 3 19E-08
1.8E+04 3.19E-08 2.06E-08 2. 16E-08 2.34E-08 2.58E-08 2 78E-08 3.06E-08 3 27E-08
_.OE+04 3.35E-08 2.25E.-08 2.34E-08 2.50E-08 2o72E-08 2 90E-08 3.15E-08 3 35F_-O8
Accuracy: * - Possible Erlo_ Greater Than 10%
# -- Possible Error Greater Than ]00% O
Chebyshev Fittinq Parameters for Rate Coefficients
Exllin .... I.OE_03 'eV, Ema x :-- '2.0E+04 eV
H
Temp.
(eV} AO }\I A2 A3 A4 A5 A6
1000. -40.0051 2.76605 -.344647 -.0369496 .00899170 -3.564719E-04 4.064999E-04
2000. -38.7629 1.97055 -°100798 -.0656769 .0461132 .00211656 -].279077E-04
4000. -3'7.4352 1.22903 .0356592 -.0490361 -.00390032 .00203_2 2.011422E-04
7000. -36.4087 .743427 .0691035 -.0248017 -.00589077 5.652350E-04 3.380127E-04
10000. -35.8193 .504234 .0663753 -.0124429 -.00494956 -1.095647E-04 2.357336E-04
15000. -35.2398 .301656 .0518339 -.00363904 -.003]390'7 -4.112259E-04 8.863478E-O5
20000. -34.8966 .198907 .0391475 -5.009338E-04 -.00]98385 --3.886616E-04 1.159612E-05
Equal Temp.-38.7626 2.81265 -.736000 .106667 -.02068]6 .00733904 -.00]85096
See appendix for Chebyshev fit detail.s.
o
D-9
_I H+ + H->H*+ H* + e
Moxweltian- Moxwellion
107- , , , ' -, , ' i ,H Temp_
(eV)
a -- 1000.
:-._ 7 _ - 7ooo.
m
Eo • -- 10000.
c-
qp 9 m -- 15000.:_cD10- :_- _ --2'0000.qp0O
qp Recommended,.+,.J
o - Datapr"
10-l° ----- Chebyshev Fit
Equal Temp.
10 -11 .... I, I ,, _1 ' 1_ 1 1 1 F
0.0 2.s s.o 7.5 10,0 12.s 15.0 17.s 20,0H* Temp. (eV) :_10s
D.-IO
Ionization Rate Coef [iclents .[or
: -i 4. +tl + H -> I-I -t. H .t e
,
Beam - Ma×we.l.lian Rate Coel!.[_c.ients (cln3/s),
tl +
Teittp.. H Enez'gy (eV/ainu) .
(eV) 10000, 20000, 40000. . 70000. 100000, 200000 500000.
1.OE.O0 2.56E-09 1.41E-08 3,86E-O8 4.78E-O8 4,83E-08 4 43E-08 3.30E-O8
2.0E400 2.56E-09 1.41E-08 3.86E-08 4.78E-08 4,83E-O8 4 43E-08 3,30E-08
4.0E+O0 2.53E.-O9 1.41E-08 3,85E-O8 4,78E-O8 4,83E-08 4 43E-08 3,3OE-O8
7.0E_OO 2.47E-09 1.41E-O8 3,85E-08 4,78E-O8 4,83E-O8 4 43E-08 3,3OE-O8
I.OE#OI 2,4OE-09 1.41E-O8 3.85E-08 4,78E-O8 4,83E.-O8 4 43E-08 3,30E-08
2.0E+OI 2.27E-09' 1.41E-08 3,85E-08 4,/7E-08 4.83E-08 4 43E-08 3,3OE-08
4.0E+OI 2.1gE-09' 1.41E-08 3,84E-08 4,77E-08 4.83E-08 4 43E 08 3.30E-O8
7.0E+OI 2.]8E-09' 1.41EL08 3,84E-08 4.77E-08 4 83E-O8 4 43E-08 3.3OE-08
I.OE+02 2.22E-09' 1.42E-08 3.83E-08 4 77E-08 4 83E-O8 4 43E-08 3,30E-08
2.0E+02 2.42E-O9' 1.44E-08 3.82E-08 4 77E-O8 4 82E-08 4 43E-08 3.3OE-08
4.0E.02 2.88E-09' 1.49E-08 3,81E-08 4 76E-08 4 82E-O8 4 42E-08 3.30E-O8
7.0E+02 3.58E-09' 1.56E-08 3.79E-08 4 75E-08 4 81E-O8 4,42E-08 3,30E-08
I,OE.03 4.25E-09' 1.63E-08 3,77E-08 4 73E-08 4 8]E-O8 4 _IEL08 3.3OE-O8
2.0E*03 6.40E.-O9 1.81E-08 3,74E-08 4 69E-O8 4 79E-08 4 40E-08 3.3OE-08
4.OE+O3 1.02E-O8 2.09E-O8 3.71E-O8 4 62E-O8 4.76E-O8 4 38E-08 3.30E-O8
7.0E+03 1.49E-08 2.40E-08 3.7OE-O8 4 52E-O8 4.7OE-08 4 36E-08 3,29E-08
I.oE+04 I' 86E-O8 2.64E-08 3.72E-O8 4 45E-O8 4,64E-O8 4 33E-08 3.29E-OB
2.0E.04 2.73E-08 3.18E-O8 3.82E-O8 4,31E-O8 4.47E..O8 4 26S-08 3.29E-O8
Accuracy: * - Possible Bi:ro[ (li:eater Thall ]0%
# - Possible Error Cii:eater Thail ].00%
lm,
Chebyshev Fittinq Parmueters for Rate Coeffici�ult_.__s
Eml n = 1,0E+00 eV, Einax = 2,0E+04 eV
H t
Energy
(eV/amu) AO A1 A2 A3 A4 A5 A6
10000, -38.2968 1 12152 ,644681 ,100717 -,100166 -.0395957 .0026'5964
20000, -35.7290 .356274 .202092 .0620743 -,00276894 -,0115918 -,00410]54
40000, -]4, 1679 -.0162401 3.246363E-04 ,00754856 .00729055 ,00420183 .00124748
70000. -33.7606 -.0400418 -,0259461 -.0120904 -,00336001 2,548592E-O4 9,663075E-04
100000. -33.7?.04 -,O256605 -.0180094 -.0107132 -,00535053 -.00208862 -4.645604E-04
200000, -33 8801 -..0146171 -. 0_)902218 -.00477874 -.00229897 -9. 828762E-04 -3.658987E-04
500000, -34. 4565 -7,913823E.-04 -5. 710595E-04 -3. 486254E-04 -.]. 820028E-04 -;8. !54704E-05 -3. 5] 2063E-05
See appendix for Cllebysliev f:It details.
D-II
_ ' H + H+ ->H+* Iri*+ e
Bemm- Mmxwelllono_
' I(_D"-- 55.0 i I l illll I i 'I l iilll I v' I l]llll ..... l I l'i'liil I ..... I'I I IIIII
H Energy
50.0 - - (eV/a m u)
a --10000.
45.0x -- 20000.
-_0.0 - v --40000./-"x JH_
t i
_ --70000,35,0 -
o m • --100000
c 30.0
i ,__ m -- 200000.,o_N--.
_- 250 - - []--500000.(_) .
oU
¢_ 20 0 _ Recommendedo _ Data
15,0 - , -
...... Chebyshev Fit
10.0
5.0 -
0,0 l J i JJJill _ I i I l..IJJll 1 i i i liiil i J I ii!IlL___ i I i i iiii.
100 10' ld ld 104 ldH* Temp. (eV)
D-J2
0Associative Det ach,uent Cross Sections for
H + I! -> t-!_._ + e
Energy Veloclty Cross Section(eVl_ml) (c,,/s) (cre_)
2,0E-O3 6.21E+04 5 12E-144. OE-O3 8.79E+04 2 23E-]47.0E-03 I. ]6E+05 I 36E-14I.OE-O2 1.39E+05 i 08E-142.0E-02 1.96E+05 6 77E-]54.0E-02 2.78E+05 3 77E-157.0E-O2 3.68E405 2 [9E-]5].OE-OI 4.39E+05 I 55E-152. OE-OI 6.2]E+05 8.79E-164.0E-OI 8.79_;+05 4.96E- 167.OB-Of ]. ]6E+06 3.25E-16]. OE+O0 i, 39E'+06 2.32E-162. OE+O0 I. 96E+06 i. 27E-164.0E+O0 2.78E+06 5.18E-.]77. OE+O0 3.68E-_,06 2.3lE-] 7
References: 417, 418, 419
Accur acy__ 30%
No_tes.__:(i) The theoretical data of (Re[. 417 are w.l.tllln a few percent ofthe experimental data of (Ref. 438). (2) Measurements oi: D_ + D- -> D2 _ +
e are consistently 30.-50% below tl]ose for If' + H-. At energies greaterthan ] eV/an|u the fluctuatiol]s in tile data mask t:llis clif[erence.
Chebystlev Pittlnq Par_uueters for Cross Sections
Emir| = 2.0E-03 eV/ainu, Ema × = 7.0E400 eV/ainu
AO A1 A2 A3 A4 A5 A6
-68,6095 -3.63490 -.153293 -0.133084 -.0284]74 -.07874]0 .0439445
Tile fit represents tlle above cross see[:i.on with an rnls cleviat]on o] 2.2%.The lllaxilllUlll d_viat ion is 3.4% at 1.0E-D3 eV/ainu.
See appendix for Chebyshev fit der:ells
D-13
H+ + H-'> t-t_+ + e
Cross Section vs. Energy10 -I] '' 'i' i'i i'i,ii'l , i ii Ill'ii 'i ',"'ii'iilil , i r,,,i
\
10-'_ _- k
- -,,,A --
I'1
E -
r-
'45 Recommendedu 10- - ", -\\ -- Data
(J') "X,\(/-) ,,.
0 _ Chebyshev Fit
10-'1__z \
\\
10-1: .... _ J , ,J_J.LJ.1 i i ilJlJl J l I llllll I 'l..I Illl_o-_ lo-_ lo-' lo0 lo'
Energy (eV/om u)
D-14'
Total Slow Electron Production Cross Sect;ions for 0
.!
H + H 2 -> r, e
Energy Ve]oc.t ty Cros<q Section(eV/allltl ) ( till/s ) ( Clli _ )
5.0 E+ O2 3 1 ;/Et' O7 ;!. 44 E- ] 87.OE+O2 3 68E-tO7 2.15E-181. OE+03 4 39E407 3.32E-]82.0E+03 6 2]f!:tO1 7,85E-]84.'0E+03 8 79E+07 1.84E-II7.0E+O3 i 16E+08 3.67E-171.OF,+04 ] 39E+08 5.66E-]7
2.0E+04 ] 96E-t08 < 1.18E-]64.0E+04 2 78E+08 ].96E--16
6.5E'I'O4 3 54EI08 2.191_'1-].6"I.OE+04 3 68E+08 2.19E-161.0E+05 4 39E+08 1.96E-162.0E4'05 6 21E+08 1.33E-IG '4.0E+05 8 78E+O8 7.96E-177. OE+O5 1,16E+09 5,08E-.1.7i. 0E-t.06 ], 39B-I-09 3,74E-172. OE+06 1.96E+O9 2. O/E- 174.0E+06 2. l 1E t09 1.15E-I'75.0E+O6 3.09E-i 09 9.50E-] 8
Referencesl 30,' 36_ ,42, 45, 89, 2]7, 3]5, 335, 344, 345, 346, 347, 348,349, 350, 351, 352, 353, 354, 355, 356, 357, 358, 359, 366
Accuracy. i 25% O
Notes..! (1) The data are the recolumel]ded data of Rudcl et al, (Re[. 335).See this refererlce for an analytical fit to the data at low and high
energies. (2 ) The slow elect ton H+productioll cross sectlolls are the StillÁ Of.four react-.ionsl (a) H_ + H2 -> _ H2 _ + e (pure ionization); (b) -> II_ +
H + H + + e (ionization with dissoclation); (c) -> H' + I]_ -I e (double
ionization); (d)-> H + 211_ I e (electron capture wlth lonizat]on).
Che,byshev Flttil]q Par_ueters foL Cross ,, Sections
Et_in = 5. OE-I02 eV/milu, lilmax :_ 5.0E+06 eV/ainu
AO AI A2 A3 A4 A5 A6
-76,9159 .969378 -1,91735 -.0245092 .313763 -. 000351145 -.0992103
']']lefit represents the above cross FJeCt].oI/ with ali rills devlatioll of 3.1%.The lilax]nlullldeviation is 6.2% at 2.OEI-05 eV/ailut.
See append],x for Chebyshev f.tt detai]_t.
D-15
QH. + H_ -> Te
Cross Section vs. Energy,0-15 'i I I III11'1 t I I IIIll'l ' I I I lIT'III I i I illlll -F-I 1 11111
,/ "10--1_
.1_, -- '
(D -
_ , '
© -'-_ RecommendedL)
O ¢) DataLP)0Gor)
---- Chebyshev Fit
U 10_t;
lr_ -le i i lllllll i .t ll|llJl i I lllllil l I li!llll 1__.1!1111/',.J
lo_ lo_ 1o* lo_ _o_ ld'Energy (eV/Um u)
D-16
CrOss Seut:lons [or the F'urmat]on oi Po[l it.|W,_ lcJtiE_ Lt] Cult.L_llon£_ of_ I1' wlt. h I1_]
I1' 4. 1t2 -,> H" t. t-12_' -i e (S]ilc.ll.e [on]z,Til:.l.(nl]I.I+ + 14;! -> Total. Pi:udut_L.tclri or 1.1.,' ((_l.- '/kH;al. It]ii ll'oi.liiaL.[Lni)FIt + Ill! -,> Total Pi:odtir:L 1()ii or II i
Single lon.tzat.toll I-I2' Prochlut.[on tl _ pl:oc',uct].on
131lei-(/y C[oBs Sect.Loll It',lie.rg y C.to£iu- Section I_lle.l.'c]7 cJt'Ol._s Sect.Loll(eV/allltl ) ( Clll7) ( eVl allltl ) ( tilt" ) ( eV / allitl ) ( (_lii2)
50E-I-O3 1,231_',-17 6,01!',+O3 8,2313-16 5. O1_.I.03 3. I 11!;-;1770_H.03 ] 78F,.-;[7 /, 01!;.,403 8,37F7-] 6 6, OE-f03 4,931!:-i'/I 01]:-1.04 2 631.,I--17 ], OF,+O4 B, 03E-16 7, OF,-103 6, 11B-].71 5E+04 4 24F,-17 2,0_',I04 6..091.,]-.16 8.01_-I03 7.251_-1720E-I.04 6 23E-.17 4 ,or.,;-i04 4, ]3E-..L6 9, OF,-I.03 8,291_-.1730E+O4 1 30[,.':-16 7, Ol_].i-O4 2,931!:- [6 ;I, O1_104 9, .I61,]--I'/4 O1!;+04 I 831_-16 .I,OE-IO5 2.321];-16 .I.51_-104 t,171_-t66 01_4.04 2 201_-.L6 1,517]+O5 1,75E-16 .I • 7E-t 04 I, 2OF.,-1670F,.t.04 2 ] 7E--J6 2,01!:-t.05 .1 4 3 E- .[6 2, Ol!',-t-04 1. I 71.,1-] 610E+05 2 O4E-:16 4,0E405 _I 691_-I'1 2.5E404 .l, 02l_-.16] 5E'i05 t 74E-16 7,01]',+O5 5 511']-.17 3,OLq-104 8,361_-]I20F,-i05 1 441];-;1.6 .I ,OE+06 4 051_-.17 3,51_+O4 "#.O3h1-1740E+05 8 71E-17 I, 5B+O6 2 85[_-17 4, O[,]-I04 6.03E-177 OB+05 5 54F,-]7 2,0lZ4O6 2 24r_,',-17 4,5E-I.04 !%,24F',-11i OE406 4 O7F,-17 3,OE406 1 561_-1.7 5,O1!:-I04 4.62L,;-.1720E+06 2 24E-17 3,5t_t.06 ] 37E-.L73 01_'-106 1 571_,G-J73 5E+06 ] 37E-i73 8E+06 I.,28E-17
Referencesi 30, 36, 40, 89, 315, 346, 348, 350, 353, 354, 356, 360,361, 362, 363, 364, 365, 366
Accu_'acyl 30%
Notesl (1) Tile interact.tOll or 1.1_ with I12 to prodtlc:e tl2 + .ions illay fol..low, Olie of..two pathwaysl (a) ii' .t tt2 -> 11' .t 112_ + e, nint_l.te ion:Lsatiun; (b) I-I" -t. 1t2 -'- II+ H2+, electroll capture, 'P.Ive reactiollEi are illvo].ved t.ll tile prodtlc.l:.[Oll of I-It.LOllSl (c) ,H" + PI2+ -> Hi -t H + ii + + e, d.tssociative J.olltzat]_oll; (d) -> H+ -t. I-I_,-t. Ii* + 20, double ion.tzation; (e) -> H .t- H + I1+, elect;rort capture with 'dissociationl (f) -> H -t H_ + I-1_, -t e, t:i;allsfer .toli].zatlorl; (g) -> tl- -i. 2t-I',double electron eapture. (2) At energ].es ].esa t;llan 150 keV/ainu the total chargeproduction cross sect:lens (at*) are clomlllated b 7 e.tectroll cal.)tute. ( 3 ) W.ltlllllthe experlnlental error' the tota], charcje production cross sect.ten .t.l:i I-.ill? sameas the tot:.al cross section for prodLicillg 1-12,_. (4) Above 150 keV the single.ionization cross section (reactJ.on a) .is the doiuJ.llant, plocean to £orln posit::lvecharges or Hz+, (5) Cross sect-ions ar,_ avatlab.le for the . double ]on]zat.lon(Ref. 36, 348, 356, 360, 36!7) (re:Iclloll u). llowuver there are larged.[_tcrepauctes and these data are not: ]ilcltldecl here, Tile cross sei_t.ions a.re at;least an order of nlagnJttlde snlalJ.er thail thfl single £ollJzat.ton cross scot.tons,
_shev Fittillq Paraluetet-s £or Cross Sections
S1Ilg, |on, .F,nl;[ i1 = 5,01,]-f03 RV/milli, 1311.1ax = 3,81];-#06 c,V/aliiUI1;__ Prod, IDiu.til = 6,01,]i.03 eV/_unu, l']llla× .= 3,513+06 eV/aniu
. ---' 5 01_t'O4 eV/allltlH" {'rod, F,filill = 5,0[,]+03 eV/aliltl, Ellis x ,
AO A.I A2 A3. A4 Ab A6
Sing, Ion -75,4752 -,100192 -].,35816 ,230586 , I[177(JO -,157087 ,0102380l-ll _ Prod, -72,9713 -2,12495 -,260502 ,0542968 -,0219667 ,022.1.059 -,00312930H" Prod. -74.4647 .0986066 --.525436 .0018383I .0396132 .012104] -.00373826
The fit represents the ,_lllgle loll, Cl;oSS sect lee w.ltll all I-ltIR devlat]on of 7.1%,']?heniaxillltUllder] atioll is ]7.3% at: 2.01].i04 eV/fUllU.The flt repzeserltn the H2' Prod. cross sectioll with an rills der.[aLl.oil oi 0.4%.The maxlllltlnldevlation is 0.7% at 2.0E405 eV/_llti.Tile fit represents the I_) Prod. cross sectlon w| th an rillsdeviation oi 0.6%.
Tile maxllllUllldevlat]ol] is ].2% at 3.0EI04 eV/_ulul,
See appendix for Cllebyshev flt dcta.its,
ii
D-17
H+ + H?-> H+ +,H_+ + e
e-+ H2 ->, Total H* _roduction+ H_--> Total H2+ Production
Cross Section vs. Energy10-15
i
.
A=[H_ (Pos, on Form,)
x--> H. + H_. + e
V=[ H.
b-]8 •
Slow Ne.qat:lve Charge l'rodtlct:ion Cross Sect: ions t'or O
l
I! _' -t lie -> electrons and H"
Energy Velocity Cross S_ct ion(eV/al{m) (cm/'_) (chi
4,4E402 2°91E+07 9 65E-205,0t_+02 3,11E+07 i 16E-t97.0E+02 3.68I!H,07 1 92E-191.OE+03 4 391/,-t-0"1 3 28E-192.0E+03 6 21E4.O7 9 40E-194, OE+03 8 79E+07 2 73E-187,0E+03 1 161!:+08 6 35E-.18
].OE+O4 1 39E408 1 O9E-172,0E404 1 96E+08 2 96E-174.0E+04 2 78E408 6 68_-177.0E+04 3 68F+08 9 07E-171.OE+05 4 39E+08 9 28E-J'/
2;.0E-¢05 6 21E+08 6 86E-1'14.0E4"05 8 78E4.08 4 24E-177.0E+05 i 16E+09 2 77E-17I.OE+06 1 39E+09 2.09E-17i. 5E+06 1 7OE+O9 1.53E-172. OE+O6 1.96E+09 1,2OE-174. OE+06 2.77E:_.09 6,79E-1.85. OE+06 3.09E+09 5.63E-18
References: 40, 83, 89, 315, 335, 347, 353, 354, 355 357 358 359 366, t , , t
367, 368, 369, 370, 371, 3"12, 373, 374, 375, 376, 377, 378,
379, 380 O
Accuracy_! E > 4xlO 4 eV/ainu - 20%
E < 4xlO 4 eV/_itu - Unknown- see note (I)
Notesl (]) These data are the reconmlended data of Rudd et al. (Ref. 335). The_ta below 4xi[O4 eV/a]llU are strongly weight;ed by t:he experimeutal results of
Rudd et al. (Ref. 83) taken ill 1983. Several inve.qtlgators have investigatedthe low energy region, ali of them reporting cross sectiol]s higher than the
reconmlended data. (2) React ions ,:hat produce slow negative charges arel (a) H +4- He -> H+ 4 He + + e, sin[lle ionlzation; (b) H + + He -> H + 4. He 2'+ + 2e, double
io,lization; (c) H+ t He-> H + He + -> I1' i lie + -i e, capture with iollJzatioll or
transfer ionization; (d) H' -i tie -,-> H- t He 2' double elec:tron capture.
Chebysl_ev Fittiriq par_ueters for Cross Sections
= , = 50E+O6 eV/ainuElllJ.I ] 4.4E-t 02 eV/alllti Ellis x .
AO A 1 A2 A3 A4 A5 A6
-79.6795 2,14499 -2.18192 -,, 146.158 .362843 .0528.[27 -.123316
The fit represents the above cross uect: i on wit h nn mis devj at:j.on o.[ 4.4%.The maximum deviation ts 1,3% at: 2,0E+04 eV/ainu.
See appendix for C'hebyshev t. t t det:ails.
®
D-19
H+ + He -> electrons + H
Cross Section vs Ener9/-16 '"1 ! '- , , I' ,,'"'i ',,,,v ,_',--,r,_ , , ,,,,',I , , ,'mT
" /f \\
- / \\\\
: /f-_ -
¢N
_ -'0
c-O _
101_ Recommended
q) : -- Datau-_ /6q©L ..... Chebyshev FitU
'lC)-lg
10-_ ._._..u..uL __,102 103 104 105 106 ld
Energy (eV/a m u)
I i
...................................... _,_-- ld" ................................................. .......... ,11l ................... i ......... ii I II ,,'1 lille I_, ,, ..................... ii Iill[ I I I
D-20
Slow Negative Cllarge Production Rate Coefficients for O
H+ + He -> electrons ancl H-
Maxwell]an - Maxwell]an Rate Coefficients (cni3/s)
H
Temp. Equal He Temp. (ev)
(eV) Temp. I0. 750. i000. 1250. 5000. 15000. 20000.
I.OE+02 3.59E-13# 1.61E-13# 3,94E-]2* 6.17E-12 * 8 83E-12 A 1.02E-10 3.79E-I0 1.39E-09
7.5E_02 4.86E-II 3,10E-II 4.86E-II 5.54E-II 6 26E-II 2 24E-I0 5,.88E-I0 1.74E-09
I.OE+03 8.71E-II 5.57E-II 7.85E-II 8.71E-II 9 61E-II 2 84E-I0 6.79E-I0 1.87E-09
1.3E+03 1.37E-I0 8.74E-II 1.16E-lO 1.26E-I0 1 37E-10 3 50E-lO 7 76E-I0 2.02E-09
1.5E_03 1,97E-I0' 1.26E-I0 1.60E-lO i.72E-I0 1 84E-IO 4 23E-I0 8 79E-I0 2.16E-Q9
1.8E+03 2.69E-I0 1.72E-I0 2.11E-10 2,24E-I0 2 39E-I0 5 02E-lO 9 87E-I0 2.31E-09
2.0E+03 3.50E-I0 2.25E-I0 2.69E-I0 2.84E-I0 300E-IO 5 88E-I0 I 10E-09 2.47E-09
3.0E+03 7.76E-I0 5.03E-I0 5.66E-I0 5 88E-I0 6 IOE-IO 9 87E-I0 1 60E-09 3.11E-09
4.0E+03 1.34E-09 8.80E-I0 9.59E-I0 9 87E-I0 I OIE-09 i 47E-09 2 16E-09 3.78E-09
5.0E+03 '2.02E-09 1.34E-09 ] 44E-09 I 47E-09 1.50E-09 2.02E-09 2 78E-09 4.48E-09
6,0E+03 2 78E-09 1.88E-09 1 98E-09 2 02E-09 2.05E-09 2.62E-09 3 44E-09 5.20E-09
7.0E+03 3 61E-09 2.47E-09 Z 58E-O9 2 62E-09 2.66E-09 3.27E-09 4 13E-09 5.93E-09
8.0E.03 4 49E-09 3.11E-09 3 23E-09 3 27E-09 3.31E-09 3.95E-09 4 84E-O9 6.66E-09
9.0E.03 5 38E-09 3.78E-09 3 91E-09 3 95E-09 3.99E-09 4.66E-09 5.56E-09 7.40E-09
1.0E+04 6 3OE-09 4.48E-09 4 61E-O9 4 66E-09 4.70E-09 5.38E-09 6.30E-09 8.13E-O9
1.2E+04 8 13E-09 5.93E-09 6.07E-09 6 lIE-09 6.16E-09 6.85E-09 7,76E-09 9.57E-09
1.5E+04 ] 08E-08 8.13E-09 8.27E-09 8.31E-09 8.36E-09 9.04E-09 9.92E-09 1.17E-08
2.0E+04 1 48E-08 1.17E-08 1.18E-08 1.18E-08 I.]9E-08 1.25E, 08 1.33E-O8 1.48E-08
Accuracy: * - Possible Error Greater Than 10%# - Possible Error Greater Thai] 100%
Chebyshev Fittinq Par_lleters for Rate Coefficient's
Enlin = 1.0E+02 eV, Ema x = 2.0E+04 eV
He
Temp.
(eV) AO Al A2 A3 A4 A5 A6
10. -46.5650 5 499'7] -.475864 .0795255 -.103842 .0]46906 5.70]499E-04
750. -44.8867 4 19397 .198206 -.184815 - 0174624 -.00795734 00438872
I000. -44.5760 3 97780 .272829 -.192799 - 0215899 -.00569587 003942]7
1250. -44.3093 3 79820 .326679 -.!93047 - 0272627 -.00347228 00358121
5000. -42.1265 2 5090'7 .515276 -.0994986 - 0616701 -.004898'74 00584793
i0000. -40.7163 1 83020 .481655 -.0331261 - 0467863 -.0183645 00768600
20000. -39.1385 I 18831 .377951 .0]54712 - 023]939 -.0206727 00437997
Equal Temp. -45.6407 5 29550 -.441278 .0087]7]8 - 0827904 .010]600 00309937
See appendix for Chebyshev fit details.
D-21
Ii H* + He--> electrons, + H-
,Maxwellian- Maxwelian
D-22
SloW Negative Charge Procluctior_ Rate Coefficients for @
He + H t -> electrons and H-
Be6ml - Maxwellian Rate Coefficients (cm'_/s)
S +
Temp. He Energy (eV/_ml)(eV) 10000. 20000. 40000. 70000. i00000. 150000. 200000.
1.0E4'00 1.51E-09 5.59E-09 1.84E-08 3.]IE-O8 4.07E-08 4.]8E-08 4 26E-082.0E+00 1.51E-09 5.80E-09 ].85E-08 3.32E-08 4.07E-08 4.[8E-08 4 26E-084.0E+00 1.52E-09 5.81E-O9 ].85E-08 3.33E-08 4.07E-O8 4.18E-O8 4 26E-087.OE+O0 1.52E-09 5.81E-09 ].85E-08 3.32E-O8 4.07E-08 4.18E-08 4 26E-08].OE+01 1.52E-09 5.81E-09 1.85E-08 3.32E-O8 4.06E-08 4.18E-08 4 26E-082.0E+01 1.53E-09 5.81E-O9 ].84E-08 3.32E-08 4.06E-08 4.18E-08 4 25E-O84.0E+01 1.54E-09 5.82E-09 1.84E-08 3.31E-08 4.05E-08 4.18E-08 4 25E-087.0E+OI I_56E-09 5.85E-09 ].84E,-08 3.31E-08 4.05E-08 4.18E-08 4 25E-08I.OE+02 1.58E-09 5.87E-O9 1.83E-08 3.30E-08 4.04E-08 4.]8E-08 4 25E-082.0E+02 1.6%E..09 5.97E-O9 1.83E-08 3.30E-08 4.02E-08 4.18E-08 4 24E-O84.0E+02 1.80E-09 6.17E-09 1.84E-08 3.28E-08 4.01E-08 4.18E-08 4.23E-087.0E+02 2.03E-09 6.48E-09 1.85E-08 3.28E-08 3.99E-08 4.18E.-08 4.22E-08I.OE+03 2.26E-09 6.80E-09 ].87E-08 3.27E-08 3.97E-08 4.]8E-08 4.22E-082.0E+03 3.04E-09 7.83E-09 1.92E-08 3.27E-08 3.93E-08 4.18E-08 4.20E-084.0E+03 4.66E-09 9.70E-09 2.04E-08 3.26E-08 3.87E-08 4.]7E-08 4.17E-08
7.0E+03 7.06E-09 ].21E-08 2.19E-08 3.25E-08 3.82E-08 4.13E-08 4.]4E--08!.OE+04 9.37E-09 1.43E-08 2.31E-08 3.25E-08 3.77E-08 4,,09E-08 4.11E-082. OE+04 i. 59E-08 ]. 98E-O8 2.62E-08 3.29E-08 3.69E=O8 3.98E-08 4.02E-08
Cllebyshev Fittinq Par_neters for Rate Coefficients @
Emili = I.OE+00 eV, Ema x = 2.0E+04 eV
He
Energy
(eV/amu) AO AI A2 A3 A4 A5 A6
I0000. -39.3816 1.02698 .5'76534 .188719 4.425971E-05 -.0]55917 -.0198253
20000. -37.3350 .517958 .301257 .123942 .00937576 -.0100372 -.0129438
40000. -35.4715 .129405 .0937]38 .0477169 .O]18588 -4.8882OIE-04 -.003254337E-03
70000. -34.4703 .00355792 -.0123483 .0153783 -.011669156 .008J7185 -.00392000
I00000. -34.0898 -.0436120 -.0204578 -.00631264 -9.902555E-04 3.700060E-04 5.42_520E-04
]50000. -33.9953 -.0150052 -.0]21264 -.00832720 -.00470324 -.00198547 -3.364408E-04
200000. -33.9705 -.0219825 -.0119088 -.00528740 -.00226756 -°00102041 -4.501627E-04
See appendix for Chebyshev fit details.
D-'23
It'q_ He + H+ -> electrons+ I-I-
Beom - Moxwellion
I050.0 I i I IIiii] I I I IIiii] " ]--I'IllllII I I Ill]JII ]- I II Ii
He Energy
45.0 - ' (eV/a m u)
..... ,_.__ _ --10000.
40.0 _'__ -
----._:._._._ x - 20000.v --40000.
35.0 -/---x
-e. /, _ _,-700oo.e3
E 3oloo • -- 100000.
.+.a
(D m -- 150000.
'.G 25.0-q---_- El --200000.0
O 20.0 -_ Recommended
.+_o ---- Data
rv"15.0 -
Chebyshev Fit
10.0 -
5.0 I0.0 J i i JlilJl i I ililJ!l, I I IJl*li!l l I lillill i i llJlll
100 10' 102 I# 104 18H* Temp. (eV)
t)- 24
Iot+izat.+[or_ ancl Tc.)ta] lie + l.+t'+.+(luct 1o11 (.'ross Sect:.lOl+_ for
li + .I- He -> fl t .I lie + I+ (-+
H+ -I He -> (H -I He +) o]: (H + + He + -I e)
lonJ.mat :l.on Torai He + [,roduct :l.on
Energy Cross Sect: :1.cJrl Ellergy Ct:oss Sec, t J.on( ev/ainu ) ( _:'m2 ) ( _v lamu ( cm _ ),
I.OE+04 2.041'.]-]7 50E+O3 3.821_-17].5E+04 3.49E-]7 7 O13+03 7.641_]-172.OE+04 4.94E-17 ] 0I_+()4 .1,331!]-.163.0E+04 6.61F,..]7 2 O1!I+04 2.39E-164.0E+04 7.371_-].7 2 3t_;+04 2,43E-]67.0E+04 8.28E-17 4 0E._04 2.17E-16
9.0E+04 8.42E-1,7 7 0_:-104 ].58E-16I.OE+05 8.38E-].7 ] OE+05 1.22_.;-161.5E+05 7.65E'17 2 01_-I05 7.14t.]-:172.0E+05 6.69E-17 40E-IO5 4+27E-174.0E+05 4.26E-17 70E+05 2.84E-17
7.0E+05 2.82E-17 ] OE+06 2.18[..]-17].0E+06 2.18E-]7 ] 5E-IO6 ],6]+B-l'/1.5E+06 1.61E-17 20E+06 ].29E-]72.OE+06 1.29E-]7 40E+O6 6.75E-]83. OE+06 8.92E-]8 5. OE+O6 5.3]E-184. OB+06 6.7 ] F,- 18,5.0[.]+06 5.321.._-18
References: 83, 87, 89, 315, :]53, 354, 359, 368, 37], 312, 375,
376, 381, 382, 383, 384, 385, 386, 387, 388 '
Accuracy: 30%
Nqtes: (]) The total cross section for slow He + ion production is the sum ofthe electron capture cross (H + . lle -> H + He _) and the ionization cross section
(H . + He -> H _ + H. . e). (2) The cross section for production of He 2_ is two
orders of magnitude less thal] that for He + al]d' COlltril]tttes a rleg].igJble al]fountto t'he slow ion formation. (3) At: energies less t.hart 2 × ].05 eV/_nu the electron
capture cross section is the doml nant reaction in producing slow ions. Abovethis energy the cross section for fle+ formation j.._{tl]e semte as the ionization
cross section to form He +. (4) For cross sections involving the formation of
slow He 2. see the following set of data.
Cl]ebyshev Fittinc I Parmuete£s for Cross Sections
Ionization Eml n = ].0E+04 eV/ainu, Ema x = 5.0E+06 eV/_mlTot. He + Prod. EnlitI 5.0E+03 eV/ainu, Ema x : 5.0E+06 eV/alutt
AO Al A2 A3 A4 A5 A6
Iollization -76.3648 -.874453 -.88455_! .2"z] ]O4 -,OZ92448 -,0234184 -.0152807
Tot. He + Prod. -75.4062 , -1.41315 -,923'/45 .441895 -.193224 -.00636635 .0315740
The fit represents the lonlzation cross sect ion with an rms deviation of ].6%.The max_munt deviation is 2'.5% at 7.0E+04 eV/mnu.
The fit represents the Tot. lie+ Prod. cross section wJt:h an flits deviation of! 1.3%.
The maximum deviation is ].7% at I.OE+04 eV/6umt.
See appendix for Chebyshev fit det:ails.
D-25
H+ + He -> H+ -f- He+ + eH. +He-> (i-i+He +) or (H+-t- He+ +e)
Cross Section vs Energyh .,._ •
-1510 .......w.....i::_"i,,,ii - i --r, ,,,,fi.......i---r--T-1-rTrq.... r----r-TTT'TTr
--
z_ = - >Total Pie _ Prod.
'/"'_'-"'_"XxX x - - > H + + He + + e
. " '
LT.0
'4S Reco rr, me tided
(b ----Data(/-),,_
or)Or)
_ ...... Chebyshev FitU 17
10- -
10 -11_ I L, J llltll l J ,.LuJil l i J LJJJil Li J JiJJ
ld lO' lo_ lo_ ldEnergy (eV/ornu)
D-26
e,Ion.lzat-l.c_n Rat:.e (!c_e {:[ .Ic.l.ant s fof
I-I* 4 fle -> IIo .I. I.le* -I. e
Maxwe.[l:[an - Maxwe 1.I.l.ail RaLe C,oe[.[.[c.l.eilLtl ( [;.'lli3/,q )
H *
Tollip, ' Equal lte Tel, p, ( eV )
( eV } T_l,p, 5000, 6000, 7 OO0, ILO00, 10000, ! 5000. !O000.
I ,OE+O3 4.O7E-12# 1,33E-I0# 2°O7E-IO# 2,99E-I()l 4, OOE-IO#_ 6,69E- IOH ,51E-O9' ?. 50E-09'
1,5E*O3 5.51E-II## 2,99E-ION 4,O8g-IOH 5,31E--ION 6,69E-IOH 9.'78E-IOH 899-O9 _ 2 92E-O9 _
2,0t{,03 2.O'/E- 10# 5, ]IF,-IO s# 6,69E.- 1 Oft {I. I{tE- [O_ 9, '7 tlli:- IOH 1,32E-O9#_ :1OI,.I- O 9 ' 3 35[,1-O9 _
2 5gio3 4.68E-I0@ 8,1BE-IOO 9,78E-IO## 1,15E-09# I,]2E-09#l 1,7OE-O9' 711,:-.09_ 3 77E-O9'
30E._O3 8,1BE-IO#_ 1,15E-ogH 1.32E-O9@ 1,51[a:-09" 1,7OE-D9 * 2.O9E-O9' 13E-O9 _ 4 2()E-O9'
3 "ZIO3 1.24E-0911 ;1,5'IE..C)9' 1,7OE-O9' l,f19E-O9 _ 2,09Ee-O9' 2.5OE-O9' 56E-O9 _ 4 62E-09'
40EIO3 I 70E 09 * I 89E-Oel * "_ O9E-O9 _ "_ ]OE-Og' 2,5OE--09 * 2,92E-09 ° 99i,,-O9' 5 05E-09'
4 5EIO3 2,20F,-O9' 2°30E-09' 2 509--O9 _ 2 71E-O9 _ 2,97!E-O9 _ 3,35E-O9 _ 41E-O9" 5 47E-.09'
50E+03 2,71E-O9' 2,71E-09 _ 2 92E-O9' 3.13E-09 _ 3,35E-09' 3.77E-O9 _ 84E-09 * 5 89E-09 _
5 51_:+03 3,24E-O9 A 3,[31",-O9 _ 3 35E-O9' 3,56E-09 _ .3.77E-09 * 4,2OE-.O9 _ 26E.O9 _ 6 30E-09'
60EIO3 3,77E-O9' 3,56E'-09 * 3 7/E-O9 _ 3.99E-09' 4.2OE-O9' ,I 62E-()9 _ 5,6%IE-O9 * 6 72E-09 _
80E+03 ._ 89E-O9' 5,26E-09' 5 47E-09 _ 5,68E-09' 5,89E-O9* 6 3OE-O9 _ 7.32E-09 8 29E-09
I OE+O,i 7 91E-O9 6,92E-09' 7 12E-O9' 7,321_:-09 "/,521'_-09, 7 91E-(q 8.87E-O9 9 "19E-O9
I 2EIO4 9 79E-09 8.413E-O9 8,68E-O9 8,87E-09 9,06E-09 9 43E-O9 I003E-08 I 12E-O8
I 4E.O4 ! 15E-O8 9,97E-O9 I,OIE-O8 1.03E-08 l.,05F,-O8 I O8E-O8 1,17E-O{_ I,P. 5E-OB
I 6E+O4 I 3113-O[I 1,14E-O8 I,]51!-O8 1,17E-08 I,19E-08 1 22E-08 1.30E-O8 1,37E-08
I 8E_O4 I 46E-O8 1,27E-08 ],28E-O8 1,3OE-08 1,31E-08 ] 34E-O_I 1,42E-O8 1.49E-O8
20E+O4 1 6OE-OB 1,39E-O8 1,4OE-O8 1.42E-08 1,43E-OB 1 46E-O8 1,53E-08 1,60E-08
Acctlracyl + - Possible gri:oi Great:el. [Pllail 10% e
ii - Possible gi:r'of Ol:eatei Than 100%
C!__ebysliev Flt:tlnq ParaJnete[s ]:ot Rate Coeffic.ients
gllltl] = 1,09-t.03 eV, I:]llla x = 2.0f3-t 04 eV
tle
Temp.
(eV) AO AI A2 A3 A4 A5 AG
5000, -40,3451 2.341!83 -.2575[17 -,O218607 ,0131131 -,OO170960 -2 '22133E-O4
6000. -40,0282 2° 14145 -, l[16812 -.O325594 ,O117041 -7,73826E-04 -3 9t9199-_'4
7OOO. -39.7552 I .o_6806 ,132538 -. 0;1{153(I.I , OO991961 -.I, 95606E-O5 -4 64455E-O4
8000, -39_5164 1.82079., 0901635 -. 0415358 , O080. ,.IJS"_'r, 5.25545E-04 -4 72996E-O4
1OOOO, -39,1158 1,58360 -,0298040 -,O4249B6 , O()46 {1310 .OO]12.196 -3 B557OE-O4
15000. -38,3952 1,19217 , 04551187 -,O348519 -,00101950 ,00132410 -2 81514E-05
20000. -37,8995 .951'14}. ,0744487 -.0255952 -,00350613 8,715911,]-04 -4, 19401E-05
Equal 'l'emp. -4 1,0272 3,86757 -I ,06890 ,261511 -, 0564975 .OO926R56 -, 001193(l(l
,See appendJ.x fo_ Chebyshev [J t. clc-.,ta:i.].[-;
D- 2"7
t-I+ 4- Pie -..:.:,bl+ + He+ -i- e
Mc_xweliGn- MGxweliGn
Chebyshev Fit
Equal Ternp,,,
10-' ...... l , , , :_,l .......0.0 2,5 5,0 7,5 10,0 12,5 15,0 17,5 20.0
H+ Temp. (eV) "10_
I',-2_I
lOll.tzaL Ion Ratr, " ) •[.c el. I! 1 c:.l e.llt:_:_ fr)r
I-k_ -t I.I _ -> 1.1[-,_ t. I-I_ .I (_
l_eam -- Ma×we].[.l.all Rate C"c:_ell :l._.:.lenL__ (cm_:_/a)
tl +
Talnp, lie FIleZ'c_l_' (_V/alnu)(eV) 10000, 2000U, 4(_000, 70000, 100000, 20(H)00, 500000,
I,OE*O0 1045E-09' 9,09[_-09 ,! 051;:-0II 3 041i:-08 3 6[ll_-OB ,1 ]5E-Df] 3,55E-Of]
2,0EtO0 1,4'1E-09 _ 9,6f]E-09 2 05E-[)8 :3 O,IV,-Of] 3 6[11,I-0f] ,1 151it-Oil .1 55F,..Of]4,0E_O0 1,49E-094 9,67H-Og 2 05E-08 ] 041_-011 3 (iSE-O_l ,I |51_-.011 ] !;bE-Of]
7,OF,_OO 1,52E,,.U9_ 9,66E-O9 2 05E-of] ],O,ll_;-Of] ii 68E-0[_ 4 151_-Of] 3 55E-Of]
I,OE_01 I.,54E-.O9A 9,661..',-09 20,IE-O0 3 041_:..Of] 3 68E-Of] ,l lS[;:-OE_ ] .55D:-08
2,0I,'.t01 1 60_,-09 A 9',65E-09 2 0,1_-0[I 3 04E-Of] 3 (;llE-Of] 4 15['_,-Of] J 55E,-Of]
4,0E_O1 1 68E'-09 _ 9,64E-09 ;.'. 04[_',-00 3 04F,-08 3 67E-08 ,) I5_;-Of] 3 55E-Of]
7,0E_01 I 77E-09 _ 9,64E-09 2,04E-0_l ] 04E-08 3 6"lE-08 4 ISE-0[t 3 55E-08
I,0E_02 ] 05E-09' 9,651.I-09 '2,04E-0[I .I04E-08 3 67F',-Of] 4 15E-08 3 ,5"-.)k 0f]
2,0E.10;_ 2 08E-09 _ 9,71E-09 2,04E-08 ] 04E-08 3 66E-08 4 t4E-0f] 3 55E-0_.I
4,0E+02 2 45E-09' 9,85E-09 ?.,05E-0f] 3 04E-0B 3 66E-0f] 4 13E-0f] 3 55E-0f]
7,0E+02 2 91E-09' I 0]E-0tl 2,06E-08 3 04E-0[I 3 651,:-0B 4 [.]E-0f] 3 54E-08
l.,0E_03 3 .{.]E-09* i 03E-08 2,06_-08 3 041(:-0f] ] 65E-08 4 12E-0f] I 55E-01]
2,0E+03 4 5JE-09* } [t0E-0f] 2,09I_:-0f] 3 05E-0f] ] 63F,-0f] 4 Ill!:-()[l 3 ',SE-0f]
4,0E.03 6 51F,-09' ] 23E-0R 2,15E-0f] 3 07E-08 3 621;:-[)FI 4 0(II,1-0[I 3 55E-0f]
7,0E403 8 99E-.09 I 42E-0f] 2,2bE-0f] ) 09l;]-0f] 3 (]0E-0[I 4 05E-0f] 3 54E-08
1,0E_04 I ]2E-0f] I 58E-0[I 2,34F:-0f] 3 )lI_-08 3,5f]E-08 4 02E,.0f] 3 54E-08
2,0E¢0(I 1 70E-0f] 2 04E-0f] 2,59E.-08 3 |f]E-0f] 1,55E-08 3 cl4E-0[l 3 53E-C)f]
Accu[acy! * ' - Possil31e I_]:ror C,rc:at.et Tllal_ ]0%
tt - PossJ.bl.e [!lrro_: Clreat:et: 'l.'han 100% D
Cheb_shev Fitttr_c I Pat_ameters for Rate CoeJ:.f:t.cte,,!)ta,
' I_llli n =-: ] 0_:t 0{} eV, I' --- 2 [)I!;-t 04 eV' " lllE[X *
He
Energy
(eV/alml ) AO A 1 A2 A3 A,I A5 A6
10000, -39,1279 I, 16505 ,469"137 ,0f]13519 -, 022f]2f]'/ -, 01.8;'_]4I -,0025f] If]O
20000, -36,5805 ,285f][17 ,]9[)12fi ,0f]69452 ,0;:]'I093 4, ]4865'_-04 -3, f]7928E-03
40000, -35,3193 .0f]16359 ,0597659 ,0332395 ,0137513 ,003f]3099 I ,22161E-04
70000, -34,601] ,0145540 ,0116645 ,006212,14 ,002510f]4 6,93"186E-04 4,4'1956E-04 [
]00000, -34,2559 -,0155100 -.,00743994 -,00_.*_45]"__ -6 ,9"1240E-04 -I ,6]4901",'-04 2 ,33078E-05
200000, -34,0[75 ..,0200973 -,01 ]flSf]g - ,00582 |6"I -, [)0256q9[ -.9,F17'_58E-f)4 -2,32402E-04
500000, -34 ....3105 -.00181505 - 00|31097 -li, ;'.H'I 1£1F1-04 -5,0526[1[ _1 04 2, c"")4E-:.).,`, 04 -I ,0 143 4E-. 04
See apl)encltx tor (:hebyshev fJt (let:al l._:_
e
I._-?,9 '
0,Pie + PI+ --> Pie+ + H+' -t- e
Mo×weiliGnO_
IO,"- 50,0 ---1- 11 rt Jill + 1"_I1 i 11II(----T-TTTTTIT[---I--I 1 I 1 Iiii"---'F-I-T'TTTN
He Fnergy
45,0 - (eV/c+rntj)
A -- 10000,
40,0 _"-m - × -2oooo,} ,,.---------.----
35,0 I. _ . V -- 4.0000,/--,,
"_ ,_- 70000,
o 30,0 - • -- 100000,
c
'0 25.0 -t+.'-:"+- [] -- 500000.Q)0 .j.1
U 20,0 L'Recommended
o _Oata
Pr: 15 0 -
...... Chebyshev Fit
I0,0 =- -- +
5,0
IF
0.0 I i li_JJJl ,,__j. I litJiil t J H!liil i £+llilii:L__...t. i iliJJi
10o ,10' 102 1¢ 104 lOs
bl+ Temp. (eV)
D- 30
'l'ol:a.I Ho) l:)ro¢hlc"l: Lc)li t_atr, C.!oe[[lc,]c.,rlt:L1 for O
H ) -t+ lie -+,." (11 .t Iio*) c_r (11) 4 I-le* 4 e)
Maxwe.l l.:L.al_ - Ma×we.l..I.tan l_aL(++ C.c.el"_ l:lc_.Lel_t:_ (¢_111++/,_)
ii t
'['nllll) + l,klUa.l lie 'l'l-_llq:), ( oV )
(oV) !l)t/llllp, 1000, 2000, 4000° 70C)0, 10000( L5000, 20000,
I 01_'I)03 3,32E-IOU 3 32F,-I0_l {i,','IE-ID#_ 1,6BE-()9U 3,70E-09 ) 0,26E-09 _ 1,06E-08 _ I,,I�L,I-O0
i 5F,-)03 1 39M-09# 1 131_:+09# 1,(_SE-OgH 3,021,_-09' 5,,IIE-09' 0,001,.I-09_ 1,24P,-Ofl +I,65l#:-0[I2 01_+03 +I+C12E-C19 A 2 ]21+-Ci9 + 3,07+l++-og _ 4,50E-09' "l 12E.+Oq t 9,7+li+:+,09 ' I,4.|E-08 I,SLL,_-CA8
l, (. , +f)_.iO.l 4,90M-09' i+ 70M-(.)9' ,l,.)[il_,-O.) (+ 26B-09 _ tj 80F,-09 + L tS14-0rl 1,5'1Y_-08 1,96B-08
11 Ol_l+O.] 7,L2E-O9 _ 5 41E..09 A 6,26F,-,09' 0,0U_+I-09 _ t 061.,+-00 _ .l 32E -+ _ L,/JE-08 2,10E-08
3 5E)03 9,33E..-09 _ 7 121,:-Og _ 8,90E-.Og' 9,77F,..Og _ I 24E-08 _ 491_-t,:+ I,B[IE-08 2,24E-08
40E+D3 I, LSE-O8 8 L18H-O9 A 9+77F:-09 ( 1,151_-C)tI I 41E-O8 l 65E-O8 2,031++'-O[I ?.,37t++'-O8
4 5E)03 1,3"lE-Or1 L 061.,I-08' l,t._l:,-D(] 1,32E,-00 [ 57E-08 I 8IE-O0 2,17E-08 2,49E-08
50E+03 L,57E-08 i 2,1E-08 1+32E-08 L,49E-O8 I 73E-08 1 96E-,08 2,30E-OB 2,61E-00
5 5F,+03 1,77E-00 I 4LE-OB I 49F,-.08 [,65E-08 I _lSE-00 2,10[].08 '2,43E-08 2,72E-OB
60E)03 1,90E-08 I 57E-00 I 6'_iE-O[l 1,[IIE-08 2 031,_-.08 2,24E-08 2,55E-08 2,[13E-08
80E+O;, 2,611_-00 2 ]7E-08 ,_ 24E-08 _'_,37E-.08 "),,_5E-08_,, 2,72E-08 2,9BE-OB 3,20E_08
I OE+Oq 3,12F,-08 2 67E-08 2 72E-00 2,8.]I_:-08 2 9BE-08 3,12[,:-08 3,32F,-08 3,51E-08
1 2E)04 3,51E-08 3 07E-08 3 L2E-08 3.20E-00 3 321,1-08 3,44E-08 3,61E-08 3,76E-08
1 4E+04 3+82E,-08 3 40E,.O0 3 441,.i-08 3,51E-08 3 6IB-O0 3,'70E-08 3,[I,IE-OB 3,97E-00
1 6Et04 4,06E-08 3 67_-08 3 70E-O0 3,70E-08 3 }14[,-08 3,92B-08 ,I,04F.-Otl 4,[4E-08
I 8E+04 4,25E-00 3,90E-08 3,92E-08 3,97E-08 4 041'_-08 ,I,IOE.-O0 ,I,19E-08 4,20E-08
2 OB+04 4,40E"08 4,08E-08 4,tOE-OB 4,14B-0[_ 4 L9B-OB 4,25B-08 4,33E-08 4,40E-08
Accuracy) * - Po[_s.tb.te l!;rror (Iro, at:er Than ]0% iti - Possible _:t+].+o,.̀ Or,,aLer Tha.tl 100%
+
__lev F'itt;lllq Parallletera [or Rate Coe£flc.l.e!its
:= + + ) i__111t[ll ] Ohi't03 eV, t+' :: 2 (+1.,-t04 eV'ilia}<
lieT e llll'+,
(oV) /_0 AI A2 A3 A4 A5 ACi
10OO, -37,7759 2,3.5765 -, 5267't6 ,046L542 -,00599557 ,00186274 5,61892E-O5
2000, -37,3613 2°05214 -,389347 °00372548 ,003fl0397 3,22896E-04 1,92'/,12E-0"/
4000, -36,7649 1,63391 ..,227162 .-,032B342 ,00'199982 4,62850E..04 ..3,5+/'204_-04
7000, "L36, 1737 I,$:4696 --,100095 --,0449948 ,00515942 ,00147386 "4,77249E--04
i0000, "35,7678 ,998971 ",0496155 --,0432215 ,00'174125 ,00[80493 --2,03326E=04
]5000° --35,30211 ,734516 ",00387920 '''0346346 ",00171864 ,001448]3 --l,44086E--05
20000, --34'9844 ,566598 ,0150211 ",0?67530 ",0031307"/ ,00_108401 2,,07674E'04
Eqtlal Temp, -37,4591 2,34257 -,631509 ,0945062 -,0203712 ,00642863 -,00134327
See appendi× ffor Chebysl_o.v [.Lt deta.t.l+l
I._-3:1
0 H+ -t.- He --> (t-1+. He.") _,r (I-I"' "F t-le+ + el)
I
Maxwelli!::ln- Maxweliclr-1
x -- 2000,
Chebyshev Fit
Equal Temp,
10- I I____I. I0,0 2,5 5,0 7,5 10,0 12,5 15,0 17,5 20,0
H* Temp. (eV) "10'J
0
D- 3 2
Total tie _ Produc.t 1oll l_aL:e C,'oc_ [ F.t c I ellt_ .|!¢_I" O
He .I I-I_ -> (tie _ -t I1) cii (Ho,' i I1' t. e)
Bealll - MaXWe.L.l..[all Rdl;.e Coe[_.f]c.l etltq (c.'ltlLI/tt)
I1-t.
'.l'enlp, lie J_ll_ l, gy ( BV/allitl )
( _tV ) l 0OOO, 2OOOO, 40000, 70f)OO, l OOOOO 20{10[)O, 500000,
I ,OBtOO I, [14E-O8 4,6BE-OtJ 6, O;]E-O0 5, PiOF,-O[I 5,3OE-OB 4,4 41,]-OII ] 56E-011
2,O1tOO 1,84E-0ll 4,0{lE-Oil 6 O2E-O8 5,flOl.,l-,Ofi 5,361_-Otl 4,44E-O[I 3 56[4-08
4,OE.tOO 1,84E-OEI 4,6717:.,-Otl 6 O2E-OII '.i,l]OE-OFi 5,361_:-Oi71 4 44E-Ofl 3 56E-OR
7,OEtOO 1,li]E-Oil 4,06E-O8 6 O1E-OB 5,[IO1_,]-Oll 5,.]017,-Of.I 4 ,141_-O[i 3 501:I-Ofl
1,OEtOL 1,83E'-O8 4,66F,-O8 00IE-OII 5,1.10E-OI.i 5,.tt51_,-O8 4 441_-()1.1 1 56E-Ofi
2,OF, tO1 1,83E-08 4,64E-,0tl 600E-O8 '_.80F,,-.08 5,.101_]-00 4 44,P,-0[I LI 56F-00
4,OE_O1 l,[i3E-Otl 4.62F,-O8 5 g9E-08 5,TgE-OIi 5,36I_-O8 4 44I.,I-O0 3,56E-OI17,OE_O1 1,113E-O8 4.6OE-O[I 5 98E-O8 5,'19E-O[i 5,351,_-O8 4 441_:-O8 ],56E-OU
1,OE,02 t,O4E-Oa 4.59F,-O8 5 9"IE-OL1 5,79E-O8 5,351_-O8 4 44F,-O[i 3,56E-Ofl
2.OEI02 1,87E-08 4.55E-08 5 94F,-O8 5,7[iE.-Ofl 5,35E-O8 ,I 44b'.-O8 3,56E-O8
4,OE402 t,95E-O8 ,| 5[E-08 5 glE.-08 5,77E-.08 5,35E-08 4 43E-O8 3,56E-O8
7,0E#02 2,07E-O8 4 48E-O8 5 [17E-08 5,75E-O(I 5,34E-O8 4 44E-08 3,56E-08
I,OE+O3 2, 18E-O8 4 46E-O[I 5 85E-08 5,74E-O8 5.34E-08 4 44E-08 3,56E-O8
2,OE_O3 2.5[F,-O8 4 44E:-08 5 76E-O8 5.71E-0[I 5.]2E-Ofi 4 44E-08 3,56E-O8
4.OE+03 3,OOF,-O8 4 47E-O8 5 62_3.O8 5,64E-Oil 5,3OE-0[I 4 ,14E-OIl .1,56_-.O87,0E$O3 3.50B-O8 4 56E-08 5 46E:-08 5,5,1E-O8 5,25l;_'-OEI 4 44E-O8 3,56E-.08
l,OE¢04 3,86E-O8 4 64E-O8 5 35E-O8 5,45E-O[I 5,2[E-OB 4 44E-Q0 3,56E-O8
2,0E404 4,53E-O8 ,1 05E-08 5 16E-O8 5,21ELO[I 5,O5E-O8 4,47,E-O8 3,56E-O8
Chebyshev Fittinq ParaJueters for Rate Coe£ficients O
l']lllil]= l,OEIOO eV, ElllaX = 2.OE+04 eV
lie
Energy
eV/ainu) AO Al A2 A3 A4 A5 A6
1OOOO, -35,1311 .412881 ,220878 .05838311 -.o173[175 L.O2_6039 .-,OO620616
20000, -33°7794 -,OO396664 ,0221013 ,O2088'73 .(_O921146 ,OO114081 -,dOO146388
40000, -33,3338 ..,O658860 -.0346993 -,O127985 -,OO242907 °00117581 °00179130
70000. -33,3704 -,O391288 -,0249648 -,O133215 -,OO605125 -,O0211349 -2,49745E-O4
IO0000, -33,5061 -,0]93669 -.O135261 -,00817621 -,OO432298 ,.,OO189118 -6,O9453E-O4
200000. -33,8626 -6,2912OE,-O4 -9,61867E-04 -9.42621E/04 -7,2]387E-O4 -4,47888E-04 -2.11683E.O4
500000. -34.3009 -7.64617E-O4 -4,54422E-O4 -2,24604E-04 -1,49745E-O4 -1,31679E-O4 -5.40533E-O5
See apperldt× for. Cllebyshev £J.t: deta.l ] r..i
D.-33
• ,He + H+--> (He+ + H) or (He+ + H+ + e)
Beam - Maxwelianal
10'-" 70,0 ..........I' i"t l:_rlj ' _ i I lllTl'}'":' I I I'lllll I 'l 'l'l tllll I J _'l ITITI'"_ ,,
He Energy
65,0 - - (eV,/amu)
a -- 10000,60,0 _
55,0 - V -- 40000.
m 50.0 _ -- 70000,ED • --100000,
I+J
O r...: 4.5,0 -,¢2 []--200000,C)
_" 40 0 I_ -- 5000000
U
o 35,0 _ Recommendedra , -Data
EL
30.0 -
...... Chebyshev Fit
25,o-
20.0- / -
15.0 ,I I I lJliJl 1 I I IllJlll I I lllllll l I I JllllJ L I l IILIt
100 10 l 102 103 104 10 '5
" H* Temp. (eV)
O
D-34
0Ionization and Total He 2* Production CroSs Sections for
H . + He -> H _ + He 2_ + 2e
H _ + He -> (H" + He 2_ ) or (H _ + He 2. + 2e)
Ionization Total He 2_ Production
Energy Cross Section Energy Cross Section
(eV/_m ) (c,_I2) (eV/_,u ) (cm 7)
2.0E+04 1.40E-19 i. OE+04 4.97E-19
3.0E+04 4.46E-19 i. 5E+04 9.85E-19
4.0E+04 6.68E-19 2. OE+04 I. 49E-18
6.0E+04 9_ 69E-19 3.0E+04 2.17E-18
8. OE+04 ]. 07E-18 4.0E+04 2.3 8E-18
I. OE+05 9.95E- 19 5. OE+04 2.4 IE-18
i. 5E+05 7.42E-19 7. OE+04 2 3OE-18
2. OE+05 5.59E-19 ].OE+05 ] 8OE-18
3.0E+05 3.67E-19 ].5E+05 1 04E-18
4. OE+05 2.52E-19 2. OB+05 6 71E-19
6.0E+05 1.38E-19 3.0E+05 3 83E-19
8.0E+05 9.63E-20 4.0E+05 2 52E-19
I. OE+06 7.49E-20 7. OE+05 i 14E- 19
i. 5E+06 4.95E-20 ].OB+06 7 54E-20
2.0E+06 3.72E--20 1.5E+06 4 98E-20
3.0E+06 2.46E-20 2.0E+06 3 74E-20
4.0E+06 1,85E-20 4.0E+06 1 86E-20
5.0E+06 1.46E-20 5. OE+06 I 48E-20
References: 83, 87, 89, 315, 353, 354, 359, 368, 37], 372, 375,376, 381, 382, 383, 384, 385, 386, 387, 388
Accuracy.. 20%
Notes.- (I) The total cross section for producing slow He 2_ ions is the sum of the
double ionizatioll cross section (H + + He -> H_ + He 2_ + 2e) and the electron capture
cross section (H . + He -> H- + He2.). (2) At energies less than 3x.]O5_ eV/ainu the
production of He 2. is dominated by double electrozl capture collisions. (3) For
cross sections involving the formation of He + see the preceding set of data.
Chebyshev Fitting Par mlleter_ for Cross Sections
Ionization Emi n = 2.0E+04 eV/6ul_u, - 50E+06 eV/_l_u
Tot. lle2+ Prod Eml n i. OEr04 eV/eum_ Emax '. = , Ema x 5. OE+06 eVainu
AO Al A2 A3 A4 A5 A6
Ionization -86.8125 -1.69704 -.988419 .579481 -.140358 -.0229323 -.0091569]
Tot. He 2. Prod. -85.7168 -2.26739 -.987093 .602380 -.0759791 -.104008 .01495]6
Tile fit represents tile lonization cross section with au rms deviation of 2.5%.The maximum deviation _s 4.3% at 4.0E+04 eV/_llu.
The fit represents the Tot. He 2. Prod. cross section with all rms deviation of 2.7%.
The maximum deviation is 4.8% at 2.0E+05 eV/aJUUo
See appendix [or Chebyshev fit detai|s.
D-35
' _ H*+ He-> I-4+ +He _* +2e 'H* + He -> (H- + He_.) or (H.+ He_. + 2e)
D-36
QDouble Ionization Rate Coefficients for
He + H . -> He 2_ 4 H. + 2e
Be_ml - Maxwellian Rate Coefficients cm3/s)
H_Temp. He Energy (eV/ainu)
(eV) 20000. 40000. 60000. 80000. i00000. 200000. 500000.
1.0E+O0 1.42E-Ii* I. 85E-.i0 3.29E-I0 4,20E-IO 4.37E-I0 3.47E-10 1.78E-I02.0E+OO 1.44E-11' 1.85E-10 3.29E-I0 4.20E-IO 4.37E-I0 3.47E-]0 i. 78E-104.0E+O0 1.46E-II* I. 85E-I0 3.29E-I0 4.19E-IO 4.36E-i0 3.47E-10 i. 78E-107.0E+O0 1.49E-II* 1.85E-I0 3.29E-i0 4.19E-10 4.36E-I0 3.47E-]0 1.78E-I0I.OE+OI I. 52E-II* 1.85E-I0 3.28E-I0 4.19E-iO 4.36E-IO 3'47E-IO 1.78E-I0
2.0E+OI i. 58E-II* 1.85E-I0 3.28E-I0 4.1BE-lO 4.36E-I0 3.47E-IO I. 78E-IO4.0E+OI i. 68E-II* i. 85E-I0 3.27E-I0 4.17E-I0 4.35E-I0 3,47E-10 1.78E-I07,0E+OI 1.80E-II* 1.85E-IO 3.27E-10 4.16E-lO 4.34E-I0 3.47E-I0 1.78E-I01.0E+02 1.90E-II* 1.85E-I0 3.26E-I0 4.15E-IlO 4.34E210 , 3.47E-10 1.78E-I02.0E+O2 2.20E-II* 1.85E-IO 3.26E-I0 4.13E-IO 4;32E-I0 3.47E-I0 1.78E-IO4.0E+02 2.70E-II* 1.87E-IO 3.25E-I0 4. fOE-lO 4.31E-I0 3.46E-i0 1.78E-IO7.0E+02 3.34E-II* i. 89E-IO 3.25E-10 4.07E-10 4.28E,10 3.47E-I0 i. 78E-IO
I.OE+03 3.90E-II* 1.92E-I0 3.25E-10 4.04E-I0 4,26E-I0 3.46E-I0 i. 78E-I02.0E+03 5.50E-11' 2. OOE-IO 3.24E-I0 3.97E-i0 4.19E-lO 3.46E-I0 i. 78E-10
4.0E+03 8. lIE-II* 2.15E-IO 3.23E-10 3.85E-10 4.08E-]0 3.45E-]0 1.78E-IO7.0E+03 I. 13E-I0 2.32E-IO 3.21E-lO 3.73E-I0 3.94E-I0 3.42E-I0 1.79E-]O1. OE+O4 I. 40E-lO 2.44E-IO 3.20E-lO 3.64E-]O 3.83E-I0 3.39E-]0 ]. 79E-102.0E+04 2.03E-I0 2.71E-lO 3.18E-I0 3.45E-IO 3.58E-I0 3.28E-I0 1.8OE-IO
Accuracy: * - Possible Error Greater Than 10%
# - Possible Error Greater Than 100%
Chebyshev Fittinq Par_mleters for Rate Coefficients
Emi n = i.0E+O0 eV, Ema x = 2.0E_V04 eV
He
Energy
(eV/amu) AO AI A2 A3 A4 A5 A6
20000. -48.1754 1.30300 ,485174 .0480600 0457483 -.0219390 -7.65210E-O4
40000, -44.6402 .155683 .1OO'721 .0406747 00551141 -,00485389 -.00420546
60000. -43.6938 .0163971 -.004"78529 -.00179360 00131646 -I.05431E-04 8.93568E-04
80000. -43.2865 -.0824386 -.0435066 -.0165975 00387115 5.14172E-O4 I. 18040E-03
iO00OO/ -43.1958 -.0767199 -,0463123 -.0215537 00727208 -9,94415E-04 8. 20812E-04
200000, -43.5811 -,0170301 -,0127181 -.00866682 00530410 -.00278]53 -i. 19855E-O3
500000. -44,8971 .00488974 .00333081 .00168204 5 29597E-04 -3,6744OE-06 -7.72152E-O5
See appendix for Chebyshev flt detai,ls
D-37
QHe + H+ -> He_+-+ H+ + 2e
Beem - MoxweliGn
10-I _ , i i iiiiil , i i i lllli[ i i I lillll , I i I iilill I I i IILLL
100 10' 102 103 10'* 10sH* Temp. (eV)
l;)-38
Total tte 2+ Producttorl Rate 'CoeffJ.e:l.ents for
H* + tte -> (ti- + He 2+) -t. (11l -t. t.le _' + 2e)
MaxwellJ.an - MaxwelJ.J.an Rate Coet[ficJents (ClU]/S)
H+
Temp, Equal lie Tel,l). ( eV )
(eV) Temp. 5000. 7500, ]0000, 12500, 15000, 1"/500, 20000,
7.5E+02 7,68E-15# 2,03E-12# 6.81E-12# 1,47E-11# 2.53E-II# 3.80E-11 _ 5.22E-11' 6,'15E_11 _
I.OE+03 1.04E-13# 3.55E-12# 9.61E-12# 1.87E-11# 3.OIE-11# 4.35E-11' 5 82E-11' 7.38E-II*
1.3EI03 5,03E-13# 5.59E-12@ I•29E-II#' 2.3OE-11# 3.53E-II* 4.92E-11 _ 6 44E-II* 8.03E-11'
1.5E+03 1.45E-12# 8.15E-12# 1.66E-I[_I 2,77E-II# 4.07E-II* 5,52E-II A 7 O7E-II* 8.68E-II*
1.8E+03 3.12E-12# 1.12E-II# 2.08E-II# 3,27E-II# 4.63E-II* 6,12E-]I* 7 70E-11' 9.33E-II*
2,0E+03 5,59E-12# 1.47E-II# 2•53E-II# 3,80E-II _ 5.22E-11 _ 6,75E-II* 8 35E-.11' I._OE.IO _
3,0E+03 2.30E-II# 3.27E-II# 4.63E-II* 6•12E-II* 7.7OE-II _ 9,33E-ii* I foE-lo* 1 27E-IO _
4.0E+03 4.92E-11' 5.52E-113 7.07E_II _ 8.68E-II _ 1.03E-]0 _ 1,20E+IO* i 37E-IO* 1 54E-10 _
5.OE+03 8,03E-II*, 8.O3E-11 _ 9.66E-,11' 1.13E-10 * I 30E-lO _ 1.47E-10* 1 63E-.10' 1 80E-IO _
6.OE+03 ].I3E,*IO _ 1.07E-lO _ 1.23E-10 * 1.40E-IO _ 1 57E-10 + 173E..IO + 1 89E-10 A 2 05E-lO
7,0E+03 1.47E-I0' 1.33E-I0' 1.50E-IO* ],67E-]O* I 83E-10' 1.99E-I0 2 14E-lO 2 30E-lO
8.0E+03 1.80E-lO A 1.60E-lO* 1.76E-I0' 1.92E-10 A 2 OBE-IO 2.24E-I0 2 3fiE-lO 2 53E-I0
9.OE+03 2.11E-IO ].86E-IO _ 2.02E-10 2.18E-10 2 33E-I0 2.47E-IO 2 61E-10 "2 75E--I0
I.OE.04 2.41E-I0 2.11E-IO 2.27E-I0 2.41E-IO 2 56E-I0 2.70E-IO 2 83E-I0 2 96E-IO
1.2E+04 2.96E-I0 2.59E-I0 2.72E-I0 2.86E-IO 2 99E-10 3,]2E-I0 3 24E-I0 3 35E-IO
1.5E.04 3,66E-10 3.21E-IO 3.33E-10 ].44E-I0 3 55E-I0 3.66E-I0 9 76E-10 ].86E-I0
2.OE+04 4.50E-I0 4.04E-IO 4.12E-I0 4.21E-10 4 29E-10 4,36E-I0 4 44E--I0 4.50E-10
Accuracy: * - Possible Error Greater Tl]al] 1.0%# - Possible Ei:ror Greater' Than ],00%
Chebyshev Fittlnq Par_lleters for Rate Coefficients O
Emir] = 7.5E+02 eV, Enlax : 2.0E+04 eV
He
Temp.
(eV) AO A1 A2 A3 A4 A5 A6
5000• -47 9855 2.71190 ....99_62 -.0631734 .0152650 -+00140966 -4.92425E-O4
7500• -47.0952 2.12886 -.1199'77 -,O784054 .00'701306 .001511"12 76.61029E-O4
i0000. -46.4732 1.74892 -,0292041 -.0751534 3.23238E-04 .00245385E-03 -3.1562OE.-O4
12500. -46.0040 1.47944 .0203814 -.0667770 -,00376242 .00232506 5.55977E-O5
15000. -45.6322 1.27884 •0490457 -•0581142 -.00655132 .00]95763 1.43604E-O4
17500. -45.3276 1,11863 0651645 -.0499554 -.00809607 .00145805 3.73270E-O4
20000• -45.0718 .991107 .0746366 -,0430706 -.00880'789 .00106692 2.57551E-04
Equal Temp. -50.6204 5.07900 -1.59808 .393560 -.101018 .0175307 -.0014'7330
See apperldix for Chebyshev fit: details
D-3 9
_1t H* -t- He .->(H- + He_*) + (H* + hie:_++2e)
D-40
Total I-le 2 ' Prc, xltlc,'L [oil Rate (:oe [ [ to'.1 _i,l]L,,_ f o t i
He .t 1.1_ -> (lle ''_ .t tl-) t. (lie '!+ i. 11_ -I- 2e) '
Begun - Ma×we.l.] t.an Rat:e Coel!f:lc.len'ts (cre J/s)
H+
Tmlilp. lh+ l']ll_Jl gy (oV/,_lllitl )
(eV) 100OO. 20000, 400O0, 7O0O0. 00000. 1500O0, 2OOOO0,
l.OEIOO 3,56E-11 _ 2,92E-IO 6,61E-10 8 44E-IO 7 9OE-I0 5,'59E-:IO 4 ]'lE-lO
2,OE#OO 3,6OE-11 _ ?,92E-IO 6,61E-10 8 4,1E-IO 'I 89E-IO 5 59E-I0 4 17E-lO
4,OE+OO 3,67E-II _ '2.92E-IO 6.60E-10 8 431']-iO 7 89E,-]0 5 59E-|O 4 |7E-lO
7.OE_O0 3.74E-1]* 2,92E-IO 6,60E-10 fl 43E-10 7 88E-I0 5 59E-I0 4 I'/E-]O
i. OE_OI 3,8OE-I].* 2 91E-10 6.601,]-1,0 8 42E-I0 7 88E-lO 5 59E-I0 4 |TE-IO
2,OE._OI 3.96E-11' 2 91'E-IO 6,59E-10 8 41E-I0 7 86E-10 5 59E-10 4 17E-lO
4.OE}OI 4.20E-II* 2 91E-IO 6,59E-IO 8 39E-IO 7 85E-14 5 59E-IO 4 I'IE-IO
7,OE:_OI 4,49E-11 _' 2 91E-IO 6.58E-10 8 37E-IO '2 83E-|O 5 58E-IO 4 ]7E-10
1.OE+O2 _,73E-II* 2 92E-i0 6,58E-IO 8 36E-ID 7 81E-10 5 5BE-lO ,1 iSE-,IO
2.OE.02 5,41E-11_' 2 95E-10 6.57E-IO 8 3ZE-10 7 78[:-.]0 5 58E-IO 4 18E-10
4,OE_O2 6.55E-11 _ 30]E..IO 6.56E--IO 8 26E-Ii) 7 72E-10 5 57E-IO 4 1|9E-10
7,OEIO2 8.03E-11* ] IOE-IO 6,55E-IO 8 20E-.13 7 66_:-I0 5 57E-I0 4 ]fiE-iO
1.OEr03 9,37E-11' 3 18E-I0 6,53E-.10 8 15E-.]O 7.62i{-10 5 57E-10 4 2OE-IO
2,0E_03 1.33E-I0' 3 43E-IO 6.5OE-IO 8.OOE-.IO 7,48E-I0 5 56E-I0 4 22E-|0
4.OE+03 1,99E-.I0 3 84E-IO 6,46E-I0 7,73E-I0 7,26E-]O 5 54E-10 4,24E-10
7.OE.O3 2,77E-I0 4.32E-10 6,41E-10 7.40E-10 6,98E-10 5 49E- 10 ,I,27E-10
I,OE+O4 3,39E-10 4,69E-10 6.36E-10 7, 12E-lO 6,7,1E-I0 5 42E-JO 4,2}IE-IO
2. OE*04 4,75E-IO 5,41E-IO 6,21E-10 6,47E-I0 6,14E-10 5 17E-IO 4,24E-IO
Acctlracyl * - Possible Error Greater '['llarl]0%II - Possible Eftor Greater That] 100%
,Ch,ebyshev Fittjnq Par6uueters ior Rate CoefflcJents
Elllti] , = .[.OE+OO eV, Enlax =- 2.0Et04 eV
HeEnergy
( oV/anlu ) AO Al A2 A3 A4 A5 A6
IO000. 46.375"I 1.27650 ,480627 .048 _ "_ -,- _25_ 0511164 _- 0308841 -.00542828
20000. -43.5984 .264368 .158736 ,0549494 .00162732 - 00969406 -,00629046
40000, -42.3060 -.0238894 -.0125884 -,00618733 ,00280784 - 00102524 -4,8473OE-O4
70000. -41,9087 -. IO1626 -.0604596 -.O289603 -,0112319 - 00285512 3,95976E-O4
iOOOOO, -42.0360 -..0958542 -.0558944 -.0266235 '-.0108604 - 00350631 -4.83059E-04
i5OO00. -42,6352 -,O233424 -.0167110 -,O116669 -,OO760143 - 004]9389 -,O0181500
200000. -43.1811 _ .0113231 .O0418441 -8.73051E-O4 -,00251835 - 00215399 -,,00136312
See appendl.x for 'Ctiebyshev f:l.t detaiIs
[)'-41
He + H+ -> (He2+ -t- H-) or (He2+ + H+ -t- 2e)
i
t)-4?,
0PEIIIlIIII_r AaE4oC,:Ial-.1VE)i _;llICI'I'o!:al 10ni_,al..Ioll Cl'oai_ So(_.Lionn [(}r
lle(2tS) i. II _.> liE:-I III .0.E_ (OpI)
Ile(21S) i. H -> I.Ic:l.i_ .t e (c,Ai )I-le(21,.q) . i. 1-1-> (of' l ) -t ((.'ai) ('l'ol:c..i]. l(.m, )
'I'ot.alloll. (,I'I) l'ei111,loll. (Pl) AE_f._oc.loll. (Al)
I;]I1it tC.Jy O |lille l;(J_ '0 I!]llE) 17cJy o
(ev/mu) (dm") (,¢,..VI alUU) (c,u") ((_:VI a,ml) (_:.i_:)
2 . OIP,-O2 7.93 E- 1!$ 1, O1.P,- 0 2 6 O2l!:.-.1.b 1 9l!I-.02 l . I:1] i!I- :15, ,
2,b_-O2 "1,351_-15 2,OF,-O2 5 891!I-:1.b 2 Ol_l-()2 ],'l'llr,-[53, OIL_-O2 6,89 g- 15 3 . 0I!',-O2 5 3 4ll.;-1!_, 2 i:$llj_02 .1. !7_1I.'I-154,01!1-O2 6,19L_',-15 4,C)1_-O2 4 931'.I_-]5 ] O1_;--02 .I.,29l'_-1!)6,01r,-O2 5,16I!I-15 6,0Ii;-02 4 291!1-]5 4 O1!_',-02 9,781!I-168,0t']-O2 4,511_-15 ' 8,Ot11-02 3 E:13i!',-:l l$ 6 01_;-02 b,79LP-]6I'. 0_-.01 4.02t_-15 1., 0['I-0] 3 4"/I!I-1.5 8.01_-02 3,75B-:[6l . 3L_-01 3 . 491,',-I 5 ].31!I,-01 ] 1 .l.L_-I !._ .I . 01!;-01 2 , 601'_-],6
1 . 3I!;- 0] 1 . t30I!',-.1.6
r
Re£ere)lueBi 420, 421, 422, 423, 4;!4, 425 426 42"I 42f3 429 430l l l l l ,
4311 432, 433
_ccu[acyl 100_
No__t:ea__L(1) 'l'he total :ion.tz, at.t.c:)n o1 I1 by .low erlerc.jy tle(21S) ].a Llie UUlII c:)[ Penningtontzat:ton He(21S) ,t H -> lte .t-I-I + ) e and a_]a(.x'..tat..t.ve i(mtz, atton IIe(2-1S) .I-H -> Hell+ + e, (2) A1.1 data have beei) notnlaltz, ed t:o t:l_eotg al: ali :l.nteract::ton energyof. 0,O4 eV, (3) ?ota] tonJ.zat:[on .[_] _!)Olllet:.[lllO,E) ro[erred t:o aB ctlellltO_l.{_',at;ton, I(4) ?he energy of the 21S s]tal:e _4 70,61 eV wJt:h a ].:[Petllne o[ 2xlO-' _.)ec-,
Chebyull_.V F.ttt£nq l)arameter_ £or Cl.o_a Sections
Tot:al Ion, (']'I) I!lll.lll = 2,01'.]-O2 eV/alllu I_ ':= ] 31,.G-Oil eV/atoll.:,lllaX *
l-'elln 0 I Oil, ( PI ) .[.",lll.t.il ]., II1!;-02 (:!V/alllt.l', !_lll/:l× :- .l, ]/0--O1 eV/ailluABbOt, Ion, (Al) I:,iill.n ]. ,9f!;-02 eV/alilt.i , l,,lllaX = :l ,3I!°,-0]. eV/_ullu
A 0 A "I A 7: A ;I A ,I A5 A 6
"I'D ta I loll, ('I'l) -.65,7017 -. 40gEl'ItS -, 02fl0546 ,000"199090 , O00b;l{.iOll5 -, O01 ,1:1l;,{Ifi , (100701497
Penn, :loll, (PI) -66,Ofl43 -,3.129G0 -, 034'105171 , ()O147.227! ,0021 ;).425 ,001 lfl'/10 ,0OO,!(747 32
&[_BOC, Iori, (,li.I) -69,9529 -I ,]{i7"15 -, 135fi04 ,023;!B77 , O1'7:i{l(I7 .004':,4 l O2 , OOO920{t12
?lie [:1.I: rel)[euerit;Et Lhc ('I'1) r;ro[:l,,] uecJLIori _v.l.i;h <:Ill i:IIIN di!!v.l.al;.I.c)tl (ii O, I Pf;,'Pile. lllaX].llltllll clnvtal;.lOll :lr.i O, 2_, al: 3, ()F,-O2 oV/aHIti,
?lie I:.[l: i'etJret:-1elli:_ t:ll(_, (I'1) c.'rof:il.i floc'l:lrln _v:li.h <Till MIIF.I dev.tat..toll of O, I_0.'l'lin IIk'lXt.llitllll devtal;]ori J,_ O, .l_t, aL {;, 01_]-()2 oV/_:Ulltl,
.71-i;.Thr-., I:"it: rel)renent:_i t:he (AI) c:)o_:)<,_ ,,]r:,c._l:.ion v_lt:h an rmF_ {l(,mt;-)l::t_:)l_ til (), " <!l'lie nia×l illunl der lat: .|.orl 1 f:i 0,4_, <:li. ], 01,',-02 r.'V/alilli,
S_)(:, append:Ix for Chel_7_;illov f t l: (h,t_ll;l_i,
l)-4ZI
QHe(2'(-'lc,. + H --> He + H+ -t- e (Cr,_l.)
Ple(.2_S)+ H-'-" t--leH"-..Fe ([,:;AiI
10-1_ i T l I Io,oc)o 0,025 0,050 o,o-,,5 c),loo o,1:_5 o, ._o
Energy (eV/clrnu)
I;-4 B
i-le(.2:'S)+ H .-"> t-le -t-H" + e (o't,:,1'./t-le(]TJ:3S,)-t..H-> I-leH+ -te (.OAI.J
C rc} c,o cT-. .,. , ..
I0- 14.T-----"r-'-t---r-TTrTTT--f---r--I-T-rrTTF------r---I-q---rTTrrl----F---t--T-T-r-I"r-c
"a-.._.
10-'_=_--.. "---.._. ._-_T.,_,+_,_\"x, _7: JAI
"E .10-160
C© ',
:.,:..'s " \ Recommended(..) - ",,,
O cD % _ DeltaC/') - "",\tj') \,..
oU_ 10-,7_ ,_ _!L.)L" '- •...... Chebyshev. Fit
10-18,_
10-I___.__L_L_Lm.L_.I__L__4zL___L_L_L.LLU_U___,_ __I.LL10-_ 10-" 10o 10_ 10_
Energy (eV/am u)
L)-4fl
Total 0 13el|rl.[ll£10 atld I_artiall_j_-_lllOl'lt. J.Oll] z_lt; lC)li *Cl:o[_ Hec_t.lcm_l for /v
I.le(2,:iS) -t. t1_ -> Lot1 L_'ot:'lllaL.lOll
Tc:)ta.1 lOllJ.ZttL:[Oll ('.l'l) l;LOd:trl_allcJl;lllli.:!tlL [ollLz_tL J.oll ( I,tI )
i _ . , ,,0 • ),_,llSI. CJy CI'oBt:I _-tb'L I.oll Bllercjy C.] c ns _ec_t,l, orl( eV / tilllU ) ( CJlll") ( oV / alllti ) ( C;lll" )
2 OE-02 6,191!;-].'1 3 CIB..02 ] ;12t!;-;L7li i3 0 l.,- 0 2 .1. 0 2 I?;.;16 4 0 E - 0 2, .1. 2 2,Ill ;I."l
, 4 0 l!I,-0 2 :l.o4 5 I!',- .[ G 5 OI!I- 0 2 ]. ] '1_i,_ .L'l5 0 B- 0 2 :li 11917;-:16 6 0 III,- 0 2, 1 5 5 E .- l "l
, " ii6 01];-02, 2,361.,-;L6 "7 C)1]I-02 ;L "741_-;[77 OE-O2 2 841iI,-.16 8 01_G-02, ;l 92E-178 OB-02, 3 34E-16 .9 OE-C) 2 2 061li-.179 01.'I-02 ] 861i',-]6 .1 01'_I-0;1 2 .1.'9_-1.7;i 0 E.-0 ] 4 3 91!I- .16 ;l 5 I!;- 0 .L 2 7 9 t!t,- ;1'7.1 5 I_- 0 .l "l 2 .1li;- .1.6 2 0 IIt,- 0 .1 ] ] 5 B- ;i '7 ,.1. 7B.-O] 8 04E-]6 ] OB-0.1 4 47B-;17
4 0t]I-0] 5 55E-.1.15,0E-O1 6 58E-]'76,0 l'.-;-0 .l "1 6 2 l!.l- ;I 77, O1!;-0;1 Li 701_-;17'li 5 B- 0 ;l g 18 I_- ;1l
Refel:elicesl 4120 42]o 433_ 4]4o 4350 436_ 437e 4380 439t 44Ot 44:1_4420 4430 4441 4450 4460 447_ 448o 449t 450, 4b;ll 4521453 t 454, 455o 456
Acctiracy I, Ullkl|owI]
Notesl ( .l ) The II1OEISLII'elIK:JlII; o[ lilet:fiot_:lb.].ci Ile.1.J.LIIll ]11 I-I2 ].r_ w_r 7 d.1.£17tcu.lt; Elli01tile exper;[illellt;a], t'el_tllt8 are .l ilC!OllEl.[lTJtellt, Therefore the dat;a ahotilcl 11ol; bet;akeil E.i8 rib 8o.[ LII_.f.4, Tlle t-ota.[ iOlliZat'.[Oll c;IroEis Elec:t; i(Jll £i at; t lie t"llia.[ eiAe i7..£j:le f:lwh:l.ch are p.l.ot ted at: O, 03 eV / alllt.i vary by a [ acJtoi. _ of si.l{ alllOllCl etghtIlletit:ltl t'elllellt l,;I iii glow cl;[ 8c:harcjefJ _ [ ] C;IWJ.llC] a.[; i; e i;C:l.l.ow allcl lllel:cjed be_tllll!t, ( 2 ) Thep/:ocesses to folilll ions arei (a) Pellnitlg ].on:i.zat::loll (pr), !Ie(23S) 4 112 -> I.le 4.t-12t .i. e} (b) . associative iolIJ.zatJ.on (AI) t-le(23S) .i- I-1_ -> .IleH _ -t- el (c)
d.1.asomJ.ative :l.oll:Lzatiol_ (DI) He(23S) t. I17. -> lte .t- tI _ + H + el (d) Ro_arr.'al_gelll_:llt:Jorlizat;LOl] (RI) He(23S) 4. t-12 -> fieF1_ -t. H + el (e) Ion pair product:lOll (IPP)
He(23S) -i. I._2 -> lie + tl { -t- H', Tile stlnl c)f: t:her-Je processes :l.s kllow as t:ota.IJ qrlizatiorl Or chellLt.oliizat]oll} ( 3 ) Note t;hat the tot;al :LorlJ zation .t.s t:lle sallle'as Pei.lilillCJ ;[oilizat;ion wiLh.tn t:he e×perLnlel_t-a.1 orrorsl (4) The elU_rgy .1.eve.L oitile 2_S ia 19,1712, eV with a Iii!el;lille of 7900 ser;,
Chebysl!ev Fttt:l.llq Pa[aillet;ei:s .[or C_oss Sect.Ions
Tot: a.l. Ioll, (T[) !!lil:l.ll --" 2 ,0L,I-0 7 oV/alllti _ ._lila×li' :-- 1,, 7_-0]5 oV/allltit_earran,q, [ori, ( RI ) l_lli.t I1 -= ] , ()I_'-02 eV/allltl_ I!,lll_l× ::, 7 P,-O] eV/allltl
/_o Al A;', h;_ A4 Ab A6
ToLal ioi_, (T]) -72°0]62 1,203fJll -0OO6t4640 -,OO56.qO72 -,OO9[14OlIO -,OO595660 -,00,175204Raatrala 9, Ioil, (IAI) -76,1234 1.06951 ,O6lO2.51 -,0002799"24 ,O1649f1"1 -,O176903 ,C)O'723031
The [:l.t represellt;a the (TI) crot_l sect:ion w.li:ll :iil rllll;i deviat:i.ol_ o.f O, 2_,,t['t_e lilCl×.]lllt.llli devt tit;]Oll .1.li O, 3_, fit: b, 01_-02 eV/_lllll.i,
The [J t: represei;ts Lhc (Itl.) c;rof-JB [_lefit:.ton w;i t:h _:111 rill0 cleviat:.ioil of O, 5._,The lllEiXilll[llll devJ at;:l (:iii ;1s O, 9_, at 6,0t!',-0_ f_V/EiIIIti,
Sae appelid;[× fox: Cliebyshev 17_lt: del:ai]s0 i
b.-4l
0He(23S) + H2 ---> Ion Formation
,.
Cross Section vs. Er-lergyIU r-- i- t i -'m-r-r-q-I r T----I_r-'-T--T-I--
- //L
- / : O'Ti,P I
X = CrR,I
o
c-O
Recomrnendedc) it.J -
0 C/3@ _- /,,x -_ Do,o(]') _ /
cn /_ //
U_ _ // ...... Chebyshev Fit/
.//
-- /2..
//
-- /./
/,/
- /,J '
10 -17 ,__J i , i t i i l_l l t .__L I l I i ,
10-2 10-' 100Energy (eV/am u)
D-48
Total, Penning, and Rearral]gement Ionization Cross Sections for
He(21S) 4- H2 -> Ion Forlllation
Total Ionization (TI) Rearrangemellt Ionization (RI)
Energy Cross Section Energy C[oss Sectione V/alllU ) ,( cii| 2 ) ( eV/iullU ) ( Chi 2 )
2.8B-02 9.97E-1:7 3.0E-02 1.19B-173. OE-02 1.11E-16 4.0B-02 1.47E-173.5E-02 1,35B-16 5.0E-02 1.69B-174.0E-02 1'58E-16 6.0E-02 1.90E-175.0E-02 2.04E-16 7.0E-02 , 2.08B-176.0E-02 2.50B-16 8.0E-02 2.26B-177.0E-02 2.94B-16 9.0E-02 2.41E-178.0E-02 3.40E-16 1.0B-01 2.51E-179. OF.-02 3.77P.-16 i. lE-OI 2.55E-17
1. OE-01 4.07E-16 ] .5E-01 2.19E-17I.SE-OI 5.00E-16 2. OE-OI i. 83E-17i. 8E-01 5.39E'16 2.5E-0l i. 57E-17
30E-01 1.38E-174 0E-01 1.12E-1750E-01 9.61E-186 0E-01 8.38E-187 0E-OI 7.47E-]8
'l 5E-OI 7. 12E-18
References: 412, 421, 433, 434, 435, 436, 437, 438, 439, 440, 441,442, 443, 444, 445, 446, 447, 448, 449, 450, 451, 452,453, 454, 455, 456 ,IlL
Accuracy : U,]known W
Notes: (i) The measurement of meta'stable helium iz] H 2 Js very difficult andthe results are inconsistent Therefore, the data should not be taken as
absolute. (2 ) The processes to form ions are : (a) Penning ionization (Pl )He(21S) + H 2 -> He + H2 _ + e; (b) Associative lorlization (AI) He(21S) + H 2 ->
Hell2_ + e; (c) Dissociative ionizatio!l (DI) He(21S) + H2 -> He + H' + H 4 e;
(d) Rearrangement ionization (RI) He(21S) + H2 -> Hell_ + H + e; (e) ]on pair
pro,!'._ction (IPP) He(21S) + H2 --> He + II_ + H-. The sum of tllese processes is
kllown as total ionization or chemionizat ion. (3 ) Note that the Pellilingionization and the total ionization are the s_ne within experimental errors;(4) The energy of the 21S state is 20.61 eV with a lifetime of 2xlO -2 soc.
C!leb/sllev Fittinq Parmneters for C[oss Sections
Total Ion. (TI) Bmi n = 2.8E-02 eV/ainu, Ema x = 1.8E-01 eV/ainuRearrang. IOll. (RI) Emi n = 3.0E-02 eV/6ullu_ Ema x = 7.5E-0] eV/_m,u
AO Al, A2 A3 A4 A5 A6
Total Ion. (TI) -71,7445 .851023 -. 128729 -. N202443 .00116383 .0124597 -.000179356
Rearrang. Ion. (RI) -77.6786 -.311173 -.434644 .0826330 .0582759 -.040(1365 -.0150564
The fit represents the (TI) cross section with arl rms deviation of 0 .3% . I
iThe maximum deviationl is 0.6% at 7.0E-02 eV/6um_.
The fit represents the (Rf) cross section with all flus deviation i of 2. i%.The maximum deviation is 2.9% at 7.0E-02 eV/rural.
See appendix for Chebyshev fit details. Q
D-49
,.
He(2_S) + H2 -> Ion Formation
Cross Section rs, Energy10-'5 1 1 ' '1 I | I I 'l'j I '"l" I I '1 I '1 I
,/J/j. , , ,,-o-T,,p,x-c_ R
10-1_
©'-...y
c-O
'+_ Recommended
e °cb -_ Data
Of) _- "__. ,,".,..,0 ,,,.
U ]0-17 "-"-,_.. Chebyshev Fit
"'x
m
10_ J ' J _ J _' '_ _ J , , _L_EL10-= 10-' 100
Energy (eV/o m u)
D-50
iIonization and lle2' Production Cross Sections for
H + + He + -> (H + + He 21 + e) (oi)24
I'1_ + He + -> (tt* + He 2+ + e) or (H ° .t- He zl) (olt e )
Ionization lle2_ Production
Energy Cross Section Energy Cross Section
(eV l_m ) (cnl2 ) (eV/mm, ) (clll2 )
2.0E+04 4 20E-19 3.7E+03 9 25E-20
2.5E+04 7 50E-19 4.0E403 i 08E-19
3.0E+04 i 18E-18 5.0E+03 I 62E-19
3.5E+04 I 67E-18 6.0E+03 2 41E-]9
4.0E+04 2 21E-]8 7.0E+03 3 55E-19
4.5E+04 2 80E-18 8.0E+03 5 35E-19
5.0E+04 3 42E-18 9.0E+03 7 92E-19
6.0E+04 4 69E-18 1.0E+04 ] 12E-18
7 0E4.04 5 92E-18 1.5E+04 4 31E-18
8.0E+04 6 98E-18 2.0E+04 9 33E-18
9.0E+04 8 00E-18 2.5E+04 1.44E-17
I.OE+O5 8 97E-18 3.0E404 i 89B-17
1.5E+05 ] 09E-17 4.0E+04 2 52E-17
2.0E+05 ] OIE-17 4.5E+04 2 71E_17
3.0E+05 7.74E-18 5.0E+04 2 86E-174.0E+05 6.36E-]8 6.0E+04 2 96E-17
5.0E+05 5.19E-18 7.0E4-04 2 93E-.178.0E+04 2 81E-17
9.0E+04 2 64E-17
i. 0E+05 2.42E-17
]. 5E+05 ]. 75E-17
2.0E+05 i. 36E-17
3.0Ef05 8.97E-18
.OE+05 6.56E-]8 I4.0E+05 5. ]2E-]8
References: 69, 73, 75, 76, "77, 81, 278, 279, 458
Accuracy.' Ionization 60%
He 2_ Production - 30%
Notes: (1) The production of He 2_ arises fronl two processes: (a) Charge exchange (H
. He _ -> H + He 2_) arld (b) Ionization (H+ + ]le+ -> II+ 4 He 2+ + e). (2) At energies
less than approximately 2.0 - 3.0xlO 5 eV/aJuu the charge exchange process Is
donlinant. Above this energy the ionlzatioll reaction dominates.
Chebyshev Fittii2q Par6uneters for Cross sections
.... 5. OE405 eV/anluIonization Eml n 2.0Ei 04 eV/ainu, Ema x
He 2+ Production Ellli.n 3.7E+03 eV/_llU Enlax: , -'-' 5.0E+05 eV/amtl
AO AI. A2 A3 A4 Ab , A6
Ionization -80. 4308 1.24048 _.890202 .00]45922 .0570045 .0193037 -.0014614/
He 2+ Production -80.5893 2. ]0007 -1.81896 -. 00398}_87 .325128 -.125749 -.00193823
The fit represents the Ionization cross section with nn inis Cteviatton of ].!%.
The lllaxinlulll doviation J s 2. 1% at: 3. OE+05 eV/am:l.
The fit represents {;he tte 2_ Pt-oductioli cross sect:loll ,with an rim} deviation ot: 3,2%
The maxinlum deviat-ion is 6.2% at: 3.7Et03 eV/anul.
See appendix for Chebyshev fit: det:aiIs. A
D-51
QH 2+ 2+H+ +He +->(H + +He _++e) o_(H+ e )(CrHe )
H+ + He+ -> H+ + He_*+ e @i) _
Cross Section vs. Energy0-161 _- ' ' , ' ,,,,m " , ,-_',,,,I • , , , , r,,,
A --_He 2+
X--ct
10-17-Z
z
- /_ - .o /c".9-_ - Recommended_) 10-la_
_ - DataV) ZU)CD
0L_
U ChebyshevFit
10-_._
103 10_ 10s 1#Energy (eV/am@
D-5 2
0Ionization 'Rate Coe fI::lcient s' for
Beau -, Maxwellian Rate Coefficients (cnl3/S)
H+'
Temp. He + Energy (eV/ainu)
(eV) 20000. 40000. 60000. 80000. ]00000. 200000. 500000.
l.OE+O0 4,25E-Ii* 6.14E-lO ] .60E-09 2.70E-O9 3,89E-09 6.27E-09 2.55_l-09#
2,0E+O0 4.30E-]I* 6. ]4E-lo 1.60B-09 2,74_]-O9 3.93E-09 6.27E-09 2.55B-O9fl
4. OE+O0 4.37E-]I* 6.14E-lO 1.59E-09 2.74E-O9 3.93E-09 6 27E-09 2.55E-09#
7. OE+O0 4.46B-II* 6.14|;]-10 i, 59E-09 2.74l!;-O9 3,93E-09 6 27E-09 2.55E-O91t
i.OE+OI 4.52E-ii* 6.15E-10 i. 59E-09 2.74 F,-O9 3.93E-09 6 26E-09 2.55E-O9|I
2.0E+OI 4.70E-II* 6.]6E-I0 1.60E-09 2,74E-O9 3.92E-09 6 26E-09 2.55E-09#
4.OB+OI 4.98E-11' 6.18E-I0 ].60E-09 2.74E-09 3 92E-09 6 25F:-09 2.55E-09_
7.0E+OI 5.30E-li* 6.21E-lO ] .60_]-09 2.75E-O9 3.91E.=09 6 25E-09 2.54E-09#
l. OE+02 5.57E-II* 6.24E-I0 I. 60E-09 2.75E-09 3,911'.]-09 6 24E-09 2.54E-0911
2.0E+02 6.36E-II* 6.35E-]0 ].61E-09 2 76E-O9 3 90E-09 6 23E-09 2 54E,09@
4.0E+02 7.68}_]-]]* 6.56E-]0 1.63E-09 2 78E-09 3 89E-09 6 2]E-09 2 54E-09#I
7.0E_02 9.48E-]I* 6.87E-]0 1.67E-09 2 81E-09 3 89E-09 6 ]9E-09 2 54E-0911
I.OE+03 ].]2E-]0* 7 17E-lO 1.70E-09 2 83E-O9 3 89|_-09 6 18E-09 2 54E-09#
2.0F,+03 1.69E-]0' 8.17E-I0 1.80E-09 2 89E-09 3 9]E-09 6 ]3B-09 2 53E-09#
4.OE+03 2.88E_]0 I.OIE-09 1.98E-09 3 OIE-09 3 96E-09 6 05E-09 2 52E-0911 I7.0B+03 4.80E-I0 1.27E-09 2.22E-09 3 17B-O9 4 02E-09 5 95[!:-09 2 51L']-O9#
1,OB+04 6.80E-I0 ].5]E-09 2.42B-09 3 301_-O9 4 07E-09 5.86E-09 2 49B-0911
2. OE+04 i .34E-09 2 .16E-09 2.93E-09 3 .62E-09 4 21B-09 5.6OE-09 2 44E-0911
Accuracy: * I- Possible Error Greater Thal] ]0%# - Possible Error GreateL" Than ]00%
C!lebyshev Fittlnq Pa_m|eters for Rate Coefficients
Blllil]:: ]. OE+O0 eV, F]max : 2. ()E404 eV
}le+.
Energy
( eV/alml ) AO Al A2 A3 A4 A5 A6
20000. -45 6943 1.5"2907 .710583 .]I75768 -.0070545] -.()2R4130 -.0139117
40000. -41 81"17 .512347 .313944 .126340 I .02,388]] -.00849678 -.00968659
60000. -40 2324 .239690 .153320 ,066]005 .0168874 -.00195984 -.00376827
80000. -39 3054 . i]1744 .065_773 ,0331289 .00699774 .OO254954 -.O0222)7 ]
iOOO00. -38 6923 .0227031 .0195819 .O1,19078 .0027]827 .00119878 -.00147599
. _. _. . _ -I-o200000. -37 825'7 .O438823 -,0248902 OI '23[178 O[)5500,{ P. -. 00[_O868[] 5 . ;!7()L_8,,E-O4
500000, -]9 5936 -. 0]467 ] 7 - .I0097{7 II _9 --, 005243]6 -, 00267[_ ] ] -, 001 ] 9] :]2 -4, O'10685E-04
See append,ix IfO_[j Chebysl]ev . .][ i L []6_|:p.IIj.] S O
/
D-53
He + + H.-> He2+ + H+ +e
Beam- MQxwellian
10--8 _ -, :,_ 1 i IIIIII I I' I Illlll I I I I iiiil-r---] 1 i ilr]-[] illil.,
f:T - He* Energy, , _ -
- - (eV/amu)
.___..I._,_, A --20000.
. :. x - 40000._,, v --60000.
,_, 0-91 - -: _ -eoooo.-
e - • --100000.--
('-" _ _
,0 m --200000.
"- [] --500000.(1)0 -
U
(u ,,J / Recommended
.+..,_
o lh-_o_ ----Data
--
- / - Chebyshev FitX:
10-1 , i i llllll ' I I I lliJ!l I LLL!IIII 1 I I llllll I I I 1111
100. 10' 102 103 10' 10sH* Temp. (eV)
'D-b4 ,q
0He 2_ pt:oduct:/on Rate Ooe_f[].c.t.ents for
H+ + He _ -> (H _ + He 24 -t e) of (1.I + He 2')
MaxweJ.llan - Maxwe.t.i.l.aJ_ Rat:e C'oel!£].c].e]lts cml3/s)
H+
Temp. BClU_l lieF Temp, (eV)
(eV) Temp, iO00. 2000, 4000, 7000, 100001 ]5000, 20000,
i
3.OE#02 1,95E-15# 4.34E-]4H 3.74E-13# 3,02E-12# 1,65E-iI _ 4,93E-11 I .62E_,1.0 3,47E-iO
50E+O2 9 77E-14_ 2,70E-13# I.O4E-12# 5,22E-12 _. 2.30E-]I* 6.23E-II I 87E-I0 3.83E-I0
7 GE+02 5 74E-13# 8.33E-13# 2.21E-12# 8 32E-12 _ 3,11E-II ,_ 7,71E-11 2 I4E-]O 4.2OE-IO
9 0E402 1 70E-]2@ 1.86E-12@ 4.O2E-12 _ 1 25E-I] _ 4,08E-ii 9.39E-]I 2 42E-I0 4,59E-10
10E+03 2 59E-12H 2,59E-12# 5,22E-12 * 1 51E-II' 4,64}.]-11 I.O3E-10 2 57E-10 4,78E.._0
1 3E+O3 6 08E-12' 5,22E-12' 9 26E.12 _ 2 30E-11' 6,23E-iI 1,28E-I0 2 97E-I0 5.29E-I0
1 5E403 i 19E-II* 9.26E-12 _ ] 51E-11' 3 34E-]1 8,11E--11 I 56E-I0 3 39E-I0 5,82E-10
i 8E+03 2 08E-11' 1.51E-II _ 2 30E-I] _ 4 64E-11 1,03E-I0 _ 87E-]O 3 83E-I0 6',36E-I0
2 OEr03 3 34E-II 2.30E,-1]* 3 34E-]I 6 23E-II 1,28E-I0 2 21E-]O 4 301;:-10 6,92E-10
4 GEne3 2 97E-I0 1,87E-I0 2 21E-IO 2 97E-I0 4,3OE-I0 5 82E-IO 8,68E-10 1,18E--O9
6.OE+03 8 08E-10 5.29E-I0 5 82E-IO 6 92E-10 8,68E-I0 ] 05E-O9 1,38E-09 1.72E-09
8.OE+03 1 45E-09 9,92E-IO 1 05E-O9 1 18E-09 1,38E-09 1 58E-O9 1,92E-09 2 25E-09
I.OE_O4 2 12E-09 1.51E-09 ] 58E-09 1.72E-09 1,92E-09 2 12E-O9 2,45E-.09 2 77E-09
1.2E.04 2 77E-09 '2.05E-09 2 12E-09 2,25E-09 2045E-09 2 65E-O9 2.96E-.09 3 27E-09
1.4E.04 3 38E-09 2,58E-09 2 65E-O9 2,77E-09 2.96E-09 3 14E-O9 3,44E-O9 3 72E-O9 I
I..6E+O4 3.94E-09 3.08E-09 3. 14E-O9 3,27E-09 3,44E:-09 3.61E-O9 3.89E-09 ,I 15E-.09
].8E_04 4.44E-09 3.56E-09 3,61E-09 3,72E-09 3,89E-09 4,O4E-O9 4.30E-09 4 54E-09
2.0E.04 4,89E-09 3.99E-09 4, O4E-09 4,15E-09 4,30E-09 4,44E-0£] 4.67E-09 4 89E-09
b
Accuracy: * - Posslble Error Greater Than ]0%
# -. Possible Error Greater Than 1100%
C!]ebyshev FittJnq Par_ueters for Rate Coefficients
Bmi n = 3.0E+02 eV, Ema x = 2.0E4:04 eV
He +
Temp,
(eV) AO AI A2 A3 A4 A5 A6
,
IO00, -48,8313 5,83309 -.599670 -.]48905 -.04134£_5 0351803 ,00376359
2000. -47.5113 ' 4.87892 -.205206 -.261188 -,00849826 0291892 -3.733670E-04
4000, -45,9304 3.85019 ,0664286 -,260544 -,O]26575 0232481 -8.778358E-04
7000. -44.4276 2.96296 .192841 -,194959 -,0273665 0145816 .00158914
10000. -43.3804 2.38527 ,238913 -,143127 -,0334989 00836597 ,00280697
15000. -42,1743 1.76616 ,255545 -,0870174 -,0337594 00]96449 ,00271327
20000. -41.3491 1.37656 .243899 --,0536024 -,0298721 -,0012007] .00208341
Equal Temp. -49.5753 7,04496 -1.51108 ,22[849 -,184942 ,]02821 -.0193609
See appendix for Chebyshev fit details.
b- 55
t-I+ + He" " (,t"1+ -t- I--le_+-.- -t- e) c,,: (bl 4-He _+)
J
Mclxwellicltq- Moxwellic,.ll
I)- b (3
lie',2) I't;oehtc:t; loll I,e.z:li-._:,C!()c:',fllc, Lollt'.e_ [or
, t1(__ I I-1_ .-> (11_!,'_ + tl _ .t _,) ()! (I.Io 'I' I H)
13_ull .- M_-Ixv/q_,].L.l.all . R_LI:(_) ('.oal l: Icl (-_lll:_j ((:filll/El }
H
°l'olup, lIe _ I!In(_,'_:c:.iy (c:'V/dinlu)
(eV) 10000, 20000, ,'|0000, 7()000, 10000(), 20{)000, bOO000,
1,0_',-I.00 :1 b6E-lO :1, fl31,I-09 f:,, 991!',-09 1, C)BI!',-OB :1 061!1-0f] B 4 bl_,-C)9 2. b:l l!I-091t
2,01!:.t.00 I 56E-.10 .1,B.31_-09 6,9¢-]I!',-09 :I,OBI!',-OIT I Or,h',-.OB [t 451!;-09 '2 bll_-0911
4, OL!',-tO0 1 571!',-10 IL,B3F,-09 O. 991!3-09 .L, OBI!I-OB 1 061_--0_-I f] 441]',-o.9 2 bJl_',-o9 tl'7 ('.)E-)OO I bIB-:lO .l [:121_',--()9 6 9[]I,.3-09 .I,O[11!',-O[I :I O61!',-O[), L', 441!',-O9 2 bll_',-Ogll
J OL,",+OJ I 5BE-.IO .I. B2E-09 6 9BF,-09 I,OB[!I-OB I 061_I-O[1 LI 441'.;-O9 2 b21!',-O911
20E-I.OJ I 611/;-.i0 'l. ,_13E-09 6 9[.1E.-.O9 I ,OII!',-.OB I O61!',-OB B 44F,-O9 2 b21_l-O91l
4 0 B-I 01 :I 66 E-. I O I 83 I.,;-00 6 97 I'_- C)9 .I. O7 I",- O_I :I O6 I?,-0 B 8 4 4 I!',- 0 9 2 b 2 I!',- O9 II
70B-I.O] I '/4B-II() ii BSF,-O9 6 9II!',-.09 l,O'/l!;-Of] I O6E-Oil 1)),431!',-.O9 2 521!I-O911
]I. OE-)-C)2 I B3E-..IO L B61!I-O9 6 971!;-09 I,OTI!;-OB .I O61!;-OB B,431!',-O9 2 521!',-O911
20E-_O2 2 ]21'-;-.10 'I 92B.-.09 6 97[,:-09 l,O71!;-OP) I O61!',-OB B,421!',.-O9 2 b21!l.,ogll
4013,.i. 0 2 2 73 E - .IO 2 0 2 I]',-09 6 99 I!;--09 I. 0 (i I_',-0 B I O6 I_',-Of_ i_, 4 1 Ii:--O9 _! b _.Ii',.-O9 II
70E-I-02 3 69L,-;-_10 2 .IBE-09 7 O11_;-C)9 I,O61!]-OP, :I O61_-.Of_ f],401!',-O9 2 b31!',-O911
.I OB.i-03 4 69E-I0 2 3_:E-09 "l 03E-09 I,O51!',-OB I O6E-OB B,401_-O9 2o53E-O911
2 O1_,'_+03 B .l ?.F.,-]O 2 '161,':-09 'I ii IF',-09 I, O31!;-.OB .10bl!;-OP, f_, 3'/I_l-O9 2,531_]-.O91140E+O3 :I. 49E-09 71 47E-09 l 241!;-O9 l,O01_-C)_ ), .I O3E-OB Ll'33F,.-O9 2,b41!',-()911
1 01.,I-_O3 2 42E-.O9 4 29F-09 I 4OB-09 9,66E-09 :I OOE.-OB B,29f,:',.-O9 2,5.'51!;-O911
i OE+04 3 24E-09 4 92E-.O9 I !_)2E-()9 9,41E-09 9 111!;-09 B,').41!',-O9 2,b61_',-O911'
20L,.-:.l.04 5 231!1-09 6 291!;-O9 I B LE.-09 li, 921!',-09 9 .LP,I_I-O9 B, Ol I!;.-O9 2,5BI!',-()911
AoC:tll_'_lCyl * -. Po_.l.bl.e E_:For (]teal.e:_r 'l'hd-lll J()_l_II - f'oE)_.Lble Err or Orenl:o): Than I00_
C!_ebysllev F_i.tt.Lnq Pa_:_neL_:rel Ilo[ R_It:e Coe[ .[_.L(.J'.].6,_i_t_,_l
Eillill = I, OE-I.O0 oV, EIII_IX =: 2, OE-I.O4 oV
llo-l
Energy
( eV.Imam) AO AI A;! A 3 A,I A5 A(;
,'tO000, -42 ;9"1EI3 1,71BSr') ,'169214 , ()(il4_)fJ,l i| -, l('ib I'1!) --,06122[I; _. -. 1,2El?.'lOSF',-04
20000. - 39,5695 .556'16[) ,3() _I,I _ [I i, 0(1439!,2 -, (.)I ,_,! 4'1.1 --, 0224B09 -, 009.19993
40000, -37,5112 ,04",I166_: ,(');!99fl66 ,OllI9;_, c) ,()029c/530 -'2, l'llgc)'lF,-O,1 -6,"145161E-(-)4
7000(1, -36,'1(155 -,0761446 -, 04() I 1,',4 -.,010(310 / -, 004 l/C)l ;! , O01426()!i ,001 fl] 3i.16
100000, -36,7766 -,051b1"73 -, 036B2!,; ). -, 0,',01Bb5 -, 00,q04421 -, ()01940!i6 I, 2 144 IOI_:-()rl
200000, -.t?,200.1 - ,Ol'I'l'IgB - ,011(.)62 fi - , ()(._6 ;.t9 q4.1. -, 0() __ r ' ':',. _ ,J_ -, 00193011 - , O01. O(.)fi ?,1
500000, - "| 9, .r)l_I94 ,01 ('.)4;.)22 ,O0514"I I', , ()O I 74,19(.) I, () Jfl c.)_'_5 I'3- O,l -Ii, 41 !i I (121_-O6 -!_,r)20[l!i'IE-O!)
0See, append:[× for C'l_ebyahev f:iI: cle, t:a:l,l e_,
D-b7
QHe+ + H+ -> (l-le_4'+ kl+ --I-e) or (He_+ + H)
i
Beam ::--Maxwellian
•irj 7, -' I i J iiii:ii J '-FI"TT'fTIT-'-'q--f-lqT_'I]-'--F-F-FI]TITF---T"-TTFITr[
- ,- He* Energy
- - (eV/'arnLi)
A -- 10000,
x "- 20000,
V -- 40000,
:> IO-R_," ....-... - _ "" 70000,m [I
o //x @ _ 100000,
__ //c
q) /./ m -- 200000,'_ -4
_ _._.j _ _ - 500ooo,0(_.)@ Recommended
lo'°- /z,_ -- .... Chebyshev Fit
,.
//f
'lO- II ___.L I I I I _Jii l J LJJ_U.j__.L_LLLLI iii l I I l LLLE__.4_LLMJJJ,
io° lo' ld _o_ ]04 ldH+ Temp. (eV)
Ii,.- !._I;I
!011.1_.,d'lLI rlll all{I II_a?'_ I'lc_rhl_'t.lr.ll! {.'I()[111 _(,l!L IolllJ llll*
I.I0_ .I llf__ .-> (II(:_'I II(--,;:° I (_) ((i,i)lle' I II01 -:_,(Ii(:'i llw'° ) Ol (lie I llc,;?'lo) (0110")
i
I o11.[_,at: .LL)I1 l.h__;_ ,l_l odtlc_t; t.Oll
l!°,llt._l;tj_p (I!I(iMtI _(: (:L I()ll l!',lW.tl(.Jy Cit l:ll:l _o¢]L.lc.)11( e.V/_lllltl ) ( I',lll" ) ((::V/a,lti) ( till" )
'l Ol7>t04 6 ]gE-19 ii 9E'tO3 LI 4GE-III] 5 I!',t-O4 .I 77 I!;- l I/ 6 (1Et ()J -I 6 "1ltl- .1I.t
i2 01.,t04 3 1.2E-.113 7 (iF,-tO3 4 94E-187 5E'104 4 /!.)E-]8 lt OE.t03 6 3tJE-Itl30 E-t-O4 6 72 F,.....113 9 0 I#;.t O3 / 84 I!',- .I li3 r,..._1.i04 [I 191G-]I1 10E;I(J4 {I ]4E-.I._I40E.i.04 10ttE- 17 .l ._1.,I.()4_' I 14_m....... ,-._'74 bE.t.04 .i 321.']-]7 20E-tO4 I. 9{IE-1750E.t04 1. 56E-.17 2 !.lF,-I.O4 7, 2 51!',- .1'1
bl!',.I O4 1 It.I E-- 17 J ()f!',-t04 7, . Oh,- I15 8E+O4 I 99E-17 ;I 5F,,I-O4 2, 6 !:)1!;-.[ "7
40EI04 2., [12E-,.174 bill.lO4 2 941!;-17b OF,iO4 300E-I'/b blil.iO4 ;.10_E-1760E-IO4 It O3E-.I/6 lE-t04 2, 9ltE-17
lte [ c-Ji:eliCE; rl I 69, 2,1 1 r 4 57 ii,ACCLIL_!C;;__L o_ - Fact't)l (),f 2 W
;_'' 50 %('illl_
Not:ea I ( .l ) The produc',L.l (;iii oi Ilr:_'_' i:il l l.t(:tfl [ I l llll I.wc) l)lo['Jef:telef:t I ( a ) (_llal;(:lr-_ F#xcll_.lll(.|_"(He_'i l-le t -> lie .t Ih;_2_)/ lh) IcuiJ_,ut;tou (fie' -i lie.' -> i.le _ -i-I.le 2_ -t e), (2) AI:erlorq;I.eEi leB8 l;llal-.i 2, O - ], Ox J05 eV/_illlil t:he c:har, c](_; oxcllt_lllCj_:_ reac:,l;:[c:m clOlil:l.llal:e_l °
(3) The l.ncielent: lte' eliol'cly .iii eV/ttiiltl .l_t plot.l:_id v_.:l, t;he nl;at, lonal: 7 lie _ i:,ni(.jel;,
!7!leb_ysliev FI Lbillq lhTl! <:lille I.(:,i; t.t [Ol. (._I.(j f:J_ _J(vt;Jl;1 (Jll_
' ' :- , _ =-: !7 [li!',-t 04 oV/_UlltlI o11:[7,a L .t,Oll EIII[ n I Ohl'l O4 o V/ i11111_1 [{"111_1X ', _ :,.- 5 9E I.O3 (]V/allll.I, " = f, 71,]404 (_V/_illltlHe 7 _ 1j i.'ocI Elil:111 ' l!"lllti× '
AO A I A2 A3 A4 A5 A6
lou.t zat:.l.oll -80, I 2(){t ;1, Gg'_6R --,I ;14597 , O191l.t710 -., 00494 22 1 , ()O64 li'lfr4 , OO.12 ;:1()131
Ile ?'_ I_Foc] , .-'l'l, !J/6 I 1,, O446h --, 3 2fl2t]13 , O3tl g 2017t --, (}(IItltI1OBR -, O] 109211 , (lO ?,(} 1 23 ?,
!l'lie ilL l:'()l;_l;(:!lJtC-)lll;l;t l:llo ]oil i_',LiL.t.oii iJtf)llil lJ(!(;[, lOli w l.I;ll fill i lilt.i (I{,v I_tl.:lf_ll c_17 (I, 5:lr,,
'file IIKIX.I Illtllll clF_vI al: Jon l i:i I, (_ ,_iL 4, ()1!',t ()li r'V/Tilllll,
Thc-_ .1{I l; l:Ol;ll;tqFJ0_llt, l.I l:ll_ _ lie. ;_t ['i (le.l, (:1 Ill:Ill ItOC'.(; It)li vi I l.II _'lll 17111li(:l('v I _11I()ll ('ii+ (/, _Jt,
'l'ha IIIi:lv, i IIIlllil r.lev 17ii: I fill i It I 0 7't_ i_ll; _, 9Et () t r,V/<ililll,
Se(., appelid:l X [ or C!lli-_lly_lhF, v 1 it:. cl_,l:al I _.l,
D-B9
+ +Pie + He ",(l-le+ _"--..... t- He --t-e)o,:, (t-le + t-le:''') (OHe _+)
Pie'" + He+ -> He+ + t-le_' -Fe (cti)
Cro_o-_.,ectlonvs, IEnergv'lO-,6
-
- ........----& _-&= _7t.leJ'
_ /,./.,r- X = O i
/" //
//
10-,7-- , //
IN -
E -C) -
o.
0 -°.1_,u - Reco m m endecl®
tr) ..... Da tel
(0(/)0k..
U lo ....... Chebyshev Fit10' ,-
-- _.
.-
"10,9 L___I.___L__L_LJ_£_LJ t...... .1...... L___L__L/__LL
'ld ld 10" 'Energy (@V//al-l-iLI)
@
D-- 6 0
OS:l.llgl.e ] ¢3n].zat :[c_11 Rate C,:Jet; f.t.c_.l ent a tlor
ilc.Y_ .t lie _ -> I-le _ -t. I1¢.-'__ + e
l-]ealll - Maxwe .l..L.Lan Rate Coet:.f_iclerlt t_ (C_lU3/t])
Fie
Telllp, He._ ERe t cJy ( oV / allltl )
(eV) 10000, 20000, 30000, 40000, 5oooo, D2000, Dh000,
l. OEl-O0 4 DOE-li* 5 85E-IO 1 62,E-09 2,96E-09 4,85E-09 5,]8F-09 5.62P_-09
2,OEIO0 4 53E-]]* 6 12E-lO ] 62E~O9 3,00E-09 4,85E-O9 5,25E-09 5,89E-09
4,0E400 4 591"`-11' 6 13E-lO .1 62E-O9 3,00E-09 4,85E-09 5,25E,.,O9 5.90E-09
7,0E+OO 4 6DE-.II* 6 13E-IO l 62E-09 3,00E-09 4,85_-O9 5,25111-09 5,90E-09
I.OE.IO] 4 69E-]I* 6 13E-]O it 6211]-09 3,0OE-09 4.85E-09 5,25E-O9 5,90E-.09
2,0E+OI 4 82E-1]* 6 13E-lO ] 62E-09 3,01E-O9 4 85E-09 5,26E-09 5,911",-09
4.0E+OI 500E-I[* 6 14E-lO [ 62E-09 3,0]F,-09 4 851",-09 5,26E-09 5,9OE-09
7.0|_+01 5.22E-II* 6 15E-IO ;[ 62E-09 3 0lE-09 4 85E-09 5,26E-09 5,81E-09
l,OE-f02 5,39E-I1' 6 16E-lO 1 62E-O9 3 02E-09 4 86E-09 5,27E-09 5,671;]-09
2.OE+O2 5.89E-11' 6 21114-10 I 63E-09 3 03E-09 4 871!:-09 5,24E--09 5.2OE-09'
4.()E+02 6 68E-]]* 6,31E-IO 1 64E-09 3 06E-09 4 84E-09 5 O51"`-O9 4.6OE-O9'
7.01",+02 7 70E-II* 6,46E.-I0 i 67E-09 3 09E-O9 4 68E-09 4 "fOE-09* 4.]0E-09'
I.OE+03 8 64E-]]* 6,62_-i0 I 69E-09 3 12E-09 4.49E-.09' 4 4OE-09' 3./9E-09'
2,0E-IO3 1 ]5E-10' 7,]6E-]O ] 76E-O9 3 L81"`-09 3,93E-09' 3 75E-09' 3.24E-09'
4,0E-t03 1 7]E-].O_ 8,25E-10 ] 91111-09 3 lIE-09 ,3,28E-O9' 3 ].OE-09* 2,74E.-C)91t /
"1,O111-t.O3 2 60E-lO* 9,89E-]O 2 04E-09 2 861_--O9' 2,75E-09' 2 62E-09t_ 2.36111-(19tt
1,0E+O4 3 57111-10 ],14E-O9 2.O1E-09' 2 62E-09' 2'44E,-091_ 2 33E-09tt 2,].3E-O9t_
2,0E404 6 89E-10 ].,42E-09' 1,95E-09' 2 09E-O9' 1,88E-09|i 1 81E-091t 1,69E-O9tt
Accuracyl * - Possibl.e I!',rror 'areater Than 10%
tt - Possible Error Greater T]lall 100%
Chebysl{ev l_'ittinq Parameters for Rate Coe£licients
Etlllil = ],OE+O0 eV, EIila x = 2.01_1+04 eV
He-t.
Ellergy
(eV/alllU) AO A 1 A2 A3 A,I A5 A6
IOOOO, -46,|185 1,19034 57948I ,111384._ ,O27947!; -.,O0"I86{151 -,O0[143904
20000 -42 O417 ,"}482OEI 2(1945'I ,IO2371 ,013OO05 -,O04,1937"I -,0168872
3OOO0 --40 3424 , tl,13cJ3 O591(,[IO ,O032"/21_ l .-,O21[,1%4 -,O232[129 -,0142410
40000 -.;19 3"{69 -,0868409 - O9._8,,,,1 -,O'143825 ,,,,' "_" .-.0480228 -,Ot61nq[l -I,5q'/744E-O5
-, - -., -, , 009.. lr. 350000 -3R 1358 3[1[1572 ?,bO3h/ 102423 00799043 0201351 , cS'i "'
._9.,O OO845f12R n?,?120[i / 93302OF,-0452000 -.1[I 6794 --,46289,LI -. ;!11231 -,ORl' ' , , . - ,
55000 -38 6693 -,5B8564 - 267081 -,OIL8306 ,O203911 -,O(_l(,[If,]f.I --,011.L873
See, append:l× [or Cl-_eby_llev f:l.t: clo.!:at.lt:l, _j_
D-6.I
He" -F He+ + He_+-> He --F -k e
Beann Mclxwellian
10-'100 10' ld 103 104 ld
He* Temp. (eV)i
D-62
,@He 2_ Production Rate Coefficients for
He _ + He 4 -> (He + + He 2_ + e) or (He + He 2+)
Bem, - Maxwellian Rate Coefficients (cm3/s)
He +
Temp. He _ Energy (eV/muu)
(eV) I0000. 20000. 30000. 40000. 50000. 60000. 65000.
I.OE+O0 1.30E-09 3.89E-09 5.71E-09 7.84E-09 9 32E-09 i.03E-08 1.06E-08
2.0E400 1.30E-09 3.89E-09 5.99E-09 7.83E.-09 9 32E-09 1,03E-08 1,06E-08
4.0E+O0 1.30E-09 3.89E-09 6.01E-09 7.83E-09 9 32E--09 1.03E-08 1.06E-08
7.0E+O0 ].29E_09 3.88E-09 6.31E'09 7.83E-09 9 3_E-09 1.03E-08 1.06E-08
I.OE+OI 1.29E-09 3.88E-09 6.01E-09 7.84E-09 9 31E-09 1.03E-08 1.06E-08
2.0E+01 1.29E-O9 3.88E-09 6.01E-09 7.84E-09 9 3]E-09 1.03E-08 :].05E-08
4.0E+01 1.29E-09 3.88E-09 6.01E-09 7.84E-09 9.31E-09 1.03E-08 ].02E-08
7.0E+O ! 1.30E-09 3.88E-09 6.01E-09 7.84E-09 9.31E-09 1.03E-08 9.57E-09"
I.OE+02 1.30E-09 3.88E-09 6.01E-09 7.84E-09 9.3]E-09 1.03E-08 9.11E-09'
2.0E+02 1.31E'09 3.88E-09 6.02E-09 7,85E-09 9.30EL09 1.03E-08 8.]9E-09"
4.0E+02 1.33E-09 3.89E-09 6.03E-09 7.85E-09 9.30E-09 9.99E-09 7.34E-09"
7.0E+02 1.36E-09 3.90E-09 6.04E-09 7.86E-09 9.29E-09 9.46E-09 6.76E-09"
I.OE+03 1.39E-09 3.92E-09 6.06E-09 7.87E-09 9.28E-09 9.00E-09' 6.44E-09'
2.0E+03 !.49E-09 3.98E-09 6.10E-09 7.89E-09 9.11E-09 7.96_-09" 5.87E-09'
4.OE+03 1.70E-09 4_IIE=09 6.20E-09 7.87E-09 8.50E-09 6.90E-09" 5.36E-09' I
7.0E+03 1.99E-09 4.31E-09 6.30E-09 7.63E-09 7.66E-09 _ 6.10E-09 _ 4.95E-09#
I.OE+04 2.26E-09 4.50E-09 6.32E-09 7.29E-09, 7.02E-09' 5.60E-09, 4.67E-09@
2.0E+04 3.05E-09 4.89E-09 6.01E-09' 6.26E-09' 5.7]E-09" 4.67E-09# 4.08E'09#
Accuracy: * - Possible Error Greater Than ]0%
' Possible Error Greater Than 100%
Chebyshev Fittinq Parmueters for Rate Coefficients _
Emi n = 1.0E+O0 eV, Ema x = 2.0E+04 eV
He+
Energy
(eV/amu ) AO AI A2 A3 A4 A5 A6
I0000. -40.5559 .324800 .215507 .]01128 .0305437 .00225930 -_0034836
20000 -38.6393 .0830639 .0600817 .03]4309 .0105748 .00101472 -.00206469
30000 -37.8497 .0259326 -.00436636 .00382678 -.0]6]047 -.00327000 -.00929120
40000 -37.3876 -.0574256 -.0510653 -.0409]52 -.0269282 -.0144190 -.005229'79
50000 -37.1678 -.166608 -.]25810 -.0745545 -.03]7364 -.00593417 .00489997
60000 -37.1929 -.348477 -.198373 -.0604564 .009]0326 .0165438 4.816223E-04
65000 -37.4160 -.490762 -.]35825 .0331097 .00708503 -.02359]2 -.00325326
See appendix for Chebyshev fit details @
D'-63
• 'He* + He ->(He* + He_* + e) or (He +He _*)
D-64
Cross Sections for Product:Lng Slow Ions and Electrons for O
Fie + H2 -> z slow ions (o _)
lie 4 142 -> z slow electrons (o-)
(o') (o-)
Energy Cross Sectioll Energy Cross S_ect]oti(ev/anu ) (cm 2 ) eV/_nu ) (cre")
7.6E+02 3.28E-17 I. 2B_ 00 2.30E-20
8.0E+O2 3.45E-17 ]. 3E+00 2.00E-19
]. OE+03 4.21E-17 ].4E+O0 5.36E- 19
2.0B+03 6.90E-17 ]. 5E-lO0 4.86E-19
4.OE+03 i. 02E-16 1.'7E+00 4.08E-]9
6. OB+03 I. 26E-16 2. OE+O0 8,65E- 19
8.0E+O3 i, 46E-16 2.5E+00 2.36E-18
I. 0B+04 I. 63E-16 3.0B+00 3.97E-]8
2,0E+04 2.17E_16 4.0B+O0 6,94E-.]8
4.0E+04 2.54E-.16 5.0B+00 i. 02B-17
6,0E+04 2.50E-16 6.0E+00 i. 35E-]'I
8.0E+04 2.35E- 16 7.0B-1-00 ]. 75E- 171.0E+05 2.18E-16 8.0E+00 2.07E-]7
+ r,2.0E Ou i 43E-16 90E+O0 2.3]E-172.5E+05 i. 17E-16 10E+O] 2.47B-17
4 01{+01 5.5_E-177 OE+0.1 7 1";B-17
10E+O2 8 42E-.174 OB+02 1 46Z--167 0E+02 1 "I'IE-161 0B+03 2 00B-16
4 0B+03 3 06B-16
70E+03 3 53E-16
] OE+O4 3 77E-1640B+O4 4 46E-1670E+O4 4 15B-16
1 0E+05 3 66B-16
2 5F]-1.05 2 06E-16 lPReferences_ o _ - 243, 459, 463
o- - 143 , 460
Accuracy- o _ - 20%
o- - ].0 eVainu to 12 eV/sum] - 20%
12 eV/;_l_u to 3.7x104 eV/an_u -UnkllowD
3.7x]04 eV/sulI[] to 2.5x104 eV/mnu - 20%
Notes: (i) Note the small resonance at 1.4 ev/m,u results from metastable He.
(2)-_-'_e cross section o . is defined as the sum of cross sections for all processes
producing slow singly-charged ions plus twice the cross section for producingdoubly-charged slow ions. Similarly the o-cross sect]oil ]s defined as the cross
section for ionization plus the cross section for electron loss or stripping. 111those reactions where electron capture is important, the o _ cross section is the
sum of the lonization cross sectiozl and the electron capture cross section.
Chebyshev Fittinq Par_mleters for Cross Sections
El,lD 7.6E+02 eV/ainu, BIIlaX = 2.5E+05 eV/a]ll[l
o- Fm] n : ].2E+00 eV/ainu, Ema x = 2.5E+05 eV/ainu
A0 A] A2 A3 A4 A5 A6
°+ -73.4532 .742441 -,556022 -.]26285 -.O371599 .O218408 .000323040
o- -75.1363 3.03724 -].67952 .577]]7 -.601974 .234746 -.168549
The fit represents tile o _ cross section with an rms deviation of 0.3%.
The maximum deviation is 0.4% at 8.0B+04 eV/ainu.
The fit represents the o" cross section wJtli an rms deviation of 52.2%.
The maximum deviation is 286.3% at: 1.2E+O0 eV/_llu.
See appendix for C.hebyshev fit details.
g
' D-65
0He+ + He+ -> E Slow Ions, (c_+)
He+ + He+ -> Z Slow Electrons (cT-)
10-19
: 10o ld I# 103 1(34 18 1#Energy (eV/Qmu)
,,,II,,
D-66
AIonization a|Id It _ Production Cross Sections [or
+
lte 4 I-12 -> tle 4 H2 + e
He + H2 -> _H _
Ionization (H2 _ Production ) l-I_ (Production )
Energy Cross Sect|on Energy Cross Section
(eVainu) (cre2) (eV/ainu) (cre2)
7.4E+O2 1.64E-17 7 4E+02 2.17E-].78.0E4"02 ].75E-17 80E+02 2.19E-17
9.0E+O2 1.93E-17 9 0E402 2.23E-171.0E+03 2.11E-]7 1 OB+03 2.28E-]7i. 5E+O3 2.97E-17 ] 5E-I-03 2.52E-172.0E+03 3.81E-17 2 0E+03 2.78E-173.0E+03 5.24E-]7 3 0E+03 3.32E-174.0E+03 6.55E-]7 40E+03 3.69E-17
5.0E-tO3 7.72E-]7 4 3E+03 3.74E-176. OE+O3 8.7]E-17 50E+03 3.67E-177.0B4-O3 9.55E-]7 60E+03 3.55E-]78.0E+03 1.03E-16 7 OB+e3 3.52E-]79.0E403 1. fOE-16 8. OE+03 3.55E-I 7i. OE.04 ]. 15E- 16 9. OE+03 3.68E-17
]. 21_+04 ]. 24E-16 ]. 0E+04 3.87E-171. IE+04 4.2OE.- 17
References: 459, 461, 462, 463, 464
Accuracy: Unknown , ONotes: (I) The data of Refs. 461, 462, 463, and 464 are approxlmate]y a factorof 2-3 less than that of Ref. 459 for tile procluct.iol] of H _ lolls. The data
presented follows closely the results of Ref. 459.
Chebyshev F:Lttinq Par_uueters [or Cross' Sections
H2 + 'Prod. Elllil]= 7.4E.t02 eV/alllU, l::lllax : 1.2E+04 eV/ainu
H+ Prod. Eml n : 7.4E402 eV/ainu, Enlax : |..lE+04 eV/ainu
AO A| A2 A] A4 A5 A6
H24"Prod. -75.1222 ].03406 -.0748886 -.O222039 -.00237843 -.000779509 .0009545]5H+ Prod, -76.0878 .319638 -.0448970 ..018390] _.r, .0_0,_953 .O349869 -,O00131466
The fit represents the lt2,_ crosr.-_ sect ion . wJ.th an rms cleviat.ton of 0.2%.The maximum deviation Is 0.4% at: ]..bE+OI eV/_ulm.
The, f,i.t represents t;he t-I_ cross sect] on wit:li an rms dev.i, at..ion of 1.0%.The lllaxilntllll deviation is .1.8% at: 6,0l!]-t 03 eV/allltl.
See appendix _or Cl_eb_,shev [.it det:ai. Js.
0iI
F\CN
E0
oo 10- Recommended
@ _- Data
8U ..... Chebyshev Fit
Z
10 -17 I 1 i 1 J iii] i .... L i i I iii
10= 103 104 10sEnergy(eVJamu)
J
D-68
OElectron and Slow L,_osltlve Ion ProcluctlcJl' Cross SectJ.ons for
He .t. He -> F, si.ew e.lect:rons (u')
He + lie .-> [: slow iQns . (o _)
o' e- (L, ower t_nergy) o- (Hi.gher Energy)
_ne rgy {, F,ne l:gy c_ t_]lle rgy _,
'( eV/al;u ) ( 0m2 ) ( eV/ainu ) (c1112) , ( ev/an|Li ) (Cn_ 2 )
5.0E+03 4.4bE-17 2,7E4.01 2,561,1- 20 3.'1E+04 2,4"1E-16'6 01_+03 5.231_-17 3.0E-t01 1.34E-1:9 4.0E+04 2 50E-16
7 0E+03 5,88E-17 3.5I_;+01 3.31E--.[9 5.0E4"04 2 50E-168 08+03 6,49E.-17 4,0E+01 4.86_;-19 6,0E+04 2 47F,-1690E+03 7.07E-i7 5.0E+01 7,66E-.|9 'l,OE+04 2 43E-.16] OE+04 7.55E-17 6,0E+01 1.06E-]8 8.0E+04 2 38E-16
1 5i_+04 .9,74E-17 7.0E+01 .1,331_-18 9.0E+04 2 33E-.162 0F_+04 1 IOE-16 8.0E+01 ]..61_-18 ].0_]+05 2 251_-16
3 0E+04 1 23E-16 9.0E+OI 1.88E-18 1.5E.I.05 1 91_-164 0E+04 1 28E-16 I.OE+02 2.]6E-18 2.0F,405 1 67E-16
5.0E404 ] 29E-.16 1.5E+02 3.52E-18 2.5E405 I 43E-166.0E-1"04 1 28E-16 2.0E.t.02 4,77E-]87.0E+04 1 26P,-16 2,5E+02 5,89E-18
8.0E+04 1 22E-16 3.0F,+02 6.96E-189.0E+04 1 19E-161.0E.05 1 16E-161.5E+05 9 91E-172.0E+05 8.49E-17
2.5E+05 .7.44E-17
Reference@: 143, 403, 462, 463, 472, 473, 474, 475
_, Unknown
ONotes: (i) The processes to forln slow positive ions ancl electrons arel .(a) He I_He -,_-He _ 4 Fie + e, electron loss; (b) He 4 He -> He _ + He _ + 2e (electron loss
with targe t ionization); (c) l{e + He -> He + Fie' + e, single ionization; (d) He
+ He -> He + Fle2+ + 2e, double ionization; (e) He + He -> He" _. He', electron
capture. (2) Cross Sections for slow positive ion formation (o+) are the slim of
reactions o(b) + o(c) + o(d) I-o(e). (3) For electror|s, (o-) is the sum of o(a)
2o(b) + o(c) + 2o(d). For .higher energies o(e) is very small and thus o_ .|.s
approximately equal to the sum of the .single and double io:_ization cross sectior|s.
(4) No attempt has been made to ir|ter49o]ate between the high-erlergy o- and :lie
low-energy data (E < 300 eV/mnu).
C/heby shev Fittinq Parameters for Cross Sections
.
o El]iin = 5.0E+03 eV/_u]|u, Ems x = 2.5E+05 eV/aJ_lu
o" (lower E) Eml n = 2.7E+01 eV/a/_u, El]lax = 3.0E+02 ev/an_u
o- (Higher E) Elllirl = 3.7E+04 eV/alllU, El,_ax = 2.5E+05 eV/6ullu
AO Al A2 A.] A4 A5 A6
(7* -74.0092 .259096 -.395285 -.00216683 .00569771 -.00263905 .00150963
O- (lower E) -82.5433 2.19805 -.641453 .385156 , -,256300 .170524 -.]06115
o- (Higher E) -72.2261 -.269539 -.0908126 -.000390444 -.000723589 ,-,0C)319421 - .O0598024
The fit represents the o _ cross section with' an rind deviation of 0.4%.
The maxJl]lum .deviatlon is 0.9% at 1.01_+04 eV/ainu.
The fit represents t;he_ o" (lower E) cross sectiol] with an rms deviation of 6.3%.
The maximum deviation Is I0.0% at 4.0E+O] eV/_uuu.
The fit represents the o- (Higher E) cross section wJ.tll an rlns deviation of 0.1%.
The maximum devJ.ation is 0.2% at 8.OE+O4 eV/mnu.
See appendix for Chebyshev fit der;ells.
O
t)-69
iiHe + He -> ZSIow Electrons (o*)
I--le+ He -> ZSIow ions (c_+ )
Cross Sect.ionvs. Energy10-'5 ,__
®
D- 7 0
Stllg.le anti l)ouble lcJn].zaL l.cH1 Czo_ls Se(_'L::1ovls rc:_r' O
lie + He -> He -t_ lie _ .t. eHe + He -> He -t. I-le ;__ .t. 2e
Sttlc, lJ.e Ionization I)oub] e Ionlzat:l.c_n
[_neirgy Cl:osa Soots.Loll line rgy Croaa Seetiou( eV/alllU ) (01112) ( eV/alll[I ! ( tILL2 )
,,
1,21_.t.O4 8.26_-.L7 l, 3L'_+04 9 93I_',-19. 1.51,]+O4 1,03E-16 ' .[. b[_-t-04 1 4Ot!;-.t8
2.0t_+O4 i, 32_:-].6 2. OL,;404 2 14_:-'.1.82,5E-I.04 1,581,]-16 2,5E-I04 2 69E-183,0E-I.04 1,80P.,-16 3,0E+04 3 ]5h2-183.5E.t.o4 ].99E-16 3,5I_-t.04 3 59E-184.0E-t"04 2.13E-]6 4,0E+04 4 03E,-184.5F,+O4 2,25[']-'.16 4,5E-t-04 4 441_-18
Referel]ces I 462, 463
AccUracy I UHkx]owl]
Notes I None
_si_ev Fitt JJ3q Parameters for Cross Sect,ion s
Single Ion, El,in = 1,2E-t04 eV/aJ,]u, _2111_,.×==_ 4.51_4-O4 eV/anlu IDouble Io1_, Emj.I_ := 1.3E+04 eV/ainu, _'luax 4,5E4O4 eV/a|Hu
AO 'AI A2 A3 A4 A5 A6
Single Ion. -72,9678 ,503766 -,0453017 -,00416573 -.00286603 ,00135469 .000526378Double Ion.-81.].695 703077 -.]06]05 .0433845 -,0115100 .00236396 -.00233450
The fit represents the Single Ton. cross section w:Lth an I:ms cleviation of 0,]%.The maximum deviation, is O. 2% at 3. OE+04 eV/_.tlllU.
The fit represents the Double Ion. cross set:tj.on with an rms devJat.ton o[_ 0.1%,The maximum deviation is 0,]% at 3,0E4-04 eV/ainu.
See appendix for Chebyshev fJ.t details.
J
O
1>-'1,I
He + He -> He -t- He+ + eHe + He -:> He + He_+ + 2e
Cross ec:tlon vs, F-nergy-154 z"_
/u 1-- ..... -7 , _..... ,--.,----,--_
a,- _(He')
_...- 1_ _""""_ x = a(He _. )/u _4
B""
I'N
Et)
c-0
°47S _r,-17 Recommendedu iu -
@ - -Data(./3 -
t'_
- Chebyshev FitU _ 1_f__
/
10-18_ x/
10- 19 ...... I t I 1 1__ ,-.£_____.L_____
104 105Energy (eV/a rnu)
D-72 '
iiIolljZat: [Oll C1.'al_tkl See;tic, Ill1 [itri.'
1.le_ 4 t-I -> I-le _ + i1_ t e
_llO rc]y Veloc;[ty (?r oFJ[:l S,_c t: .t.c_11(eV/alml) (c'l.l_ ) (c:m2')
6 3F_.i.03 .I, 101!:.i.08 J., 2fJlll-].7"10 E+ 03 ], 16 _l.i.08 .[, 4 7 I_.-1 "lB O_l.t.03 1,24l,.Ii.0B 1,75l_-,1'1 '90E.I.03 1, ;t 21!:.t0B 2,07t]l- i 7]. OE-i.04 I, 39P].I.OB P,, 4 51_-.I 71 51_.t.O4 1,701_;.t-OB 4 8OI!l-;l'l20B.l.04 1,961_.I.0B B 071_,-,;17
.30L_,.t.04 2,4.1,I_.I.08 I 46L",-164 01_].I.04 2,TBl_-l.0B ;I 9BPJ-1650L_.I.04 3 I.LE-i.0B 2 .1.61l,-.L660L_].i,04 3,401_-I, OB 2 .I.BI_-.I.670E.I-04 3 6BI_-I.0B 2 101!I-16B OE-i.04 3 931.']-I.0B 2 O01_-;L69,0 I_;+04 4 17 [_',-t.08 ;1 911_- ;I 6], OE-l.05 4. 39E+0B ]. 78E-,11.61,5E-I05 5 3BE-i.08 ;[ 36_-162,O1_-iO5 6 2].E-t.08 i 101_-]63,0E.I.05 7 61F,.I.OB {I 04[_,-]74, OE-t 0 5 8 'l B I_-t0 B 6 4 ] ld;_ ] 75. Ol_l'i05 9 B2F.,I.I.OB 5 361_-] 76. OB-fOb :10Bl_+C)9 4 D6ll:-l'/7,0P]+05 I. 16BI-09 4 04F,-.[7 ,8 01!;+05 I 24FH,09 3 6].I_-J. 79 0!3.1.05 I 321']-I09 3 261!I-;17
] OE._06 I 39E-I09 2 94E--1720E-I-06 .[ 961_-l-09 ] 591_-J730.E+06 2 401.q-I.09 1,09[_-].740E-I.06 2 771_.I,09 8,33E-].85. OE+06 3 09i!',-I,09 6. 741_-186. 017,+06 3 391_+09 5,76_;-187.0 I_'o+06 3 6 5 I_+ 09 4.97 F,- 11.88.OE-t-O6 3 901_I.09 4,39P.:-]8
r. ¢'Referencesl 564, j6,_, 566
Un know n
Note_l.._..._!_(i) As far as we know if()ptll._IJ..,_hede×perimenta], data exist, The dataplotted are l:lleoi:etical i:estllts, (2) For elleZ'gies less t;hall 105 eV/alilU tile data
of Ref, !$66 has been plottecl. '/'lieclasslc.'a.l Mol]t'.e Carlo caJc:ulat:lol]s have beenquJ.te 'accurate ii] pr.edtcttn£1 stllli].ar col.l.:l.slollal processes wllere ,.experJ.lllellta.l.data is avai.lable for COlllpflrlsoll, (3) For ellercj.ies cii:eater thai] 10 _ eVlallltl data
of Ref. 565 is plotted, These ca].culat;ions ai;'e BO[l l apl)[oxtlllat:tons wh.tch kfllotlldbe good at t;hese high energies, At lower energ:[es t;l'ie (.'.lross sect:Ions a l:O lilt,lE;lihigher than those gtvell ill Re Jr, 566.
_sllev t_'.:l.l;tJ.iiq Parallleteru [oi. C]:oss SecLlon_l
t!]111;i.i1:: 6. ]F,+O] eV/alml, li;ilia x =-" 17.0_',i-O6 eV/flllltl
A0 A 1 A 2 A ;l A 4 A 5 A 6
-'16, :18()8 -,896422 -1,400:16 ,494199 -, 0.1 ]'la03 -. :135.[:13 , .I.]O603
The t7:1.t: reprei]c.-,i]t:_.l l:lle al;)()ve cl;('_f:iN £iect: t [:iii w:t Lli _ill I111[I ch:,v:l ai:.i()ll (_[ ] • 2%.
The lila:_tlllt.llll (JE!vJ.atJ(Jll |.N 6,7% at. .1., 51_',-t-O4 f:_V/_;llllll, _i_
See apperldix ["or C;llebyshev [.ii: ct(-,.Lails,
b-"13
' I--le" -t- H ->,He + + H+ + e
C.rossSection vs. Ener-gy-15
lC) =_r-- _-T-_ _-rrrj -r--r-Tr-rTTT1--'--r--T'T_Tnl - _ r--r-rTr_
x ", \ "k '
"I0-IG__ X 'Pl E
0 -
0 "
U -rb
, l,/')lnir) - "'x,Recon-lmended
U 1(./-17.... -.-- Data
'_ Chebyshev Fit,,..4
10-1o i I I_L.IIIII _1 _LLLIUII .L_J _.J_t_.ll,. l 1 [_LL_U
•lo_ I¢ io_ loo ldEnergy (eV/ar-nu)
D- 7 4
I on.I. zat t Ol/ Rate Coc_[ .l .I c!].ollt _i I"c._[ O
I.I 4 lie ° -.". tl _ .r l-le _ -i. c_
I:lnalll -. Maxno.l ] .I/:.lll R,:ll:f.-_ C'l3e.l [ tc].fi_llLiJ (cml3/S)
He '
Telllp, H l_Jll(_i:'q.y (eV/alllU)( eV ) 10000, 20000, 40000, 70()0(). .LO00OC), 2()0000, 500OO00
, , i i i_ I.[ OB-t'O0 3 41B-09 ] 58i_-08 5 491!]-O8 7 721.,-08 7 82L,I-O8 6.,B3_.-08 5 2,61_-08• i e i_2,0B't'O0 3,4.Ll!l-09 .L 58B-08 5 49B-08 7 7l.I!]-08 7 821'.I-08 6 El]Ill-08 5 2,6L-08
i o _ Q P l4 OB't'O0 3 4.1.F.-09 ./ 58E-08 5 48B-08 'l '1,11_-08 7 82I_-08 6 83&-08 5 26,13-087.0B-t'O0 3.42B-09 ].5BE-OB 5 48F,-OB "1.1]I_-08 7 [t21,7,-00 6 83[,3-08 5.261_-0B;l.OF,-i.O] ].43B-09 1.581_,3-08 5 471!1-08 7.711!;-08 7 82l_-0{I 6 B.]B-O8 5,26B-082.01_3+01 3.45V,-09 ]. 581_,-08 5 46U]-,08 7. "1.1['.]-08 "/ B21i;-08 6 831_-08 5,261'.I-08
4,OE-t'O] 3,49117-09 1 59F,-08 5 45E-08 7,11E-O8 "l 821!1-08 6 83E-O8 f$,26F,-08• ,-17.0B.t.OJ. 3.55U]-09 J 60F,-08 5 431'3'-08 "1.70U]-08 7 82F,-08 6 8..]l,J-08 5,26I_-08
].OE]'t'02 3,61U'-09 .k 6.1E-C)8 5 43I!:-()8 7,701)I-08 7 82E-OB 6 83U:-08 5.26F,-082 OB+02 3.81E-09 .I, 64U]-08 5 41E-08 7,691!:-08 "l 81U:-08 6 83U]-08 5.26U.l-084 OB-t02 4,20I_,-09 1 72B-.08 5 40F,-08 "/,67UI-08 7 8]1_-08 6 82B-08 5,26l_]-08
e , " |17 0l_'I02 4,84lf)-09 ] 83L_,-08 [, 39_1-08 7 65FJ-08 7 "1917,-0[1 6 [121g-08 5,251,,-08' f- ['11 OB+03 5,52F.-0.:] 1 93B-08 39U]--08 7 621_-08 7 '171!;-08 6 82U;-08 5,25l_-08
20E-t.03 7,93U:-09 2 25t/I-08 5 41.F,-O(I 7 521!J-08 7 /2F]-08 6 811_]-08 5,251_]-084 OB.t-03 1,29l_;-08 2 16E-08 5 461_1-08 7 341.3-08 'l 62E-08 6 8017,-08 5,24I."]-08
70B-t.03 .l.97B-.08 3 341_-08 5,551_-08 "1 .I.4l_-08 'l 48U]-08 6 "/8U',-08 5. 231!1-08] OB-t,04 2.56F,-08 3.78F,-08 5.631_.-08 6 99F,-08 7 35_-08 6 1..d.,-08 5 23I_-082 OB I04 3.99R-08 4.76B-08 5. 8617]_,-08 6 73F,-08 7 O31{:-O8 6 661;]-O8 J'_.211_-O8
Chebyl:lh_ev l_'±ttincl Parallletel:s £or Rate Coef£ic:ielits
OEIII.I I] = ii., OUI-tO0 ' eV, l_llia x = 2,01!14 04 eV,
F1
Eilez'gy(sV/al,U) AO AI A2 AI A4 A5 A6
iOOO0, -37,625g 1,123OO ,601815 ,16437l -,O334027 -.,0580936 -,0243672
20000, -35,3341 ,489409 ,271922 ,O807229 -,00015166 -,0204835 -,OO815012
40000, -33,4270 ,0164455 ,02281[57 ,0149114 ,00585597 ,O0147262 -3,367767E-O6
70000, -32.8194 -,O548059 -,O346997 -,O154334 -,OO311520] ,0013"1249 ,0018555_
100000, -32.7709 -.03775"10 -.0264510 .-.014278,1 -, 00_ 15,.,,6 -.00155]12 -3.572900[",-05
200000, -33,0075 -,00828099 -,00567988 -,0034993[ -,00Z01522 -,, 00104778 -4,638534E-.04500000. -33.5256 -.OO412902 -.00205167 -6.18"1466E-0,I -2.150041E-O4 -'I.937"195F,-05-I.271717F'-O4
See appendix for Chebyshev .[:l.t deta.[ls.
b- 7b
i
I-t + He+ .-> He + -t- H + + e
Beom- Maxw@llion
I09_0 "' I '"1 I'111111 ..... j I ii:ilil I " I- i 17 I'III[-'---I--T-T_T'ITTT---_'T-T-I'7TTTT
LI Energy
El,0 _ - _ (eV/o rn u)
A -- lO000,,
7,0 _ X -- 20000.
v -- 4.0000,/--...,
.? 6,0 - _ -7oooo,I'g
E , L...._........u i _ • -- 100000,+., 5,0c.0 m -- 200000,
0 c..)
[] --500000,_) 4.,0 -0
L)Recornmended
o 3.0 - _ ----Data
...... Chebyshev Fit2,o - .ii , -
1,0 i/ -
0,0 __L. 1 1 illfll ..... [ I 1 lil!!l _1 11 iLllll __1 I J LIIIIL.__.J__.L.LLLLLL
_o° ld io_ lcr io_ lo_He + Temp, (eV)
/
, D-76
Cross Sections for the Production of Slow Positive Ions and QElectrOns for He + Passing ThrOugh H 2
He+ + H2 -> Z Slow Ions o+-> E Electrons o"
Slow Ions o . Electrons o
Energy Cross Section Ehergy Cross section
(ev/ainu ) (cm 2 ) (ev /allu) (cm 2 ),
7.5E+02 i. 28E-16 2.5E+03 4.19E-178. OE+02 1.24E-16 3. OE+03 4.59E-17
I. OE+03 i. 15E-16 4. OE+03 5.36E-171.3_.+03 1.lIE-16 7 0E4_03 7.38E-171.5E+03 i. 14E-16 i. OE+04 9.89E-172. OE+03 1.34E-16 1.5E+04 i. 52E-164. OE+03 2.66E- 16 2. OE+04 2.01E- 167. OE+03 3.72E-16 4. OE+04 3.30E-16i. OE+04 4.20E-16 6.0E+04 3.61E-16I. 5E+04 4.65E-16 7.0E+04 3.63E-162. OE+04 4.92E-16 I. OE+05 3.36E-16
3. OE+04 5.08E- 16 1.5E+05 2.84E-164.0E+04 5.03E-16 2. OE+05 2.46E- 167.0E+04 4.11E-16 4.0E+05 ] 67E-16i. OE+05 3.4 IE- 16 5. OE+05 1.46E-16I. 5E+05 2.70E-162. OE+05 2.29E-16
'_ 4. OE+05 i. 46E-16% 5. OE+05 ] •24E-16
References: 96, 104, 105, 353, 355, 364, 462, 463, 478, 479, 480, 481
Accuracy: 50%
Notes: (I) The reactions that produce slow ions and electrons as reaction
p'roducts ares (a) He + + H2 -> He* + H2 + + e, single ionization; (b) He + +
H2 -> He + H2+_, single capture; (c) He* + H2 -> He +.+ H. 4 H + e,
dissociative ionization; (d) He* + H2 -> He+ + H_ + Ht + 2e, double
ionization; (e) He* 4 H 2 -> He + H . + H, dissociative electron capture; (f)
He + + H 2 -> He + H. + H* + e, electron capture with ionization, o . is equal
tO the sum o(a) + o(b) + o(c)41 2o(d) + o(e) + 2o(f). o- is equal to o(a) +
o(c) + 2o(d) + o(f). (2) For energies less than 105 eV/mm] the electron4
capture cross sections to [olqll H 2 dominate the o . cross sections. (3) the
0- cross sections of Ref. 355 are not plotted belciw 2.5 x 103 eV/_im due
to the small energy dependence of the cross sections.
Chebyshev Fittinq Par_m_eters for Cross Sections
Slow Ions o . = = 50E+05 eV/ruralEmi n 7.5E+O 2 eV/6mm, Ema x .
Electrons o- Emi n = 2.5E+03 eV/_mlu, Ema x = 5.0E+05 eV/_l_u
tO A1 A2 A3 A4 A5 A6
= Slow Ions o+ -72.16_5 .175055 -.713665 -.133412 .172753 -'_619895 .0345550
Electrons c- -73.0711 .770468r --.649678 --.176586 .134550 .03004]0 --.0402778
The fit represents the o* cross Section with an rms deviation of 3.2%.
The maximum deviation is 5.5% a£: 2.0E+03 eV/fume.<
The fit represents the o- cross section with an rms deviation of 0.7%.
The maximum deviation is 1.6% at 'i.0E+04 eV/6mm.
See appendix for Chebyshev fit details.I"
' ' D-77
0He + -4-H -> Eglow Ions (ct+)He+ :F H_ -> EElectrons @',_
_1 , ,, ,,
L
Cross Section vs. Ener9y-15 ,10 '" - , i 1 i IIIII I "1 I I I I111 I I I I i 1 II1_11 l I''1'I 111'1
&----U
X- o't"
IN
E(..)
c-O
Recommended
(u - _ Data(J') _
0303
8 -(.2 _ Chebyshev Fit
10 -17 i t J J lilil I .I i i 11111 i , i i JiJl|i' i f i i lfii
10= 103 10' 105 106Energy (eV/Qm u)
D-78
Cross Sections for the Formation of H2 +, H., and O
for Double Ionization for He + in Hz
Lie. + H 2 ->> HH%++ Hz+ +- _ Hz + e [o(H2+)]
He+ + H2-> z H. lo(H+)]
He _ + H 2 -> He* + H+ + H+ + 2e (Double Ionization)
Hz . Production H + Production Double Ionization
Energy Cross( S_ctlon Energy Cross Section Energy Cross _ection(eV/_,u ) cm _) (eV/_,lu ) (cm 2) (eV/allU ) (cm _ )
7.3E+02 3.08E-17 7.4E+02 9.39E-17 2.5E+04 4.77E-188.0E+02 3.23E-17 8.0E+02 8.99E-17 3. OE+04 4.53B-18
I. 0E+03 3.55E-17 9.0E+02 8.45E-17 4.0E+04 3.68E-18I. 5E+03 4.45E-17 I.OE+03 8. OOE-17 5. OE+04 2.86E-182.0E+03 5.45E-17 I. 5E+03 6.92E-17 6. OE+04 2.31E-184.0E+03 i. 04E-16 2.0E+03 6.71E-17 7. OE+04 I. 92E-187.0E+03 i. 84E-16 2.5E+03 6.65E-17 8. OE+04 i. 62E-18
I. 0E+04 2.83E-16 3. OE+03 6.70E-17 9. OE+04 i. 40E-18i. 5E+04 3.96E-16 4.0E+03 6.93E-17 I. OE+05 I. 22E-182.0E+04 4.21E-16 5.0E+03 7.50E-17 i. 5E+05 6.79E-19
4.0E+04 3.93E,16 6.0E+03 8,29E-17 2.0E+05 4.23E-197.0E+04 3.37E-16 7.OE+03 9.05E-17 3. OE+05 2,26E-19i. 0E+05 2.83E-16 8.0E+03 i. 02E-16 4.0E+05 i. 42E-19I. 5E+05 2.22E-16 8.6E+03 I. 05E-16 5. OE+05 i. OOE-192.0E+05 1.86E-16 9.0E+03 I. 04Z-16 6. OE+05 7.3 IE-204.0E+05 i. 25E-16 i. OE+04 9.64E-17 7. OE+05 5.83E-207.0E+05 9.17E-17 i. 2E404 8.49E-17 8. OE+05 4.73E-208.0E+05 8.51E-17 9.0E+05 4.09E-20
References: 360, 365, 462, 463, 481, 482
Acc__.uracyz' o(H_+) _ 20%a (H* ) Unknown
b
o(DoUble Ion. ) - 20%
Notes_ (i) H2 + is formed from ionization of H 2 by He + and from electron capture
collisions. (2) H + is formed from dissociative ionization, He + + H2 -> He + + H+
% H + e; from double ionization, He + + H2 -> He + + H + + H . + 2e; and from
transfer ionization, He + + H 2 -> He + H + + H + + e.
Chebyshev Fittinq Par_lle_ers for Cross Sections
H2 + Prod. Enlin = 7.3E+02 eV/6UllU, Ema x = 8.0E+05 eV/6mlU
H + Prod. Eml n = 7.4E+02 eV/_llu, E,uax = I. 2E+04 eV/_mu
Double Ion. Eml n = 2.5E+04 eV/_nu, Ema x = 9.0E+05 eV/6uuu
AO Al A2 A3 A4 A5 A6
H2+ Prod. -73.3806 .601066 -1.00967 -.0679372 .247157 -.0416476 -.0640838
H+ Prod. -74.0876 .0639707 .162049 -.0778454 -.0615354 -.0437939 -.0172413Doubls Ion. -84 0918 -2.48636 -.206129 .0854195 -.00909082 .0148658 -.00608471
The fit represents the H2 + Prod. cross section with an rms deviation of 3.7%.The nlaximum deviation is 9.0% at 4.0E+04 eV/6mlU.
The fit represents the H + Prod. cross section with an rms deviation of 1.8%.The maximum deviation is 5.7% at 1.0E+04 eV/mllU.
i,
The fit represents the Double Ion. cross section with an rms deviation of 1.1%.The maximum deviation is 2.5% at 2.0E+05 eV/_l_u.
See appendix for Chebvshev fit details.
D- /9
• ,He + + H_ -> a(H_ .)
,, He*+ H_ -> a(H+)He* + H_-> He* + 2H* + 2e
Cross Section vs. Energy- 15,lP",.
|U -----'_"T'_T-"I-q--TT'T'I1-- ---I I t'l IIlll I'--'T" i i llill i I I-T-I-I-I-C
/ "-..
' t -:. ";''- '*_'/__......_ /""3< "'_ - A-O'(H')×"- o(H+)] q--He* + 2H. + 2e
Ol
E _7o 10- -,,_./
C::0 - '_.,
_ .,.,,
- \ Recommended
© "\ _ DataOf) - \\Or) \
0o IO-_E_oL-
U ! ' Chebyshev Fit
10-_9_.
J
10-2<___u J ,_J,J_J , , ,,L,,Jl j _ J,,,,,i J , ,,ELL
102 103 10'* 10s 10eEnergy (eV/amu)
D-80
Cross Sect|one for ProdtlctJon of 81ow Positive Charges (_+)and Blow Eiect_ol_s (0") _or He+ Pa_eing Through }le.
He + + He -> o+, _"
He + + He (o +) He + + He (,o')
Znergy Cross S_ction Znergy Cross Section( eV/ainu ) (cre') ( eV/ainu ) (cm 2 ) ,
2.5E+O3 6.13E,16 2.51_+03 1.40E-174. OE+03 5 o83B-16 4. OE+03 2.15E-, 177,0Z+03 5.05E-16 7.0E+03 3.37E-171,0E:+04 4,49Z'16 1,0E+04 4.46E- 172,08+O4 3,49E- 16 2.0E+04 7,56E-174.0E+04 2.68E-16 4. OE+04 1.19E- 167,0B+04 2.12B- 16 7.OZ+04 I.59E- 161. OB+05 1,84g- 16 3,0E+05 1,81E- 16
2. OE+05 1.30E- 16 1. lE+05 1.83E- 164.0B+05 7.58E-17 2.0E+05 I.51E-167.0E+05" 4.72E-17 4.0Z+05 9.77Z,17i,0E+06 3.53i_-17 5.OB+05 8.39E- 172.0E+06 1.94E-172.8E+06 1.45E-17
961 104, 105; 355, 364, 388, 463, 472, 478, 479, 480, 487, 493,497, 498,499, 500, 579
Accuracv_ g > 3-4xlO4eV/amu -. 20%
' g < 3-4xlO4eV/a_lu Unknown
Notesz (1) _. and o" are tile stm! of the cross sections for processes producing slowions and electrons, respectively. (2) The reaction channels contributing to theseprocesses are (a) single electron capture; (b) single and double ionization of thetarget atom; (c) single capture plus ionization of the target; (d) capture into Wthe continuum; (e) electron loss; (f) electron ions plus ionization of the target,For He + + He collisions, proceses (c, d and f) are believed to contribute a factor"
of ten less than the ethel processes especially at low energies. (3) For He+energies less than 105 eV/eJ_u, the low-energy o" data of Refs, 104, 105, 355, 364,463, 480, 487, 498, and 500 are not includecJ in the present co,_)ilation. Thesedata are questionable since the cross settle,ts are only slightly dependent onenergy. (4) For low energies the o+ cross sections are dominated by singleelectron capture collisions,
c_hebyshev _ittln_ Parau,eters for Cross Sections
He_ 4 He (a*) Emln - 2.5E+03 eV/ainu, Ema x = 2.8E+06 eV/ainu
He+ + He (o') Emi n - 2.5E+03 eV/amlu, Ema x = 5.0E+05 eV/mllu
AO Al A2 A3 A4 A5 A6
He + + He (_,_) -73,0794 -1.87553 -,3684D2 -,0292343 .0164797 .0394079 -.00613696
He+ + Fie (o') -74.6255 1.02842 -.609151 -.175413 -.00862801 .0447902 .0224536
The fit represents the He _ + He (o+) cross section with an rms deviation of 1,5%,The maximum deviation is 2,1% at 7.0E+05 eVainu.
The fit represents the He+ + He (0") cross section with an rms deviation of 1.5%.The maximum deviation is 2,5% at 2.0Z+05 eV/allu.
Bee appendix for Chebyshev fit details.
D-81
eHe+ + He -> cr+He+ + He -,> o-
/
7, Cross Section vs. Ener9y" I+15 r]0 T'---F'+T-I--rI-I'iT -'l - w I i I 111 i I "I--T-T-Ff'FI----I'---+T-T-I--I-Fr'f
"_ A .-: U- ,_'_ X O"+
'%\
\
\\,1"+4E x
0 '! "4 _ ,
c-O
'._ 1(o 10- - Recornmended
e @ - ' , ,DotoCO _
rf)© -
U _ Chebyshev Fit
!10-.17 J J J JJ,_,I_ _z.._J.__JJJ,_l i.........L..L.X...i...J.izL___L._+JJ t_J_
lo_ lo+ lo_ _o+ lo'Energy (eV//am u)
D-82
Ionization Rate C_f[ictents for @
r
He _ _ He -> o _
M_elltan - M_wellian Rate C_fttctents (_|3/S)
He4
T_Ip, F.qua] He Temp. (eV)
[eV) Tmap. 5000. 6000. 8000. 10OOO. 12000. 15000. 20000.
1.Og*O3 8.49E-I0# 1.73E-00# 2ol2E.-Oe* 2.78E--08" 3,30g-08* J.7XE-Oa* 4.2OE-O8 • 4.76E-O0"
1.5E_03 3.93E-09# 1,93E-08' 2.30E-08" 2,92E-08' 3.41E-08 _ 3.filE-00" 4.26E-08 _ 4.alE-Oa _
2,0E*03 8,30E-09| 2,12E-08 _ 2.47E.-08 _ 3,06E-08 _ 3,52E-08" 3.Sgg-0fl* 4,33E-08 _ 4.85E-00'
2o5g_03 1,29E-08f 2,30E-08" ' 2,63E-08" 3,18E-08 _ 3,62E-08" 3.97E-08' 4,3qE-08' 4,90E-08'
3,0E_03 I,_3E-08# 2,'4'IE-08" 2,78E-08' 3.30E-08' 3.71E-08' 4.05E..08' 4,45E-0_' 4_q4_-0lI*3,5E*03 ,2,12E.,.08' 2,63E-08' 2,92E-08' 3,41E-08' 3,81E-08" 4,13E-08' 4.51E-00 _ 4.91!1_-08'
4.0E*03 2.47E-08' 1.78E-08' 3.06E-08' 3.52E-08* 3.89g-08" 4.20E-08 _ 4;56E-08 _ 5.02E-O8
4.5E+03 2.78E-00 _ 2.92E-08' 3.18E-08 _ 3.62E-08' 3.97E-00 + 4.26E-08" 4.62E-00' 5.06E-08
5.0E403 3.06E.-08 _ 3.06E-08" 3.30E-08' 3.71E-08' 4.05E-08 _ 4.33E_08 ' 4.67E-08 _ 5.(}9E-08
5.5E_03 3.30E-0_" 3.1BE-Off _ , 3.41E-08' 3.81E-08 _ . 4.13E-08 _ _.39E-08" 4.72E-08_ 5.13E-()0
6.0E_03 3.52E-08' 3.30E-08" 3.52E:-08 _ 3.89E-08 _ 4.20E-08' 4.45E-08 + 4.76E.-00 _ 5.16E--O8
8.0E*03 4o20E-08" 3.71E-08 _ 3.89E-08" 4.20E-08 _ 4.45E-08" 4.67E-08" 4.94E-08 _ 5.29E-08
1.OE*04 4.67E-08 _ 4.05E-08 _ 4.20E-08 ^ 4.45E-08 _ 4.67E-08 _ 4.85E-08" 5.09E-08 5.4_)E-08
1.2E_04 5.02E-0_ 4.33E-08' 4.45E-08" 4.67E-08, 4.85E-08' 5.02E-08 5.23E-Off 5.51E-08
1.4E_04 5.29E-08 4.56E-08' 4.67E-08 _ 4.85E-08' 5.02E-00 5.16E-08 5.35E-08 5.60E-08
1.6E+04 5.51E-08 4.76E-08' 4.85E-08' 5.02E-08 5.16E-08 5.29E-08 5°46E-08 5.6g_-08
1.8E*04 5.69E-00 4.94E-.08' 5.02E-08 5.16E-08 5.29E-08 5.40E-08 5.56E-08 5o77E-0_
2.0E_04 _5,84E-08 '5.0gE-08 5,16E,-08 5.29E-08 5.40E-08 5.51E-08 5.65E-08 5.84E-08
Accuracy: * - Possible Erro,: Greater Tha_) 10%
-- Possible Error Greater Tlla,] I00%
Che__/byshev Fitting Paran_ters for Rate Coefficle_]ts
Emil] = I, 0E+03 eV, Ema x = 2, OE.04 eV
He
Ter_p.
(eV ) AO AI A2 A3 A4 A5 A6
5000. -34.6840 .561425 ,00846562 -.0219365 -2. 039967E-04 .00120158 -I. 325802E-05
6000. , -34.4871 ,460985 ,0203888 -.0170479 -.00123903 8.950819E-04 7.412802E-05
8000. -34.2085 .331032 .0296262 -.0J.01056 -.00187431 4. 167700E-04 1.213301E-04
10000. -34.0188 .252148 ,0310288 -.00582488 -.O0180584 I. 394312E-04 I.072709E-04
12000. -33,8797 ,200089 .0298230 -.00316385 -.00155179 -8. 216817E-06 8.11 5796E-05
15000, -33,7274 •149363 •0266925 -8. 769851E-04 -,00114857 - 1.026825E-04 4.607838E-05
20000. -33,5570 :101222 ,0215477 7,809161E-04 -6. 525756E-04 -I. 278772E-04 1. 216316E~05
Equal Temp. -36,1071 1.93272 -.683257 .177855 -.0338898 .00493571 -5.4992qlE-04
See appendix for Cllebyshev fit details.
D-83
OHe + + Pie -> o.
Moxwellon - Moxwelion0"I
JO65,0 I I I i I I 1
He Temp.
60,.0 " (eV)
A --5000.
55.0x --6000,
v - sooo.50,0
",,, _<--10000.
E _5,oo • --12000,
O _-@ m --15000.'O 40.0q:- /_- []--20000.(i)o __/
U 35,0 /' /q) ,// / Recommendedo ---- Dator'Y
30.0
Chebyshev Fit25.0
Equcll Temp,20,0
15.0 , I I I 1 1 l ,
0.0 2.5 5.0 7.5 10.0 12.5 t5.0 17.5 20.0
He* Temp, (eV) "10 3
O
D-84
IonJ zation Rate toe, f fie tentu for O
lte ! He_ -> o _
Beam - Maxwe.l.tjan Rate Coe[l:l, cJents (cma/s)
He +
Temp. lie Energy ( eV / _J_U )(eV) 10OO0. 20000. 40000. 70000. 100000. 200000. 500000.
1. OE+O0 6.24E-08 6.86E--08 7.45E-08 7.79F,-O8 8.0BE--OR 8.07E 08 6.16t'I-082.0E+O0 6,24E-08 6.86E-OB 7.44E-0B 7.79E-08 8.08E-Oll q. O IE-O8 6. ]6E-084. OE+00 6.24E-08 6.86E-08 7,44E_08 7.79E-O8 8.08E-OB I.0/E--08 6. 16E-08
7.0E+O0 6,24E-08 6.86E-08 7.44E-08 7.79E-08 B.0OE-OP 8.07E-08 6.16E-08I,OE+0I 6.24E-08 6.86E-08 7.44E-08 7.79E-08 8,08E-(_ 8.0"lE-08 6.16E-08
2.OB+Of 6.23E-08 6.86E-08 7.44E-08 7o19E-08 8.08E OB 8.07E-O8 6,16E-084.0E+01 6.23E-,08 6.85E-08 7.44E-08 7.7BE-OB B. 08E-08 B. O/E-08 6. ]6E-0fl7. OE+01 6.23E-0B 6,85E-08 7.44E-08 7.79E-08 8.08E-08 8,06E-08 6.16E-00I, OE+02 6,23E-0B 6. B5E-.08 7,44E-08 7.79E-OO 8.07E-08 R. 06E-08 6. 16E-082, OE+02 6.23E-08 6,85E-08 7.44E-08 7.79E-08 8.07E-O8 8.05E-08 6.16E-084.0E402 6.23E-08 6.85E-08 7.44E-OB 7,79E-08 8.0'lE-08 8.05E- 08 6.16E-087, OE+02 6,23E-DE 6,85E-08 7,44E--08 7,80E-08 8,06E-08 B. 04E_08 6.16E.-08I, 0E+03 6.23E-08 6.86E-08 7.43E-08 7.80E-08 8.O6E--08 8.03E--08 6.16E--082, OE+03 6.23E-0B 6.86E-08 7.43E-0B 7.80E-08 ft.05E-08 B. 01E-08 6, ]GE-0B4,0E+03 6.21E-08 6.87E-08 7.43E-08 7,81E-- 08 8.04E-O8 7.98E-08 6.16E--087,0E+03 6. ]9E-08 6.88E-08 7,43E-OB 7.81E-08 B. 02E-08 7.95E-08 6. ]6E-08I, OE+04 6,19E-08 6.88E-08 7.43E-08 7.81E-OB 8.01E-08 7.93E-08 6. 16E-082. OE+04 6,28E-08 6.90E-08 7.44E-08 I.82E-08 7.99E-O8 7.87E-O8 6,16E-08
ChebyBllev Fittinq Par_netere for Rate Coefficients I
Em_n_ = I. 0E+00 eV, Ema x := 2.0E+04 eV
He
Energy
(eV/amu) AO A1 A2 A3 A4 A5 A6
i0000. _33.1826 -8.447088E-O4 4.3'19986E-04 _OO153621 .O0196721 .O0191297 .O016557g20000. -32.9886 .00246657 .00200537 .00110670 ].142096E-O4 -7.069038E-05 -9.257167E-O540000. -32.8276 -7.087943E-04 1.614074E-04 4.588880E.-O4 3.529485E-O4 1.83671OE-04 9.755263E-O570000, -32.7333 ,00154471 7.127662E-04 1,336512E-04 -9.932082E_.05 -1.253244E-04 -7.595"196E-05I00000. -32.6686 -.00490652 -.00228784 -7.224299E-04 -1.31302.]E-04 -2.878208E-05 1.350276E-05200000. -32.6778 -.O107031 -.00545996 -.00203612 -5.571363E-04 -8.99606]E-05 ].739583E-05500000, -33,2050 -2,649854E-04 -1.908228E-04 -I.196480E-04 -6.719115E-05 _-3.770261E-05 -2.551690E-05
See appendix for Chebyshev fit details.
IIII, i
D- 8 5
i' He + He+ -> cr+
Beom MoxwellionO_
I090,0 '1" i ililll I 1 i ililli I I i I-ill]ll'--'-]--I IITill I I I illTTf
He Energy87.5 -
(eV/om u)
A --10000,85.0 -
x --20000,
82,5 -v --4,0000,
8'0,0 _ --'e - _ -- 70000,
b 77,5 _ e -- 100000,-t---'
_> m --200000.'G 75,o -'-t-"- _ --500000.©
0 72 5URecommended
-'-" Datao 70.0 -
L,.. ....
67.5....... Chebyshev Fit
65.0 -
62._ _-_ ._____ -
60.0 I J I I Jiltl J I l lllllJ .... I, i i i,l_il i_J I I_LILLL,__I I |ililJ
lO° lo' lO_ lo_ lo_ lo"He+ Temp. (eV)
0.-86
I cml zat J c_ll Ratc_,, Coe [ I':Ic:,[c_lil:s I!or
He + 4. llc._-> ¢,"
L,
Ma×w(_.l..l_lan .- Ma×wel.l Iat_ RaL.o (.!o_[[, c:i(::xli;u _ (cm 3/[_s)
H B +
Temp, 'Equal llo Temp, (e_V)
( 8V ) 'l_Blnp, 5000, GO00, 80'o0, 10000, 12000° 15000, 20OO0,
I,OE¢03' 2 40E-II# 3 15F,,-10* .'-.I,55E-I0' ),46E-O9 ° 1,99E-09' 2 5,1E-09 3,39E-09 4,[17E-09
1.5E_O3 1 23E-_0_, 8 33E-IO' :I,O_F,-09' 1,59E-09' 2,1.3E-O9' 2 68E-09 ],54E-O9 5,02E-O9
2,0E+03 2 86E-lOH 9 55E-10' 1 20E-09' l,'/]E-09' 2,27E-09' 2 821!:-0_1 3,68E-09 5,.1"/E-09
2,5E¢03 4 89E-10' I 08E-.09' 1 33F..-09_ 1,86F',-09' 2 40E..09 2 97_-09 3 _3E-09 5,32E-09
3,0E_03 7 15E-10' 1 20E-09 A I ,16E-09" 1,99E-09 ,_ 2 .5,1E-09 3 liE-09 3 98F1-09 5,.'-18E-09
,.,},_ 03. 9 55E-10 '_ 1 33E-09' 1 59E-09 _ 2,,L3E 09 _ 2 6[IF,-09 3 2.5E-09 4 12F,-09 5,03E-094 0E_03 1 20F,-.09 j' 1 46E-09' I 13E-09' _ 2'1E-09' 2 52E-09 3 39E-09 4 27E-09 5,78E-09
4 5E103 I 46E-09" 1 59E-09' 1 86I_-09" 2 ,IOF.'09 2 9"1E-09. 3 54I":-09 . 4 42E-09 5,93E-09
5 eel03 1 7]E-O9 A i "13E-O94, I 99E-09' 2 54E-O9 3 II[;;-.O9 3 68E-09 ,I57E-O9 5,09E-09
5 5E403 1 99E-O9' I 86E-O9' 2 13E-09' 2 69E-09 3 25E-O9 3 831_;-09 4 72E-O9 6,24E-09
60E+03 2 27E-09 _ I 99E-O9' 2 _17E-09' 2 82E-09 3 39E-O9 3 9|%E-09 ,I87E-09 6,4OE-O9
80E_()3 3 39E-O9 .! 54E-09 2 82E-09 3 39E-09 3 991_',-O9 4 5"2E-O9 5 481[,:-O9 7,02E-09
10E_O4 4,57E-09 3 lIE-e9 3 39E-09 3.98E-09 4 57E-09 5 17E-09 6,09E-09 "1,54E-O9
1 2E_O4 5,78E-09 3 69E-O9 3 98E-09 4,57E-09 5 17E-09 5 78E-O9 6,71E-09 8,27E-O9
1 4E¢O4 7,O2_:-O9 4 27E.O9 ,I 59E-09 5,J7E-O9 5 7fiE-e9 6,4OE-09 7.33E-09 8,91E-O9
I 6E¢04 9,27E-O9 4 871:',-O9 5 17E-O9 5,78E-09 6 40E-O9 7,02[,]-09 7.96E-O9 9,54E-O9
'1 8E_()4 9,54E-O9 5 48E-O9 5 79E-09 6,,IOE-09 7 02E-O9 7 64E-O9 8,59E-09 1.92E-O8
2 OE¢O4 I,O8E-08 60qE-O9 6.40E-09 7,O2E.-(,9 7 64E-O9 8.27E-09 9,22E.-09 |,08E-O8
Ac:curacy: * - Posslble l_z-ror Greater That] 10%
II - Possible Er[or Great:el Than 1100% O
Chebysl_ev F.Ittinq ParmIIeters [or Rate CoefficieNts
'
Emit] = ], OEI O3 eV, Elllax = 2, OE+04 eV
Fie
Temp,
(eV) AO Al A2 A3 A4 A5 A6
5000. -40.2457 1.09016 137224 -,00960777 -,qO225681 ,00426467 -3,707387E-05
6000, ~39,9199 955399 144445 -.OO462863 .-.O0797896 I,656917E-04 .I,638382E-05
8000, -39.4021 78204] 145020 ,OO249323 -,O0333214 -2,249516E-04 6.938838E-05
IOOO0. -38.9951 665607 138788 .00682158 --,OO268049 -4.285723E-04 4,558085F-05
12000, -38.6575 580939 130790 ,00942419 -.00211989 -5,139889E-04 ], 332445E-O5
15000, -38,2374 489850 118758 .0114760 -.OO136912 -5,313647E-04 -2. 87635"2F,-05
20000. -37.6842 386897 101410 ,0124848 -5. O96409E-O4 -4,65f_I2OE-O,I -'I,014682E-05
Equal _'emp. -41.6708 2 88394 -,522,]63 ,167306 -,O405614 ,O0499359 -2.402961E-O4
See appendlx for Chebyshev t.i.t cletai]s.
O
i
I).-lt'1
Pie+ + He > o-q
D- 8 8
AIolllzat.] oll Rate Coe£ I.J c:t etlt:s [of
' lie + 110+ _.> o-
Lteam -- Maxwol..ltan Rate Coe[f.tcJent:t_; (ulna/E1)
He
'I'eutp. lie t_lle rgy ( eV/al.tl )(eV) I0000, 20000. 40000. VO000. .l00000. 200000. 4()0000.
1,OF_.t.O0 8.9913-09 3.5].E-09 2,121]',-08 5 88L,]-08 8 73FJ-()B 9,38F,-08 8,59g-082.0E.+O0 .7 461:1-09 9.85t+-09 2,88E.-08 5 91t+:..,08 8 451,.':-08 9.38r.,;-08 8,58E,.084.0F,,-I.O0 6 44E-09 1,401_--()+1 3.24g-08 5 84g-08 8 03E-08 9..181.,2-08 8,58E-f)81.OE+00 6 22_-.09 1,48E-08 3.30B-08 5 84E-()8 7 951,]-08 9.37E-O8 8,581!:-O8l. OE+O1 6 20E-09 1,48I,]-08 3.3()E-08 5 84E-O8 1 941_-08 9 31E-O8 8,58E-O82,0t_t()1 6 20B-09 J,48E-08 3.30E-08 5 84E-O8 / 94E-O8 9 37t3-O8 8,b81_-()840E+O] 6 21B-09 1 48I,.",-08 3 30g-08 5 84g-08 7 94[,,'-08 9 3"1g.-08 8,581_-0117 OB i+01 6 22E--09 1 49E_ 08 3 ]OP]-08 5 84F3-08' 7 941_-08 9 36E-08 8+58F3-08
] OB-102 6 23E-09 l 491_:-08 3 30[,:-08 5 84[!]-0B I 93t_I-08 9 36E-08 8 58E-0820g-l.02 6 26F,-09 t 49L!:-08 3 30L_-08 5 841._-08 7 93g-08 9 35E-08 8 58E-084 OB.lO2 6 33F,-09 1 49g-08 3 311_-08 5 84E-08 7 92E-08 9 34[']-08 8 581_-08'7 0_:+02 6 43E-09 ,l 50E-08 3 31E.08 5 84g-08 7 911!:-08 9 3313..08 8 58E-08i Og103 6 53E-09 ] 51E-08 3 32E-08 5 841!;-08 7 901+3-08 9 32g-08 8 57_-082 O1.']+03 6 87E-,09 I 55E-08 3 35E-08 5 86E-08 "7 87E-08 9 30E-08 8 !YIE-0840E103 7 56F]-09 1 62E_,-08 '] 41E-08 5.891,]-08 1 831!1-08 9 27E-08 8 56g-0870B103 8 57E-09 ] 72F]-08 3 50E,-08 5.94F_-08 7 78g-08 9 22F,-08 8 51g-08
1.0E-I()4 9 57E-09 1 82E-08 3 58E-08 5,991+:-08 7 7415-08 9 20E-O8 8 39E-082.0_]-I04 ] 29F]--08 2 16E;-08 3 87E-08 6.11L,;-08 7 6[iE-08 9 13E-08 l 9.lE-08
s
Chebyshev Flttlllq Parr allle tel_ s for Rate Coe.if Icler|ts i
Eml n = l.Og+O0 eV, l!;max : 2.0El04 eV
He
gnergy
( e%'/ainu ) AO A 1 A 2 A 3 ,t',,1 A 5 A6
10000, -37,3757 , [52585 ,271251 ,0286627 ,0720550 -,00417889 1.885647E-04
20000, -36,2921 ,498746 -,223651 ,296885 -,142577 ,103860 -.0465049
40000, -34,5146 .168467 -,0600577 ,0991481 -.0398571 ,0325305 -,0123581
70000, -33,2915 .0119357 ,0143042 ,00553446 ,00283829 ,00124894 -,00136315
100000. -32,6810 -.0457164 ,0165590 -,0198832 ,00750636 -,00146373 -,00200726
200000, -32,3'292 -.0113032 -,00566531 -.00204888 -5,329708E-04 -7.815125E-05 I, 640098E-05
400000. -32,5635 -.0211742 -.0170066 -,0140215 + ,00943770 -,00589724 -, 002,93363
See appendix lo1: Chebysllev f.tt cletai]s,
D- H9
He + Pie+ -> cT-
BeGin - MGxwellion
'O
,_ 11,0 i-_-_ _-n-ml---r---_-r-rml .... 1 I 1 IIIT1T----F'-I-I-FIlIII -"V li _,,_, He Energy
1O,0 t - (eV/a rnu)A -- 10000,
9,0 -, x -- 20000
"x8,0 - "_'" - . :.-_ "'_ - V -- 4-0000,
,f-,-,.09\ _ -- 70000,
7,0 - ""E(p • -- 100000,
,,_..1"
c 6,0 __ m --200000,
[] -- 400000"-" 50 - '®0
U Recomn'lendedtD 4.0 - , -•+-' _ -- DatalD ..tl-
: 3,0 /'I' -Chebyshev I-it
2,0 _ "
/ Ir
/
o, 0
100 'lO' ld ld 104 "/ldHe+ Ternp. (eV)
@
D-90
Single and Double Iontzat. ioJ_ Cross Se_',l:ions for H,.' in tte I
He" _. tie -> fie + -4-Fie' + e
-> Fle 4 -i He"' + 2e
lie' + He) .t e He ) + He z' .! 2e
Energy CROSS Section Energy Cross Sect_ou( eV/all|u ) ( cIII 2 ) ( eV/allll.! ) ( Clll2 )
].2E+04 4.09E-.16 1 2E+04 2.16E-lA1.5E+04 3.57E-16 1 5E+04 2.87E-18
2.0E+04 3.07E-16 2 OEr04 3.88E-]83.0_04 2.52E-16 30F,+04 5.82E-18
4.0E404 2.119E-[6 40E+04 7.76E-]8
6.0E+04 1.80E--16 60E+04 9.'14E-18
8.0E+04 1.54E-16 80E+04 9.08E-18
1.0E+05 1.36E-16 ] OE+05 "!.69E-18
I. 5E+05 ]. 08E-16 i. 5E+O5 4,95E-]8
2.0E+05 9. ]2E-17 2.0E405 3.32E-]8
3.0E+05 7.02E-.[ 7 3. OE+05 [. 8] E-18
4. OE+05 5.8'5E-] 7 4, OE,.t05 [..19E- 186.0E+05 4.53E-']7 6.0E+05 7.14E-]97.8E+05 3.82E-]7 7.5E+05 5.60E-I 9
References: 388, 462, 463, 494, 495, 496
Acc u r a_cy.i 20 %
Note At lower energies the formation of He' is domi_]ated by slI_gle electron
capture.
Chebyshev Fitt inq Par a,leters for Cross Sections O
He _ + He" 4- e Emi n = ].2E+04 eV/ainu, Ema x = 7.8E+05 eV/ainu
lle' + ]lez_ + 2e _;lllil]= i. 2E+04 eVlamu, Ema × = 7.5E+05 eV/EmlU
AO AI A2 A3 A4 A5 A6
He+ , Ho+_ • e -73. 1564 -1. ].7268 -.0534400 -.00895703 .0130892 -.00303440 .000546481He+ _ He-+ _ 2e -80.9940 -.8097_1 -.972278 .157307 .149794 -.0339390 -.0320888
Tlle fit represents the He* .t He + { e cross section with an rills deviation of 0.2%.
The maximum deviation is 0.3% at I.OE405 eV/smlu.
Tile fit represents the He _ _ ]le2' _ 2e cross sectiof] with a_] rms devJatJor] of 2.0%.
The maximum deviation is 3.3% at 3.0E+04 eV/ainu.
See append.i× for Chebysl]ev fit details.
I)-91
SHe+ + He-> He+ + He+ + e c_(He+)
He + + He -> He + + He_+ + 2e cT(He2+)
CrossSectionvs.Energy10-15 , I I ',' I , , I ), I , , | I 1 I ,--
A = a(He +)
_'_ x = o-(He_+),
1(,i)-1_, .-.._' _
(N
E0
c-O
'_ 10 -17 Recommended(D--Data
V')
-,,,.0 \\
UL \\, ...... Chebyshev Fit
10-' _""",.,,.
x.N
10-_9 , , , , , , ,,1 , ,i ,_ , , ,,,lo" lO_ t#
Energy (eV/o rn u)
' D-92
Single ionization Rate Coe [ficierlts for O
' ' He + I-le* -> tie' ,-t l.le _ -t: .e
Be6ml - Maxwellian Rate Coefficients cm3/S)
He _
Temp. He Energy (eV/muU )(eV) 15000. 20000. 40000. 70000. 100000. 200000. 500000.
1. OE+O0 6.07E-08 6.03E-08 6.08E'08 6, 08E-08 5.97E-08 5.66E-08 4.99E-082.0E+O0 6.08E-08 6.03E--08 6.08E-08 6.08E-08 5.97E-08 5.66E-08 4.99E-084.0E+O0 6.08E-08 6.03E-08 6.08E-08 6.08E-08 5.97E-08 5_66E-08 4.99E-087.0E+O0 6.08E-08 6.03E-08 6.08E-08 6.08E-08 5.97E-08 5.66E-08 4.99E-08
]. 0E+OI 6.08E-08 6.03E-08 6.08E-08 6.08E-08 5.97E-08 5.66E-08 4.99E-082.0E.01 6,08E-08 6.03E-08 6.08E-08 6.08E-08 5.97E-08 5.66E-08 4.99E-084.0E+OI 6.08E-08 6.03E-08 6.08E-08 6.08E-08 5.97E-08 5.66E-08 4.99E-087. OE+O]. 6.08E-08 6.03E-08 6.08E-08 6.08E-08 5.97E-08 5,66E-08, 4.99E-081.0E+02 6.08E-O8 6.04E-08 6.08E-08 6.08E-08 5.97E-08 5.66E-08 4.99E-08
2.0E402 6.06E-08 6.04E-08 6.08E-0'8 6.08E-08 5.97E-08 5.66E-08 4.99E-084.0E+02 5.91E-08 6.04E-08 6.09E-08 6.08E-08 5.97E-08 5.66E-08 4.99E-087,0E+02 5.65E-08 6.04E-08 6.09E-08 6.08E-08 5.97E-08 5.66E-08 4.99E-08i. 0E+03 5.45E-08' 6.04E-08 6.08E-08 6 08E-08 5.97E-08 5.66E-08 4.99E-082.0E+03 5.05E-08' 5.96E-08 6.09E-08 6 08E-08 5.97E-08 5.65E-O8 4.99E-08
4.0E+03 4.73E-08' 5.73E-08 6.09E-08 6 07E.:08 5; 97E-08 5.65E-08 4.99E-087. OE+O3 4.59E-08' 5.49E-08 6. O8E-08 6 07E--08 5.96E-08 5.64E-08 4.99E-08
I.OE+O4 4.55E-08' 5.36E-08' 6.07E-08 6 06E-08 5.96E-08 5.64E-08 4.99E-082.0E+04 4.61E-08' 5.18E-08' 5.98E-08 6 03E-08 5.95E-08 5.63E-08 4.99E-08
Accuracy_ * - Possible Error Greater Than 10%# - Possible Error Greater Than 100%
Chebyshev Fitti_lq Parmueters for Rate Coefficients
Emi n : I.OE+O0 eV, Ema x = 2.0E+04 eV
He
Energy(eV/amu) AO Al A2 A3 A4 A5 A6
15000. -33,4287 -,158108 -.0677688 .0633240 .0303214 .0168471 -.00235247
20000. -33.3167 -,0613195 -,0440891 -.0209720 -.00324850 .0049291'7 .00599209
40000. -33.2337 -.00382566 -.00347023 -.00301869 -.00227878 -.O0145508 -8.331803E-04
70000, -33.2330 -.00284092 -.00208988 -.00125435 -6.089006E-04 -2.360207E-04 -6.07084OE-05
I00000, -33,2684 -.00150867 -9,658744E-04 -5,35351E-04 -2.92897E-04 -1.57790E-04 -6.49004E-05
200000. -33.3763 -.0025'/819 -.00]51167 -4.93080E-04 -2.11497E-04 5.23848E,-05 -7.73477E-06
500000. -33.6268 -2.54059E-04 -1.83372E-04 -I.19077E-04 -7,06237E-05 -4.19!IOE-05 -3.05576E-05
See appendix for Chebyshev fit details
[)-93
+ + +He -t- He > I-le --FHe + e
Beam ....Mcqxwellian
I0,-- 67.5 -- 1 1 illlll I I -T-FTI I I I I I I I.IIIII I I' I llJlll I I I I'11111
He Energy
65.0 - _ (eV/a m u)
a --15000.
62.5 - _ x -- 20000.
•.--- .---- v --40000.-_.-- -- " _ iii_. _ -- ± - - " , --_ --
, < ,\ ' ,(\ --------.@ _ -- 70000.E \ \ '° % '\ • -,ooooo.
+-, 57.5c"
@ _ m --200000.
o 55,0 _ []--500000.o \@ Recommended
o 52.5 - _ _ Data
50.0 ........ ____ _ - .... Cnebyshev Fit
47.5
4.5.0 l I IJJJJJl J l ilJllll ] J JJllJJl j I tllil'lf" l i i Illll
100 10' ld ld 104 18He + Temp. (eV)
D-94
II&Double Iol]izat _Orl Rate Coefficients for I
He + He + -> He + + He 2_ _ e
Beam - Maxwellian Rate Coefficients (CilI]/s)
He _
Tenlp. He Energy eV/e_1_u)(eV) 15000. 20000. 40000. 70000. i00000. 200000. 500000.
I. OE+00 4.90E-IO 7.62E'I0 2.15E-09 3.45E-09 3.38E-09 2.06E-09 8.82E-I02. OE+O0 4.88E-I0 7.62E-I0 2.15E-09 3.45E-09 3.38E-09 2.06E-09 8.82E-I04. OE+O0 4.88E-IO 7.62E-ZO 2.15E-09 3.45E-09 3.38E-09 2.06E-09 8.82E-I07.0E+O0 4.88E-I0 7.62E-I0 2.15E-09 3.45E-09 3.38E-09 2.06E-09 8.82E-]0I.OE+01 4.88E-I0 7.62E-IO 2.15E-09 3.45E-09 3.37E-09 2.06E-O9 8.82E-I02.GE+OI 4.88E-IO 7.62E-I0 2.15E-09 3.45E-09 3.37E-09 2.O6E-09 8.82E-I04.GE+01 4.88E-I0 7.63E-10 2.15E-09 3.45E-09 3.37E,09 2.06E-09 8.82E-I07. OE+OI 4 88E-I0 7.64E,I0 2.15E-09 3.45E-09 3.37E-09 2.06E-09 8.82E-I0I.OE+02 4.89E_.IO 7.64E.-I0 2.15E-09 3. !5E-09 3.37E,09 2.06E-O9 8.82E-I02 GE+02 4.89E-I0 7.67E-IO 2.14E-09 3,45E-09 3.36E-09 2.06E-O9 8.82E-]04.OE+02 4.86E-I0 7.72E-I0 2.14E-09 3.45E-09 3.36E-O9 2.06E'09 8.82E-107. GE+02 4.81E-I0 7.81E-I0 2.14E-09 3.45E-09 3.35E-09 2.06E-O9 8.82E-I0i. OE+03 4.80E-lO 7.89E-10 2.14E-09 3.44E-09 3.35E-09 2 06E-09 8.82E-I02. OE+03 4.91E-lO* 8.12E-IO 2.16E-09 3.42E-09 3.33E-09 2 06E-09 8.82E-I04.0E+03 5.35E-]0" 8.60E-IO 2.19E-09 3.38E-09 3.30E-09 2 O6E-09 8.82E-i07. OE+03 6.13E-lO* 9.36E-I0 2.22E-09 3.32E-09 3.27E-O9 2 06E-09 8.83E-]0i. OE+04 6.93E-I0 i. OIE-09 2.25E-09 3.26E-09 3.23E-09 2 06E-O9 8.83E-102. GE+04 9.42E-I0 i. 25E-09 2_32E.-09 3.12E-09 3.12E-09 2 05E-09 8,85E-II_0
Accuracy: * - Possible Error Greater Than 10%
- Possible Error Greater Than 100% Q
Chebyshev Fittinq Par_lleters for Rate Coefficients
Emi n = 10E+O0 eV, Enlax = 2,0E+04 eV
He
Energy
(eV/amu ) AO A1 A2 A3 A4 A5 A6
15000. -42.6506 ,210697 .170191 .107504 ,0517361 ,0113452 -,00599787
20000. -41.7921 .173873 .119280 .0639172 ,0267485 .00833917 ,0(.)105484
40000. -39.8862 ,0257832 .0218619 ,0122377 .00'362207 -2.35724E-O4 -9,65877E-04
70000. -39,0084 -,0336772 -.025]73] -,0147490 -,00625255 -.00]43355 2,795328E-04
IOOO00. -39.0462 -.0279022 -.0]71564 -.00916918 -.00454775 -.00203657 -7.5i4507E-04
200000, -40,0019 -.00189800 -8.3304 {E-04 -I, 62792E-04 -2,09259E-04 -7,95723E-05 -1.42798E-04
500000, -41.6965 9. 43319E-04 7. 29142E-04 4,97094E-04 2.96459E-04 I, 50204E-04 6. 26450E-05
E
See appendix for Chebyshev fit details.
i •
D-95
0He + He .+ ---":_,He"- + He' + + 20
Bec3m- MGXwellionO
I0*--" 40.0 ' i "11 Ilfll I '1 I i illll I ---T- I I illll I I "T-E[UU_ I I I
He Energy
(eV/(] rnu)35,0 -
a --15000.x --20000.30.0
v --40000.
_ --70000.
_ 25.0 -o • --I00000k_..J
0 .H m m --200000.© 20.0 --
47_.:'"- [] --500000,ou(b 15.0 - , - Recommended'o _Data
I0.0 -
/0 _ Chebyshev Fit
5.0 ....
0.0 l I I_JJllll l I llillll J I l lllJJl l I l lllJJl 1 J I IJ|JJ
100 10' 10_ 103 10' 105He+ Temp. (eV)
D-.96
Ionizat toll Cross Sect lolls .[01: O
, f.le _4 -t- H -> l.le 2. t. 11' .k e
Energy Velocity Ci:oss Sect ion(eV/ainu )' (cm/s) (cnl2 )
3. lE+04 2.4 5Et08 2.31F',-]64, ()[,'+04 2.78E_ 08 ,'3.39E--165 ....OE+04 3 liE+08 4 ()')E-J66. OE+04 3.40E+08 4.29E-.[67, OE+04 3.68E+08 4.22E-I8. OE+04 3,93E+08 4 0 It-169.0E+04 4.17E+08 3 •90E-[6i. OE+05 4.39E+08 3.77E-.[6
i. 5E4.05 5.38E+0[_ 3.04E-] 6
2.0E+05 6.21E+08 2.53E-163. OB+05 7.61E+08 i. 90E-]6
4.0E4.05 8.78E+08 i, 53E-165.0E+05 ' 9.82E+08 1.28E-165.5E+05 ].03E+09 i. 18E-]6
References: 506, 50'I, 508,. 509, 510, 522, 5]2, 653
Accuracy: 30%
Notes: (i) As fat: as we are aware only one experimellta] measurement hasbeen reported (Ref. 510). AS ore 100 _eV/amu the theoretical results o[
Crothers and McCan[i (Ref. 507) are with].n 10% of tile experimental results.At energies less than I00 keV/aluu the theoretical data (Refs. 506, 507,
508, 509, 511, 512) vary by as iiluch as all orclet: of magllitude.
Chebyshev FittJ.nq Par_l_eters for Cross Sections
: , : , 5.5E+05 eV/_mlEnlin 3. IE+04 eV/ainu Ellla x
, ,
AO AI A2 A3 A4 A5 A6
-71.9027 -,471110 -.344985 .128260 -.0459423 .00932704 .00279820
The fit. represents t:he above cross section with an rms deviat.ion of 0.5%.The nlaxilllUIiideviation .L£' O. 8% at 9.0E+04 eV/atom.
See appendix for Chebyshev fit details'.
D-97
QHe _++ H > He2+ + H+ • e
,,
1on]zaL].oll P,ate ct)et![:iclents [or
H .t- lie 2_ -.> I1_, -t- He 2_ -t e
BeeuII -' Maxwc-_l ].:[ all Rate (k-,e f. [ [(,'].etlL,':;' ( c,'m'_/s )
l.le 2_
Telilp. tt l!',lle i:gy ( eV / allltl(eV) 35000. 40000. , 60000. 80000. 100000. 2(.)0000. 500000.
1.OE+O0 7 21E-08 9 41E-08 l.4qE-O/ .1..6()1_-,07 .[.66E-0"1 1. 57E-07 1.26E-0'1
2.0E+00 7 21E-08 9 40E.-08 1,,IoE-07 ] 60E-.07 ].66E-07 1 57E-07 1.26E-074.0E+O0 '1 21E-08 9 40E-08 1.46E-07 1 601!b-()7 1.66F,-07 1 57E-0"1 :i.26E-07
7.OE+O0 7 21E-08 9 39E-08 1,46E-07 I. 60E-07 ].66E-0'1 1 57E-07 .I.26E-071.OE+0]., ' 21E-08 9 39E-08 ]..46E-07 :1, 60E-07 .1..65E-07 1 57E-(17 1.26E-072,ON+01 , 21E-.08 ,9 38E-08 '1.46E-07 .I 60E-07 I. 65E-07 1 57E-07 ]. 26E-,074.0E+OI 7 22E-08 9 37E-08 1.46E-07 1 60E-07 1,65E-07 I 57E-07 ]..261_-O7
7.0E-_,Oi 7 22E-08 9 35E-08 ].45E-07 .1 60E-07 1.65E-07 1 57E-.07 .[.26E-071.OB+02 7 23E-08 9 35E-08 1.45E-07 I 60E-07 1.65E-07 1. 57E-07 1.26E-07
2.0E.02 7 19E-08 9 33E-08 ].45E-07 .[ 60E-07 1 65E-07 1..57E-07 1.26E-074.0E-_02 7 0lE-08 9.31E-08 1.45E-01 ]. 606;-0,7 ]. 65E-07 1;5'IE-07 1.26E-0"17.0E+02 6.8OE-08 9.29E-08 1.44E-07 [ 6OE-07: 1 65E-07 1.57E-07 1.26E-07
].0E+03 6.67E-08' 9 25E-08 1.44E-07 ] 59E-07 i 65E-07 1.57E-07 1.25E-072.0E+03 6.54E-08' 9 IOE-O8 1.43E-0"I .I. 59E-07 ] 64E-07 1.57E-07 :1.241_-074.0E+03 6.66E-08' 8 96E-08 1.42E-0I I 59E-07 1 64E-07 1.57E-07 1.18E-077.0E+03 6.96F.:-08' 8 96E-08 1.40E-07 i 58E-07 ] 63E-07 ].56E-07 1.fOE-07,I.OE+04 7.26E-08' 9 O4E-08, ].38E-07 [ 56E-07 [ 62E-07 1.56E-07 ].O4E-07'2.0E+04 8.06E-08' 9 43E-08' ].34E,;_.07 i 53E-07 1 60E-07 . 1.56E-07 9.36E-08"
Accuracy' * - Possible Urr, of Greater Than ]0%
# - Possible Error Greater Than 100% i
Chebyshev Fittinq Pa_aunet:ers for Rate Coe£ficients
Erain = I.OE+00 eV, Ema x = 2.0E'1+O4 eV
II
Energy(eV/al, u) AO Al A2 A3 A4 A5 A6
35000. -32.8985 .00549401 .0364412 .0474517 .0313047 .00563515 -.00840841
40000. .-32. _844 -.0158075 6. 87820E-O4 .00939742 .0108456 .00801907 .00326444
60000. -31.5217 -.0331828 -.O190037 .-.O0885517 -.00343877 -9. 09107E.-04 9.5887!5['.'-05
80000. -31.3145 -.0148657 -.0105289 -.00656864 -.00357109 -.[10159023 -5. 08065E-04
I00OO0. -31..2432 -.0124344 -.00696173 -.00342119 -.00172670 -9.03335E-04 -4. 39816E-04
200000. -31.3365 -.00345476 -.00195539 -9. 1053]E-04 -3. 44995E-04 -I .21204E-04 -2.21966E-O5
500000. -31.[1962 -.105965 -.0779255 -.0443668 -.0153954 -4. 90580E-.()4 .00568340
See appendix for Chebyshev fit details.
D-99
H + He2+ -> H+ + He_+ + e
BeGin- M<lxwelliGnGD
'0"- 20,0 ---:yq-tiilWl I l , ,,,,,t I ,:i ,illll I ", f If'ifll I ' I I IIIIII.)_. ,
H Energy
(eV/a m u)
18.0 - - A-- 35000.
x -- 40000,
16.0 _"e - v -- 60000.
\U')"\ _ -- 80000.
Irl
E,,._o _ • -lOOOOO
• +-' 14.0 -- I ' _ -- '
C
O .02 m --200000.
_- _ []--500000.0 12.0 - <,,_ -U¢_ Rec°mrnendedo _ Data
FY10.0 -
( .......... ! .... Chebyshev Fit
8.0 - / -
6.0 -- i i i;_Jl_l t I._L.L.LUll 1 1 l lllllI 1 I III1!11 I 1 l illli
100 10' 10_ 103 104. 10sHe_+ Temp. (eV)
®
D--lO0
Cross Sec,t.iol[lS [oi tlts Production o[ Slow Positive Ions a_rl P,leel rf_ns 8
for Fle2+ Cotl.ld]tlg with IIz Molecules
He z_ + FI2 -> }: (H _2 alld H' Prod. ) (,-> _ rP,loci.rolls (.,-
lie2_ + H_ ((;') lie_ + IIz (_-)
F_llergy Cross Section EI1erc.]y Cross Section(eV I ainu) (cre") (_;VI_,u ) (cre")
4. OE+03 3.82E-16 2.5E_ 03 9.15E-17
4. OE403 6.17E-16 4.0E+O3 7.80_-.1.7
7.OF,_03 8.79E-16 5.DE+03 "/ 52E-17
I.OE.04 1.lIE--15 7.0E._O3 B 35E-17
1.5E+O4 1,37E-15 1.01_:+04 I .LSE-16
?,.OE+04 1.47E-15 1.5E+04 2 12B-16
2.3E+04 1,49E-] 5 2.0E4.O4 3 17E-16
4.0E+04 1.28E-15 4.0E+04 6 19E-16
7.0E+04 9.83E-16 'I.OE+O4 7 OOE-.16
I.OE+05 7.90E-16 I. 0E+05 6 971,]-] 6
i. 5F,+05 6.21E-16 I. 5E4'05 6 01E-] 6
2.0E+05 5.15_,_16 2.0E+05 4 94E._.L6
] ,OE+05 4.01E-16 4.0E+05 2 51E-16
5.0E+O5 1 90E-16
Referencesl 95, 143, 144, 346, 479, 532, 533, 534
Accuraqy, i 25%
Notes! {i) The seven reactions producillg slow iol|_ and electrolls are_ (a) He 24 4.
H 2 -> He 2_ + H2* + e (8iIlgle iotlization), (b) He ?* + H 2 -> Fle2+ 4. H _ + H + e
(dissociative iol_ization), (c) He 2_ + H 2 -> He 2_ + H* + H . + 2e (double
iollization), (d) He 2_ + H 2 -> He* + H_* (siI_gle electron _apture), (e) He 2_ + FI -
> He* + FI+ + H (dissociative electro U capture), (f) He 2+ + F]2 -> He + + H _ + Fl_ +
e (electrot_ capture with ionization), (g) He 2_ + Fl2 -> He + H + 4 H _ (double Welectron capture). (2) Afrosimov et al (Ref. 95) have luade a detailed study of
these reactions ill the energy reg]oll 2..3x]03 to 2.5×104 eV/amlu. (3) The cross
section for slow electrol] production (o-) is the stim of t_(a) + o(b) + 2o(c) + c,([).
(4) The cross section for slow positive ion proc]uctioll is the sum of o(a) + o(b)
+ 2o(c) + o(d) _. o(e) + 2o(f) _ 2_(g).
Chebyshev Fittinq Par sllteters for Cross Sections
Fle2+ + H 2 (o_) EI)_In = 2.0L,]+03 eV/ainu, Ema × = 3. OE+O5 eV/aim!
}le_+ + FI_ (o-) ,Eml n = 2.5EiO3 eV/a_llU, Ninax = 5.0E405 eV/m_u
AO AI A2 A3 A4 A5 A6
lle_ + H z (o*) -69,8186 .01]1387 -.631977 .0]'/9570 .0939313 -.00776735 -.O3]O932
lle2_ + H 2 (0-) -72.0755 .794419 -.668306 -.447465 .]96243 -.000576099 -'.0629005
The fit represents the (_*) cross section with all rt_Is (Jevlat]on of 1.3%.
The maximum deviat_1)n is 3.0% at 4.0E+04 eV/ainu.
The fit: t'epresents the (o_) cross sect ion w]th an rms dev.tatJo_) o.f. 3.2%.
The maximu,l clev_atlon |s 5.8% at: 7.0E+04 eV/_m_u.
See appendix [or Chebyshev _It details.
, D-i01
0He_+ H_ . e o-
Cross Section vs. Energy,-.,-'14 ,
, , ..............U 1 I I I I I I 1 1 I I I I I I I I I I 1' I I 1 I 1'1
_ , , A --C_+
' X:o"-
O- 15_p-._,
r'q
gc- ,©
'_ Recommended(D
cb _Datal/1
o3
0
L. ' _n Dn""e"ys"ev Fit
U '10-'_ i
10-_?:, , l., ll t l_l_l ,i i i i lliil 1 i , 1 111|1
103 10_ ,, 105 10°Energy (eV/amu)
D-lO2
Cross Sections for the Production of lt+ and H 2' Ions for He 2_ Incldent ()n H 2
lle2+ + H z -> o(H')
-> o(H2 _ )
(Curve A) (Curve B) (Curve C) (Curve D)
Total H2 * Prod. Si n.qle IOll. I{2 + Prod. Total H' Prod. [on. H + Prod.
Energy o Ene rg}, (_ Energy o Energy o
(eV/a_llU ) (c1112) (eV/allltl) (cm 2 ) (eV/ainu ) (el,|2 ) (eV/a]l,tl) (cl,l2 )
2 IE+03 9.68E-17 2.5E+03 9 97E-18 2.3E+03 2.17E-16 2.3E+03 i 66E-16
70E+03 6.30E-16 I.OE+04 5 30E-17 7.0E+03 1.91E-16 7.0E+03 ] 12E-16
1 OE404 7.92E-16 1.5B+04 1 36E-16 1.0E+04 2.15E-16 1.0E404 1 29E-[6
1 5E+04 9.00E-16 2.0E+O4 2 90E-]6 1.5E+04 2.51E-]6 1.5E+04 ] 60E-]6
20E+04 9.95E-16 3.0E+04 1 50E-15 2,0E+04 2,86E-16 2.0E+O4 I 79E-16
3 OEr04 1.48E-15 4.0E+04 3 20E-15 4.0E+04 4.53E-16 2.5E+04 ]. 90E-16
40E.04 3.18E-15 8.4E+04 5 19E--15 7.0E_O4 6.35E-]6 4.0E+04 I 76E-16
7 0E+04 5.07E-]5 I.OE+05 5 ]8E-]5 8.0E+04 6.43B-16 7.0E+04 i 36E-16
8 4E+04 5.21E-I[ 1.5E+05 4 77E-15 I.OE+05 6.32E-16 I.OE+05 i 06E-16
10E+05 5.18E-15 2.0E+05 4 26E-15 1.5E+05 5.59E-16 1.5E+05 7 5]E-]7
1 5E+05 4.80E-15 4.0E+05 2 97E-15 2.0E+05 4.87E-16 2.0E+05 5.46E-17
20E+05 4.29E-]5 5.4E+05 2 50E-15 4.0E+05 3.20E.-]6 4.0E_05 2.33E-17
40E+05 2.97E-15 4.6E+05 2.92E-]6 6.0E+05 i. 50E-].7
5.4E+05 2.50E-]5
References: 95, 346, 553
Accuracy_! 25%
Notes: (1) The seven reactions producing reaction products H + and H 2" are: (a) He 2_
H 2 -> He 2+ + H2 + + e, single ionlzation; (b) He _'+ + H 2 -> He 2_ + H 4 + H + e,
dissociative ionization; (c) He 2+ + H 2 -> He 2_ + H + + II* _ 2_, double ionization;
(d) He _'. + H 2 -> He + _ H 2", e]ectron capture; (e) He 2. + H2 -> He+ + H _ + H,
dissociative electrou capture; (f) He 2_ + H 2 -> He' _ H . + H+ + e, electron capture
with lonizat_on; (g) He 2+ + 112 -> He + Ii+ + H _, double elect;roll capture. (2)
Afrosinlov et al. (Ref, 96) have ,lade detailed studies of these reactions. (3)
Shown as curve A is the total cross sect.ion for produci_]g H2+ and is the sum of
o(a) and o(d). (4) Curve B is the sil]gle lonJzatiou cross section for producing
H2 +' o(a). (5) Curve C is the total cross section for producing H + and is the sum
of o(b) 4 2o(c) + o(e) + 2o(f). (6) Curve D is tl_e cross sectioll for producing H'
by ionization collisions, o(b) 4 2o(c).
Chebyshev Fittil_q Par6uueters for Cross Sections
Curve A Eml n = 2.1E+03 eVainu, Ema x = 5.4E+05 eV/amtu
Curve B Eml n 2.5E+03 eV/_mlu, = 5.4E+05 eVainu
Curve C Eml n 2.3E+03 eV/ainu, EIUaX
Curve D EMl n 2.3E+03 eV/ainu, Ema x = 4.6E+05 eV/em_u= Ema x _ 6.0E_05 eV/ainu
AO AI A2 A3 , A4 A5 A6
Curve A -68.8191 1.6:697 -.768285 -.163048 -.111162 .206844 _ .0545283
Curve B -70.9500 3.2-_148 -1.!2038 -.650292 .397513 .189249 -.208238
Curve C -71.4299 .407648 -.257736 -.323208 .0419822 .0784881 .0252954
Curve D -74.1448 -.984730 -.626797 -.217335 .186783 -.0134584 -.0263402
The fit represents the Curve A cross section with an _ms deviation of 12.0%.The ,llaximum deviation is 23.3% at 3_0E+04 eV/_llu.The fit represents the Curve B cross section with an rms deviation of 12.'1%.The maximull_ deviati.on is 31.9% at 2.0E_O4 eV/am|tl.
The flt represents the Curve C cross section with an rms deviation oi 2.3%.The maximum deviation is 3.3% at 1.5E+05 eV/ainu.
The fit represents the Curve D closs section with an rms deviatiol] of 3.2%.
The maximum deviation is 4.4% at 7.0E+04 eV/_llU.
See appendix for Chebyshev fit details.
•
D-lO3
OHe_+ + H -> ct(H+),cr(H+)2 2
Cross Sectior_ vs. Energy10-'__ i i i i i i'i II w'-_T-T_----1 I i I i i I I
/ / ,,, :.,
J' ,"_ _-A
- ,. _ . V-C
- " _-D
E0 i,
f-- .,,.0
'.D 1_ Recommendedo 10- - --Data
_1_ ® -b0
CO
'0 _ Chebyshev Fit
// \10-1__
10-,i , i i i lilll i i i i AIIll I I I i lllJ
103 104. 10_ 106Energy (eV/amu)
D-104
QCross Sections for tile Production of Slow Pos.ltive Ions and El ectrcms
for He 2+ Ions Interact:ing with I-le.
tie 2' t- HO -> o +He;"' + He -> o-
He 2+ + He (o 4) He ''4 + He (o-)
Energy Cross Section Energy Cross Sect.loll( ev/amt! ) ( Clll_ ) ( e V / allll.I ) ( cnl2 )
9. OE+03 3.72E-]6 5. OE+03 ]. 59 [,]-18i. OE+O P 4.03E-16 7. OE+03 4.68E- [81.5E+04 5.30E-]6 ].OE+04 I. 29F,-172.OE+04 5.87E-16 1.5E+O4 3.O7E-173.OE+04 6.03E-]6 2.0E+04 5. ] IE-174,OE+04 :).r_91E-]6 4.0E_'04 1.30E-167. OE+04 4.98E-16 7. OE+04 2.20E- 161.0E+05 4. ].9[']-16 ]. OE'105 2.74E-16I. 5E+05 3.29E- ].6 :[.3E+05 2.88E-16
2. OB+0% 2. 7313-]6 I. 5E+O5 2.84F'-164. OB-l'05 ]. 70B-16 2.0E+05 2.5]g-167 ;OB+05 i. ]413,-]6 4. OB+05 I. 62E-16].OE406 8.54E-17 7. Og'+O5 1.06E-]61.5E+06 6. fOE-J7 ].OB+06 7.96E-172. OE+06 4.74E-]7 '[.r.,>E+06 5.57E-].72.9E+06 ']•4]|']-17 2 •OE+06 4 •3 lE-J7
2.8E+06 3 •29B-] 7
L
0References: 143, 144, :1.48, 375, 381, 382, 479, 49!5, !332, 534, 537,538, 539, 540
Ac.curacy!, o .... 30%o- - 50%
i
Notes: (]) Tile reactions occurring whon He 24 Teacts with He are: (a) He 2+ _ He
-> He + He 2., double electron capture; (b) He 2+ + lie -> lle" 4 He', single
electron ca]_ture; (c) He 2_ + He -> He 2+ + He 2+ + 2e, double Ionization; _{I) He 2+•+ lte -> He z+ + He + -_ e, sJngl.e .tonlzat::|on; (e) He 2+ t He -> He + + He + _ e,single capture with sirlgLe fonJzation. The cross sect:ions for slow el.ectron
production o- is 2o(c) + o(d) 4 o(e). ']'he cross sectJolls for slow ion production
°+ is o(a) 4 o(b) + o(c) + o(d) + o(e). (2) For energies less tllal] 105 eV/ainu
electron capture dominates overlonization.
_byshev Fittinq Parameters £or Cross Sections
o+ Ellli n = 9. OE+03 eV/Emltl, Eiila x : 2.9E-106 eV/ainu
o- grain = 5.0E+03 eV/ainu, F,max : 2.8g-t-06 eV/ainu
AO Al A2 A3 A4 A5 A6
o+ -12.3332 -].34390 -.539938 .150932 -.0442699 -.00]O2]0] .004982]I
o- -75.4418 1.18618 -].77854 .310230 .0670546 .0236438 -.0500356
Tile fit represents tile o4 cross section witll an rms dev.[ation oi O.6%.
Tile nlaxJlliUllldeviation is 1.3% at: 3.()E_04 eV/anlil.
The fit represent s the o- cross sect J.on w.i t:h an [Ills deviat i°n oi 2.9%.
The lllaXillltllll deviatJ.on is 5. ] % at 7.0E+03 eV/_nu.
See appenclix for Cheby_hev fit details.
D- :t0 5
He_++ He -> ct-He2+ .+ He -> cr+
Cross Section vs. Energy10 -15 ' , , ,",',,,,I'"l , ,',,,,,i ,', , ,,,,,i ' '' '''"
- /
/ \
- _/ \\\
\ A--O -+
X-'O"
i0-1__E-"
E //0
ff
,0_ - Recommended_.) -
¢) DataLr)(/)or)
0 Chebyshev Fit
L) 10-;7_
l(h-1 J___L.l t lllll J ....I. J iJlltl 1 1 I ii Jill. J _ li iii.1%/
10+ 10+ 10s 10+ 107Energy (eV/amu)
J
1
D-106
I Slow Positive ]on Pz:oductiorl Rate Coe[f.ic:t.enl:s fo[
lte R+ t- lte -> o _
P i '
Maxwe]].ian - Maxwe]].ian Rate CoefJ:.t.c.[ents (_:ml3/S)
' 24`tte
Temp. Equal lie Temp. (eV)(eV 1 Temp. 5000, 6000, 8000. i0000. 12000. ]5000. 20000
k
3.5E,*03 1.01E'09H 2,40E-09_ 3.68E-09# 6,9.5E-09_ 1 .....09E-08# I 53E-08_ 2 _2E-08# 3,37E-08 *
4,0E+O3 1 86E-OgH 30IE.,09_ 4,42E-ogH 7.89E-09_ l.'20E-O8_ ] 64E-O8_ 2,33E-O8 _ 3.4flE-O8 _
4.5E*03 30IE-09@ ] 68E-091/ 5,22E-090 8,'86E-09_ I,?IE-OSH 1 75E-O8_ 2.45E-08' 3.59E-08'
5,0E_03 4 42E-O9# 4 42E--09_ 6.O6F',:0911 9.86E_0c1_ 1,42E-O8@ 1 87F,-08@ "2.57E...O8 _ 3,70E-O8 A
5.5E+03 6 06E-09# 5 22E,09,_ 6.95E-09# 1,09E-08# 1,53E-O8@ I 99F,-O8H 2_.68E-O8 _ 3.8[E-08'
6.0E+03 7 89E-09# 6 06E-09@ 'I,89E-09# 1,20E-08# 1,0,1E-08_I 2 IOE-OBII 2,80E-O8' 3,9}.E-.O8'
8,0E403 I 64F3-08_ 9 86E-09_ 1,2OE-0811 1,64E-08_ ::.IOE.-O8@ 2 57E-08' 3.26E-08' 4.35E-08 _
] .()E_04 2.57E-08' 1 42E-08_ 1, (;4E-08_ 2, IOE-OSH ,',.57E-O8' 3,03E-08' 3. '/OE-O8* 4.76E-08 _
1.2EIO4 3,48E-08 _ I 87E-08_ 2.1OE-08# 2.57E-08 _ 3,03E-08 _ 3.48E-08 _ 4,14F, 98 _ 5.15E-08 _
1 4Ei04 4,35E-O8' 2 33E--08 _ 2.57E.O8 + 3, ()3E-08 _ 3.48E-08' 3,92E-08 _ 4.55E-()8' 5.53E_O8 +
],6E+04 5. ] 5E.-O8 + 2 80E-O8 _ 3.03I_-08 '_ 3.48E-08' 3,92E-.O8' 4.35E-O8' 4.95E-O8 '_ 5.89E-08'
1.8E+04 5.89E-08' 3 26E-08' 3,48E-08' 3.92E-08' 4,35 .E-08 _ 4.76E-O8 _ 5. 34E.-OB _, 6, ?.4E-.O8 _
'2.OE+O4 6.57E-08 _ 3 "fOE-OR" 3,9JE-08' 4. 35E--O8' 4,761']-08 * 5.1.5E-O8' 5,'?IE.-O8 * 6.571,?,-0_]_
Accuracy: * - Possible Error* (]£eater Than I[)%# - Possible Error Oreater Tharl 100%
Cbet)yal_ev Fittinq Parmneteis for Rat:e Coefficients
Etll:Jn = 3.5E-t.03 eV, l,r;llh.l× =: 2 • OB.! 04 eV ,He
Temp.
(eV ) AO A I A2 A 3 A 4 A 5 A6
5000. -36.8434 1.38333 -.0598328 -,015'7120 .OO186832 ' 1,83603E-O4 6,O5353E-05
6000 -36 4161 I 19746 .0301418 ,0151798 9 7 l-,r* . . _ ,' , • - - . [.,.,8E-.04 1 15739E-04 3 58181E-05
8000, -35.7440 .928769 .00411079 : ,O]26285 I, 550(]6E-04 2.078i6E-O4 i. 37906E-04
IO000. -35,?.350 ,745842 .0204972 -.00979258 -3,75639E-O4 2. 3856OE-O4 -3. 33682F,-O5
12000. -34.8337 ,635060 .0278881 -.90";27889 -6,44358|'3-01 -3.66627E-05 4,O9092E-O5
15(100. -34,3648 .477864 ,0321621 -.O0474753 -6,70690E-04 1.26091E-O4 -4,23094E-O5
20000, -33.8047 .336]27 .0310835E-02 -.O0234049 -6,33145E-04 -5.0436OE-O5 -] .09705E-O4
Equal Temp. -36.4417 2,0299[! ,39947"2 .0593303 -,O0723537 5,'7"14"10E-04 -3.03527E-05
See appencl.lx for Chebyshev fit (]eta.|]s.
D-107
QHe_+ -I- He -> a +
0.0 1 1 1 I 1 I' 2,5 5.0 7.5 10.0 12,5 15,0 17.5 20.0
He2+ Temp. (eV) "10_
D-108
OSlow ,.Posiltive Ion 'Product;ion Rate Coe]!fl.c-.l.ents for."
" He + I-1o.2_ -> o 4
Bemu - Ma×we.iI.lan Rate Coeffi[;ients (cm3/s)
He 2_
Temp. He Energy (eV/_nu )(eV) IOO00. 2OOOO. 40000, 70000. I00000. 200000. 500000.
i. OEfOO 5.60E-08 1.15E-07 1.64E-0'I 1.83E-O7 1.84E-O7 ] 69E-0"I 1 42E-0"12.0E+O0 5.60E-08 1.15E-O'I 1,64E-07 1.83E-07 1.84E-O7 I 70E-07 I 42E-074.OE+O0 5.60E-08 1.15E-07 ].64E-0/ ],83E-07 I 84E-07 ] "IOE-07 I 42E-O77.0E+00 5 60E-08 I. 5', I_E-07 1.64E-07 ] 83E-07 ] 84E':-O7 I 70E-O7 ] 42E-O71,OE+01 5,60E-08 ..1..15E-07 1.,64E-.07 1.83E-07 1 84E-07 ] 70E-07 1 42E-07
2,0E.fO1 5,60E-08 1.,15E-07 1,64E-0"1 1.83E-07 1 84E-O'1 1 7OE-O'l 1 42E-O'I4,OE+O1 5,55E-08 1.15E.-07 ] 64E-07 I RIE-O'I , 1 84E-07 1 "lOE-07 1 42E-077.0E-tO1 5,42E-08 1.15E-07 1 64E-07 ] ,_.3r.,:-O/ ] 84E-07 1 70E-Ol 1 42E-O7
1.OEr.02, 5.29E-08 1.'15E-07 ii 64E-07 .[ 83F-07 1 84E'0"1 I 70E-O'/ 1 42E-O72.0E+02 4.99E-08' 1.15E-07 1 6.3E-.0"1 1 83E-0"! 1 84E-0'2 1 70E-O'I 1 42E-074,OE+02 4.75E-08' 1.14E-07 1 63E-07 1 82r,:_O7 ] 84E-07 1 69E-O7 1 42E-O77,OE+02 4,6"7E-08' 1.14E-07 1 63E-07 I 82E-07 1 83E-07 1 69E-07 1 42E-O71,OE+03 4.68E-08" ]..14E-0/ 1 63E-07 1 82I/:-07 .1 831.]-,0"1 .1 69E-0/ ] 42F,-072.0E+03 4.90E-08" 1..]4E-07 . 1. 62E-07 ]. 82E-0'/ :l 83E-07 ] 69E-07 1 42E-07
4.OE+03 5.40E-08' 11.15E-.O7 1 62E-O7 ] 81_1-07 t 83E-O7 1 69E-07 1 42E-077.OE+03 6,06E-08' 1.15E-07 :1 61E-07 ] 80E.-07 1 82E-.07 1 69E-O7 1,42E-07
1.OE_04 6.62E-08 * 1.16E-O7 1 60E--Q7 I 8OE-O7 1 82E-O7 I 69E-07 1.42E-O72.0E+04 8.14E-08' 1.20E-07 ] 59E--07 ] 18E-07 1 80E-07 ] 69E-07 1.42E-07
Accuracy: * - Possib].e Error Greater Than 10%
# - Posslble'' Error Greater Than 100% Ii I
Chebyshev Fittinq Parameters for. Rate Coefficients
Ellli n = 'I,OE+O0 eV, Eiila x = 2.0E4.04 eV
He
Energy .(eV/amu ) AO Al A2 A3 A4 A5 A6
I0000. -33,3528 ,0888838 _145456 .115375 .0287771 -,O19"1504 -,0097556120000, -31,9486 ,00733446 ,0104567 ,00858353 ,00508869 ,00265079 .0015503940000, -31,2633 -,0136989 -,00614936 -,00195506 -5.61861E-04 -2.03312E-O4 -6,59434E-0570000. -31,0420 -.0112913 -.00592950 -.00253976 -,00106355 - 4.84457E-O4 -2.29325E-O4I00000, -31,0255 -.00737792 -,004]5937 -,00198048 -9, 12662E.-04 -4.315OOE-04 -1,81183E-O4200000, -31,1826 -,OO1.93461 -.00125764 -4,52646E-04 -2.5365OE-04 2,30595E-O5 -3.75081E-O5500000. -31.5305 -2,,56726E-O4 -1,78746E-O4 -I ,O4195E1-04 "5,27594E-D5 -2,69854E-O5 -1 .83293E-O5
See appendi× for. Chebyshev flt deta l]s
D-lO9
IIHe ,+,He2+ -> c_+
2.5
lo0 ld lO_ 1o_ 1o_ 18He_* Temp. (eV)
D-II0
Slow I_lectron Produet;t,on Rate C.oef,f.ie:Lent.s for 0
l:le 2t + tte -> 0"
Ma×w('lliau - Maxwelliau Rat:e Coei"flc:ieuts (elU3/s)
He z+
TelBp, Eq tlaI lie 'I'{_i,p, (eV )
(eV) Tem'p. 5ooo,. 6ooo. 8ooo, IOOOO. 12000. 15000. 2oooo,
I 5EIO3 I, 17E-12_ 6,45E-11_ I, lIE-lO _ 2147E-'lO _ 4,44E-IO* 6.99E-10 1, IBE-09 2i24E-09 '<
20Ei03 6.87E-12# 8.57E-II ^ 1,39E-I0' 2,9]E-10 A 5,02E-IO* 7,72E-IO 1,28E-O9 2 36E-O9
2 5E+O3 2,11E-II_ 1 IIE-IO* 1,71E-lO _ 3,3BE-I()* 5.64E-10 _ B,48E-IO 1,37E-Q9 2 4BE-O9
30EIO3 4.68E'II@ 1 39E-I0 _ 2.O'IE-.IO _ 3,89E-IO _ 6.30E-IO _ 9.27E_IO 1,47E-O9 2 61E-09
3 5E_O3 8.57E-11' 1 "IIE-IO* 2,47E-I0 _ 4,44E-qO _ 6,99E-IO ].OIE-09 1,57E-O9 2 73E-O9
40E+O3 1,39E-I0' 2 O7E-I0' 2.91E-I0 _ 5.02E-10 _ 7.72E-'10 I 10E-O9 1,60E-O9 2 86E-O9
4 5E*O3 2.O7E-10 _ 2 47E-I0 _ 3,38E-I0' 5,64E-IO A fl.48E-]O t 18[?,-O9 1.7BE-O9 300E-O9
50E+03 2 91E-IO* 2 91E-I0 * 3.89E-I0' 6,3OE-I0 _ 9,27E-IO I 28E-O9 1,89E-O9 3 13E-O9
5 5E+03 3 09E-I0 _ 3 ,38E-10* 4,44EiI0 _ 6,99E-10 I,OIE-O9 I 37E-O9 2.OOE-O9 3 27E-O9
6 0E_O3 5 O2E-IO* 3 89E-IO * 5,O?,E-IO* 7,7_2E-I0 I.IOE-O9 1 47E-,O9 2.12E-09 3 41E-O9
00EIO3 I IOE-O9 6 3OE-IO _ 7 72E-I0 1,1OE-O9 ],47E-O9 1 _]9E-O9 2.61E-09 3 99E-O9
10E_O4 1 89E-09 9 27E-IO ] 1OE-O9 1,47E-O9 l,fIgE-O9 2 36E-O9 3,]3E-O9 ,I 6OE-09
I 2E_O4 2 B6E-O9 I 28E-09 1 47E-09 I,_19E-O9 2,36E-O9 2 86E-09 3.69E-09 5 24E-09
1 4E_O4 3.99E-09 i 6BE-09 I 89E-09 2,36E-O9 2,II6E-O9 3 411.,:-O9 4,29E-09 5 91E-O9
1 6E+O4 5.24E-09 2 12E-09 2 .16E-09 2,B6E-.O9 1.41E-O9 3 99E-Og 4.92E-09 6 6OE-O9
1 8E+O4 6,60E-09 2 61E-09 2 86E-O9 3,41E-O9 3.99E-O9 4 6OE-O9 5,57E_O9 7 32E-O9
2 0E+O4 8 O6E-O9 3 13E-09 I 41E-09 3,99E-09 4 60F-O9 5 24E-O9 6 25E-O9 O O6E 09
Accut-acyl A -Possi.ble Error Gi;eater Than 11.0%
II - Possible Error Greater 'I'hal} 100%
@, Ch__ebyshev Vittir,_q Pa_ullete_s _or Rate Coefficiellt._.ss
Eiilin = ],5E4-03 eV, Enlax = 2.0E+04 eV
He
Telilp.
(eV) AO AI A2 A3 A4 Ab AO
5000, 43 3317 1.97188 ,145899 -,O314B58 -,00292157 9.873101_-O4 6,59233E-O5
6000, -42 7445 1,73787 165090 -,0242892 -,00406700 '7.29676E-O4 ]. 185191_;-04
8000, -41 B072 1,40305 177579 -.01Z5933 -,00472104 2,21088E-O4 I. 43982E-O4
] 0000. -41 0752 1,17389 175396 -,OO4537Q9 -,00443211 -1,26246E-04 1,20206E-O4
12000. -40 4766 1,00680 167979 8,55383E-04 -,00385784 -3,27458E-O4 B. 43893E--O5
15000, -39 "7464 .826618 15417. I ,00577291 -, 00294670 -4,58815E-O4 3,46633E-05
20000. -38 8140 .631796 131790 ,DO946407 -,00174398 -4,77146E-04 - l, 7817,5E-O5
Equal Temp. -44 6706 4,27088 -.605712 .139921 -.0311302 ,OO607534 -B, 51332E-O4
See appendix for C'hebyshev fit deta.t.ls,
D-11.I
iie2+H -t-He -2-, cr
,
,,
Mmxwellior-i-Mmxwellimn
8',"<,...,_ r ' , ----, -r [ r ----1.....
......_..I___._..._..--.---7.Z':.--"• H e -re rl, p,
./...i- _.......>_ _../..----". (eV)
_.--_/_.:;.-_.._.--_f..----"_ -.5ooo,...-I .../ _ .... /._/ _...---(.j_..,.---..... ......-_A.--_./"-'-_---- ,.:- Gooo,
./.--- ......--" .._-- _..f.-1"I /--I.t /
1 / ../: /" /"'7 q -- 8000,
•co I0-9 .- / :/ /./-•.,.,. ./ // /'/. ....-"_,,'..- Z '* -- I000O,
{,q / i /,/ i li /
g- -- - _,-I_ooo."-" / ,'" I"/"
._':2.c.__>.+_- v//" //,,(7k,.,,,, _ [] - 15ooo,_- []--20000,q)0O
(D Recommended0 "lr>,-lc _ - Data
Ct/ Ik./
...... Chebyshev FitI
- Equcil Ternp,I
/
1OF".... J_c_ ___z.... l J i. L ,0.0 2.5 5,0 7,5 I0,0 12,5 15,0 17,5 20.0
He_+ Temp. (eV) "10_
ii
D-112
L
Slow Electron Produot[ol] Rate Coefficlent;s [or
fie -I.lie2. -> o"
Beam - Maxwelllall Rate Coefficients (Cm3/el)
He 2+ ,
Temp. He Erierely (eV/ainu )(eV) i0000. 20000, 40000, I0000. 100000. 200000. 500000,
I,OE+O0 1.06E-09 1.04B-08 6 65[':-08 3.41E,-08 5.3]E-O8 1.56E-O'1 1 34E-.072,0B4.O0 1,60B-O9 1.00F,-08 4 88E-OB 6.09E-08 9.79E-08 1,56E-07 [ 341_-074.0E+O0 1.78B-O9 1.00E-OB 3 B6E-O8 "1,70l_-O_I ],]8l!:-O7 1,56E-07 [ 34E-O77. OE-lOO i 79F,-09 i. O()F,-08 3 63E-08 8.04E-O8 I, 20E-O7 I. 561_:-07 I 341!:-O7
l. OE+01 I 78E-09 i 00F,-08 3 61E-08 8.07F,-08 1.201!I-07 1,56E-07 I 34B-O72,0E+O1 i 78E-09 ] 00E-OB 3 60E-0B 8.011!;-O8 :I,20E-OI 1.56E-07 :I 341,.",-O'74.0E+01 1 79E_-09 1 00E-08 3 60E-08 8.07E-08 1.20E-07 ]. 56E-07 .| 34E-077.0E'I.OI 1 '19E-09 ! 00E-08 3 60E-08 8,0'IE-08 ].20F,-07 I 561_-O7 I 34E-07
I OB+02 1 80E-O9, i OOE-08 3 60E-08 8,06E-0_ .1.201']-07 i 56B-O7 .[ 34E,-O720E+O2 I 83E-O9 100E-O8 3.60E-08 8.06E-O8' 1.20E-O7 I 56[,:-07 ] 34E-O74 0E+O2 1 90E-O9 , i 0lE:-08 3.60B-08 8,06B-O8 1.20E-O7 ] 56E-O7 I 34E-O7
70E+O2 2 0:lE-09 1 03E-08 3.61E-08 8.06E-08 1.19E-O'I ] 55E-O"l ] 34F,-O'II OE-I-03 2 13E-O9 I 04E-08 3,62E-O8 8.06E-O8 1.19E-O7 ] 55E-07 ] 34E.-O7
2 OB+03 2 51E-09 ]. 09E-08 3.67E-08 8,09F,-08 I.].9E-O7 :I 55E-07 :I.34E-O'I4.0E+03 3 27B-09 1.20E-08 3.'19E-08 8,16E-O8 1.19E-07 I 55F,-07 :I 34E-077.0E+03 4 44E-O9 1.37E-08 3.97E-08 8.28F,-O8 ].]9E-07 I 54F,-0'I I 34E-07I.OE+O4 5 63E-O9 1.54E-08 4,14E-O8 8,38E-08 1,19E-O7 I 54E-07 ] 34F-O72.0E+O4 9 85E;-O9 2.085-08 4.70E-08 8.69E-O8 :|.19E-O7 I 52E-07 1 34B-O7
{_'hebyshev Flttlnq Parameters for Rate Coefficients
ElM n = 1,0E-t.O0 eV, Ema x = 2, OE+04 eVHo
Energy l
(eV/amu) AO AI A2 ,A3 A4 A5 AG
]0OO0. -39.6384 ,794564 ,318341 ,275468 -,0163980 ,0386510 -,030276520000, -36,5385 ,251533 ,188617 ,0914015 ,0423640 ,00564777 .0022539840000. -33.9830 -.096596_ .217818 , -,0655465 ,O766555 -,0163273 5.77974E-O470000. -32.8790 ,252448 -,174234 ,159512 -,0904273 ,O541651 -,0228943]00000. -132.0888 .]96302 -,176198 ,14045_ -,0957365 ,0592874 -,0318816200000, -31.3593 -,00872687 -,00490003 -,00214295 -9,76224E-04 -3,39591E-04 -1.98244E.-O4500000, -31,6466 -3.56481E-04 -2,64796E-0,I -I,77709E-04 -I,07797E-04 -6,25087E-05 -4,O2042E-O5
See appendix for Cllebysllev f.lt:_ deta:lls,
II
D- ].1t
• 'He + He2_ --> o--
Beam Maxwellion
,IU 6____x__rTrrllllS_- i T-l_uu111 I I IllUlll I I Inlu/u/- i i i ._
.... He Energy
-- - (eV/a r'nu)
z_ --I0000,
x -- 20000.
E[ ITI _, __ 40000.
,% '10-7 ...- ......... •m"" ,-- - _ -- 70000.
c) :_,_ ¢ -- 100000,--/ (
7"O _,,,, ._.-_7+"C. ",-.,,.._ [] -- 200000.9(,.)
'4-- '_ --530000' (D _ ,X '
0 //
o ./¢) .--" Recommer_ded
IC)-B _ ' _"" _s, _ ------ Data(3.1 - /- -
_ _- .... Chebyshev Fit
//
/
f..._JY-- _.._,._ .-
/-f
/
•lO-9___L_Lk411_l _L__LaJ_LLU] L_LJ_LU.Lfl__.± _ L!lllJl J LZJ,ZZZ
ld' ld I0"_ 10:_ 10" 1()5He 2! -[bmp. (eV)
O
................. i ill ...................................................................... i., ,,,,l ............... 11: ............. 1.................. ii_l[T,j_ ............ ':..: ........ rT ................ :l._ _-- ..................................................................................................................... J
D--114
Single arld Doub].e Ionization Cross Sections for l-le2' + He CO1].i81_llS O
lte 2_ + Fie -> He 2+ + tte _ -t- ette 2' + tte -> He _+ + l-le2_ + 2e
Single lonization Double lonizat l.on
Energy Cross Section Energy Cross Section
(eV/_nu ) (cm ? ) ( eV/ainu ) (cm _ )
]. 5E+03 2.72E-18 1.4EI04 4.43E-192. OE+03 2.85E-18 i. 5E+04 4.70E-19
4. OE+03 3.4 IE- 18 2.0E404 6.21E_]97. OE+03 4.73E-18 4. OE+04 i. 32E-181. OE-104 5.96E-18 7. OEI04 2.76E-18].5E+04 8.11E-18 L. OE+05 6.06E-18
2. OE+04 1. IOE-17 i. 4E+05 7.60E-] 84. OE+04 2.92E-17 i. 5E+05 7.50E-]87.0E+04 1.28E-16 2.0E+05 6.6SEr 181 •OE+05 !. 85E- 16 4. OE+05 3.01E-181.5E+05 2 09E-16 7.0E+05 1.27E-182.0E+05 2 05E-16 I.OE+06 7.13E-194.0E+05 1 50E-16 1.5E+06 3.51E-197.0E+05 i 03E-16 2.0E+06 2.53E-]9]. OF,+06 8 17E-17 2.7E406 2.06E-191.5E+06 6 IOE--172. OE+06 4 97E-]72.4E+06 4 46E-17
References: 148, 282, 381, 382, 383, 384, 387, 537, 538, 540 I
Accuracy: o(He .) - 30%
o(He 2. ) - 50%
Notez-- The data of DuBoi8 (Ref. 538) supercede earlier results (Ref. 282) dueto recalibration of the slow recoil ion detector. These corrected data are
consistent with those of Afrosimov et al. (Ref. 148), which define tile low-energy behavior of the cross section.
Cheb;,shev Fittinq Par6uueters for Cross Sections
o(He +) Ell|in = ].5E+03 eV/aJml, Ema x = 2.4E+06 eV/_llu
o(lle2_) Elllill:: 1.4E+04 eV/a]11u, Elllax =: 2.7E+06 eV/mllu
A0 A1 A2 A3 A4 A5 A6
a(He.) -76.5996 1.88840 -.91310] -.705245 .237700 .295143 -.101724
a(He 24) -82.9537 -.441854 -].49781 .0576939 .413751 -0249295 -.0956323
The fit represents the o(He +) cross sect:ion with an rms deviat:.i.otl of 15.4%.
The maxinlunl deviatlol] Js 44.5% at 4.0E+04 eV/ainu.
The fit represents the o(He 2') cross section with an r111_ deviation of 8.4%.
The maximum deviatlon is 18.4% at 7.0E+04 eV/_uml.
See appendix for Chebysl_ev f.'it:, details. 0
b- .'1.15
0He2+ + He -> He_++-He+ + e ct(He+)
He_++ He -> He2++ He"_++ 2e ct(He_+)
t
Cr-oss Section vs. F-nergy• -15lO ¢ .... 7 ', , ,_tr,1 , i, wl',_,l ', , ,'l-r'r'r-rr-- , , i _
,,
' X - cr(He_+i
10-_6 /' "_"
,/ "_,._/ • ,
I
0 ,/
r- , '}/
° /,)/'-_ _ Recommendedo 10-17
0 ® 4";"/ ,'_X" _ DataOf) .. q ' -(/.) _ ,,-.,
0 'U Chebyshev Fit
_ //
_. X
10 19 l t l llttlL . I I t ltlJtl .t 1 I lJlI_LL j__...J__l I11_1
"ld 10" 10s 106 ldEnergy (eV/a mu)
D-II6
0Single Ionization Rate Coefficients for
He 2_ + He -> He 2+ 4- He + + e
Maxwellian - Ma_wellian Rate Coefficients (cm3/s)
He2+
Temp. Equal He Temp. (eV)
(eV) Temp. I000. 2000. 4000, 7000. I0000. 15000. 20000.
1.0E.03 2.02E-II@ 2.02E-II# 5.26E-I{@ 1 21E-10* 2.21E-I0' 3.23E-10 5.15E-.I0 7.50E-I0
1.5E.03 5.26E-II# 3.57E-II# 6.99E-II* 1 38E-I0 + _.38E-I0 _ 3.41E-I0 5.36E-I0 7.76E-I0
2.0E+03 8_72E-II* 5.26E-II# 8,72E-II* 1 55E-I0 _ 2_54E-I0' 3.59E-I0 5.58E-I0 8.04E-In
2,5E+03 1.21E-lO* 6.99E-II* 1.04E-lO* I 71E-10 * 2.71E-I0' 3.77E-I0 5.80E-I0 8.31E-I0
3.0E+03 1.55E'I0' 8.72E-II * 1,21E-10* i 88E-I0' 2 88E-I0 3.96E-I0 6.03E-I0 8.60E-I0
3.5E+03 !.88E-I0' 1.04E-10* 1.38E-]0 * 2 04E-10* 3 06E-10 4.15E-I0 6.26E-I0 8.89E-I0
4.0E+03 2.21E-I0' 1.21E-10* 1.55E-I0' 2 21E-10* 3 23E-I0 4.34E-I0 6.50E-I0 9.19E-I0
4.5E+03 2.54E-I0' 1.38E-I0' 1.71E-lO* 2 38E-I0' 3 41E-10 4.54E-I0 6.74E-I0 9.50E-I0
5.0E+03 2.88E-I0 1.55E-I0' 1.88E-I0' 2_54E-I0' 3 59E-I0 4.74E-I0 6,99E-I0 9_81E-I0
[5,5E+03 3.23E-I0 1.71E-lO _, 2.04E_.I0 * 2.71E-I0' 3 77E-I0 4.94E-I0 '/.24E-I0 I.OIE-09
6_0E+03 3.59E-I0 1.88E-I0' 2.21E-I0 _ 2.88E-I0 3 96E-i0 5.15E-I0 7.50E-I0 1.05E-09
8,0E_03 5.15E-I0 2.54E-I0' 2.88E-]0 3.59E-I0 4 74E-10 6.03E-I0 8.60E-10 1.19E-09
1.OEr04 6,99E-I0 3.23E-I0 3.59E-I0 4.34E-I0 5 58E-i0 6.99E-I0 9.81E-I0 1.34E-09
1.2E+04 9.19E-I0 3.96E-I0 4.34E-I0 5.15E-I0 6 50E-lO 8.04E-I0 1.11E-09 1.51E-09
1.4E+04 1.19E-09 4.74E-I0 5.15E-I0 6.03E-I0 7 50E-IO 9.19E-i0 1.26E-09 1.69E-09
1.6E+04 1.51E-09 5.58E-I0 6.03E-I0 6.99E-I0 8 60E-lO 1.05E-09 1.42E-09 1.90E-O9
1.8E+04 1.90E-C9 6.50E-I0 6.99E-I0 8.04E-I0 9 81E-lO 1.19E-09 1.60E-09 2.12E-09
2.0E+04 2.36E-09 7.50E-I0 8.04E-10 9.19E-I0 i lIE-09 i.34E-09 1.79E-09 2.36E-09
Accuracy: * - Possible Error Greater Than 10%
# - Possible Error Greater Than 100% qp
Chebyshev Fittinq ?arml_eters for Rate Coefficients
Brain =i I.OE+03 eV, iEmax I = 2.0E+04 eV
He
Temp.
(BV) AO A1 A2 A3 A4 A5 A6
1000. -45.5517 i 76637 -,0538507 .0411721 .0121873 -.00162780 4.71335E-04
2000. -44 8184 1 34639 .0940426 .0160336 .0100615 7.61162E-04 -5.25996E-06
4000, -43 9954 993020 .171815 .0181703 .00532378 .00150693 1.33413E-I04
7000, -43 2344 780722 .188817 ,0272646 .00407424 .00107015 2.33342E-04
i0000. -42 6662 678316 .186986 .0320032 .00435983 7.84218E-04 1.42277E-04
15000. -41 8920 588941 .178679 .0346782 ,00461614 3.94516E-04 -9.31127E-05
20000. -41 2236 538493 .169263 .0338729 .00410893 1.87221E-05 -2.35709E-04
Equal Temp. -44 3188 2.21934 -.0710730 .154144 -.0123650 .00522272 -.00149471
See appendix for Chebysl]ev fit details.
D-II7
_i He_* + He ->He _* + He* + e
Maxwellian- Maxwelian
...... Chebyshev Fit
-- Equal Temp.
0.0 2.5 5.0 7.5 10.0 12.5 15.O 17.5 20.0
He_+ Temp. (eV) _'103
,
D-118
, •Single Ionlzatlon Rate Coefticlents for
He + He 2_ -> He_ 4 tle 24 :t- e,
Beau - MaxwetlJan Rate Coefficlents (cm3/s)
He 2+
Temp. He ' 'Energy (eV/ainu)
(eV) 1OO00. 20000. 40000. 70000. 100000. 200000. 500000.
1.OE4-O0 7.33E-11 1.69E-10 9.5"/E-09 ].611:':-08 , 7.'23E-O8 1.27E-0'1 1.27E-'072. Og+O0 3.5OE-10 9 12E-iO 9.31E-09 3 .3"II_-08 8.37E-08 ] •27B-07 I. 2/E-O'l
4,0E+O0 6.77E-I0 i. 78E-O9 8.43E-09 4.44E-O8 8.29E-08 1.27E-07 1.27E-077. OE+O0 8.03E- iO 2. ]OE_09 8.17E-09 4 ,66E-O8 8.17E-08 1 .27E-07 I. 27F:-07
i. OE+OI 8. 258.-10 2.16E-09 8.16E-09 4 ,68E-08 8.13E-08 1.27E-07 i. 27E-072. OE+OI 8.3OE-IO 2. I'/E,-O9 8.18E-09 4.67E-O8 8. ]OE-08 i. 27E-07 i. 2"7E-0"/4.0E+OI 8.31E-IO 2.18E'09 8.22E-09 4.66E-O8 8.09E-08 1.27E-07 ].27E-077.OE+OI 8.33E-I0 2.18E-09 8.26E-O9 4.64E-O8 8.08E-08 1.2/E-07 1.27E-O7I.OE+02 8.35E-I0 2.19E-09 8.30E-09 4.63E-O8 8.08E-O8 1.27E-07 I. 27E.-072.0E+02 8.4OE-I0 2.20E-09 8.40E-09 4.61E-08 8.06E-08 I. 27E-O7 1.27E-074 OE+02 8 50E-lO 2 23E-O9 8.57E-09 4 E-08 8. . ..59 .04E-O8 ].27E-07 1.27E-077. OE+02 8.65E-I0 2.28E-09 8.79E-09 4 •57E-08 8. O]E-08 ] .27B-07 ]. 27E-07I.OE403 8.8OE-I0 2.32E-09 9 01E-09 4.56E.08 8.00E-08 1.26E-07 ].27E-07
2. OE+03 9.34E-I0 2.46E-09 9.68E-09 4 .56E-08 7 .97E-08 i. 26E-07 ] .27E-07
4. OE+03 I.O5E-09 2.73E-09 I. fOE-08 4.61E-08 7,95E-08 1.26E-07 ].27E-077. OE+03 i. 26E-09 3.20E-09 1.30E-08 4.7]E-O8 7.94E-08 1.25E-07 ].27E-07
] .OE4.04 1.5OE-09 3.78E-O9 1.48E-08 4.8]E-O8 7.94E-O8 1,24E-07 ],27E-072. OE+04 2.65E-09 6.33E-09 2.04E-O8 5.15E-O8 7.99E-08 ], 23E-07 i. 27E-07
.Che.byshev Fittinq Parmueters for Rate Coefficients _O
Eml n = I.OE+00 eV, Enlax = 2.0E+04 eV
He
Energy
(eV/ainu) AO A1 A2 A3 A4 . A5 A6
I0000. -42.0879 ].05416 -.278168 .571603 -.178692 .163417 -.0427310
20000. -40,2183 1.05217 -.32" 387 .576861 -,203701 .]:75474 -.05142OO
40000. -:36.7712 .292755 .267684 .0744621 .0454617 .OO691932 -.0]24274
70000. -34.0338 .300282 -.20"7456 .207032 -.108795 .0715453 -.0312105
IOOO00. -32.6844 .00402251 -.0177396 .0232129 -.0175932 .OilerS648 -.01375]9
200000. -31.7707 -.0135888 -.00673208 -.O0257568 -7,31948E-04 -2.50] 36E-O4 -2,83646E-O5
500000. -31.7621 -4. 22604E-O4 -3. 26343E-04 -2. 33365E-04 -1.51845E-04 -9_21185E-O5 -5. 83670E-O5
See appendix for Chebyshev fit details.
O
D'119
QHe + He_+ -> He.++He _+ + e
Beam - Maxwellian
D-120
Double Ionization Rate C,oefflc]ents for
He } He 2_ -.< He 2' -I-He 2'' + e
Beam - Maxwell] an Rate Coeff-I.clent:S (c;m3/s)
He 2_-
'Pemp. He Energy (eV/ainu) '(eV) ' ]5000. ' 20000. 40000, 70000, i00000. 200000, 500000.
I,OE+00 9.35E-11 ' ]. 13E-lO ].86E-I0 ]..74F,-09 I.'73E-09 4.].3E-09 2 09E-092.0E+O0 8.19F,-11 1 21E-]0 3.04E-_I0 ],26F,-09 2.49E-09 4.13E-09 2 09F,-094.0E+O0 8.00E-II 1 22E-]0 3.59E-10 1.05E-09 2.65E-O9 4.]3E-09 2 09E-097,0E+O0 8.00E-].I ] 22E-I0 3,67E-]0 ].O2E-09 2.65E-09 4.]3E-09 2 09E,-.09
].OE+OI 8,0].E-11 1 22E-]0 3.67E-]0 l.02E-09 2.65E-09 4.12E-09 2 ()q_'.L-092.0E+OI 7.98E-11 1 22E-10 3.67E-10 ].,02E-09 2.65E-09 4.]2E-09 2 09E--09
4.0E+O]. 7.81E-11 .[ 22E-I0 3.68E-.[0 ].O2E-09 2.64E-O9 4..12E-09 2 09E,-097.0E+01 "/,50E-!I 1 23E--I0 3.68B-10 .L.O2E-09 2 '63E-09 4.1]E-09 2 09E-09] OE+02 7.25E-]1 _ l 23E-]0 3.69E-10 ].03E-09 2 63E-09 4.11E-09 2 09E-092 0E4.02 6.79E-II* ]. 23E-10 3.70E-I0 1,03E-09 2 62E-O9 4.10E-09 2 JOE-0940E+02 6.47E-II* 1 24E-.l.0 3.73E-]0 1.04E-09 2 60E-O9 4.O9E-09 2 IOE-O970E+02 6.39E-11 'k 1 26E-I0 3.76E-i.0 1.06E-09 2 59E-09 4.O8E-09 2 JOE-091 OF+03 6.45E-11' 1.27E-10 3.79E-10 ].O7E-09 2 58E-O9 4.07E-09 2 ]OE-O920E:f03 6.87E-11" ].30E-lO 3.90E-].0 .[_.[.LE-09 2 56E-09 4.O5E-09 2 JOE-094.0E+03 7.87E-II* 1.3"lE-lO 4'.IOE-.[O 1.18E-09 2 56E-.09 4.OIE-09 2 fOE-097.OE+03 9.41E-]I* ].52E-]0 4.43E-10 ].26E-09 2 56E-09 3.97E-09 2 .JOE-09I.OE+04 I,IOE-IO* 1,69E--.I0 4.78E-]0 1.34E-09 2 58E-09 3.94E-09 2 JOE-092.0E+04 1.66E-I0' 2.34E-I0 6.12E-lO ].54E-09 2 62E-09 3.84E-09 2 ]OE-O9
Accuracy' * - Possible Error Greater 'I'llan .1.0%# - Possible Error Greater Than 100% U
C_he[Tyshev Flttlnq Parmueters for Rate CoefficJ.ents
Eml n = 1. OE+O0 eV, Ema x : 2. OB+04 eV
h,
Energy(eV/amu) AO Al A2 A3 A4 A5 A6
15000, -46.3312 ,153224 .279715 ,]56829 ,0725151 ,0242560 .0070585220000, -45.4317 .231432 .136168 ,105908 ,037929] ,02619022 .00177492
40000, -43,4356 ,345707 -.0276535 ,185072 -.0448587 ,0604026 -.0]8319070000. -41,O648 .0136654 .223879 -.0488164 .O714513 -.0272212 .00699819
I00000, -39.6220 ,082276'7 -.0834305 ,0811386 -.0492265 ,0386945 -.0239545200000. -38.6471 -,0288702 -,O153708 -.00634634 -.O0248827 -8.91443E-04 -4 33357E-O4
, _r ,500000. -39.9659 .00135586 8 97190E-O4 4.168_,._E-04 1.05292E-04 -.2,86625E-05 -6.55320E-05
See appendix for Chebyshev fit details.
D-12]
02+tte + I-te"_+....> t-le_+ + He + e
BeGin ....MGxwellian
D-122
0CroNs _"e_ectiOlls [or the IonJ_zat-J.ol_ oi bi b_' ptotoll llllpact
I-1_ + bj -> II' -t b.|.t + e
,-_ Sleet.lollEllerqy Ve.l.ocJ.t-y tl c _:( ev/a_ilu ) (cm/s ) (_"lu_)
2,5E-t-04 2 20t_-t'08 ]. 20[':]-1 54 OE-t04 ! 2 IBEtOB 1 5()l_-.]{_,7 OE-l04 3 6BE-I-08 4 49E--]61 OE't-05 4 39E+OB 3 22E-.16i 5E-105 5 38EIOB 2 24E-16
2 0Bi-05 6 2].I'.I+08 ] 73g--]64 0 E-I-05 8 78 i]',-I08 9 48 I._- I I7 O g 'II" 0 5 .I ] 6 [_ "li 0 9 [] 7 9 l!] " '.l "7
] OE+06 1 39l']+09 4 2.11])-171 5E+06 1. 7()E-f09 2 9BE-172 OB+06 1 96E-t09 2 36E-17
' 2 3E+06 2 tOEi09 2 :L2B-:I'I
Refersl]ces t 232, 234, I 7, 138
Accuracy i 30%
Note: Cross sections for doLIbl6; iollizat ioll and electi:ou tral]sfer
•._ll--_attol] lllay be fOtllld in Ref. 234.
Chebyshev F'ittirlq Pa r _.uilet e.[ s for Cross Sectiol]s 0
ElÁlill = 2,5E-t-04 eV/mllu, Ellla × --: 2.3Et-06 eV/anlu
AO Al A2 A3 A4 A5 A6
-72.8380 -2.01716 .0360083 .00414961 .00683897 .00418712 .00222666
The fit represents the above c'ross nect:lon wJ.t:h ai] rlus cleviat:ion o1: O.2%.The maximum deviation is 0.4% at: 1.0E406 eV/_uuu.
See appel]dJx for ChebyBhev f:[t details.
D-123
Otq+ + Li--> H* + Li*.+ e
Cross Section vs. Energy•_,...,-14.IU i t i r Li'1 i i'l .... i _,' "T-'--T--'1-'T'I-'I ! I .... I' ---I .... ! i ! i--IT"
10"'5_ _,\/-',. \r_ %
E \\C) X
\c- X
.o "\+--' \ Recommended<P x(b \ -DataOh \\\Or) \(f) \
_O NNXU \\ Chebyshev Fit
10-1 _ \
- \- \
\
i "\
10-17 I _ I i i i l_l.±.l i I i J J llll __L__L_I J l J ii
_o' lo_ lo_ ldEnergy (eV/am u)
D- .L2 4
Oloft[ ZLI_._I.[]II t(t1|'(;9 C!C]E]I'[ t {' [(!_llt f:l [(JL"
l._i t II _ -.> l_d_ .I It_ .t e:;
Te1111:i, I.,.[ F,IIOt_y ( eV/ altltt )(eV) 250OO, 30000, 40000, "10000, 100000. 200000, 500000,
I,()B.tOO 1032E-O7. 2,41B-,07 2 LOE-07 I 651_,.O/ J 411,,-_07 [ 01I!:-O'/ ? 651_;-.O8f p. • z_2,O_+00 L,32E-O'/* 2,41B-,07 2 1OF,-O7 I 6.:H.,-O1 [ _ll_-.()l 1 (_)'ll_-.O'l 1 651_-()B
,. )4 OB-tO0 1 32E-0"1' 2,41F,-07 2 .|01,3-01 J 651]_-O7 I 4L1_-.(7 1 0"11_-O'/ 7 651!I,.OB7 OB'tOO 1 32F,-_O'1' 2,4.11'I-O7 2 lOE-O'l I 65t!;-O7 I 4JF,-07 I 07B.-Ol 7 651_]-()8I OE}O1 .l 32E-07' 2,41t/;-0"1 2 ]OB-O'/ .I 651:_-01 1 411_-0"1 1 07E;-O7 7 6bI_-OB20 _;-tO1 i 32 F,- 0 "1* 2.41 E - 07 2 10 F,- 0 '1 l 6 5F,,-O/ 1 4 .IE- 0 "l 1 07 E-.O"/ "1 6 5I]:- Ot]40g+O1 i 32I_-0'1' 2,41E-O7 2 101!',-07 J 651g-,OI 1 41E-0'/ 10'I!_;-O1 7 fiSt_]-(}Lt70 g +O1 1 3 2;P,,-O7 * 2,4 0E-0 "/ 2 i Ol,:- O"1 l 6 5I!:- OI 1 4 2E - 07 10 "1E- 0 "1 '1 6 5I!;- OBJ OE+02 1 32B-07, 2,37F,-O7 2 lOB-07 1 65E-O7 1 421P,-0"I I O'IV,-07 7 65E-,OB20F,402 1 32B-(}'1, 2.,26E-.07 2 lOLl;-07 1 65E-O1 1 4JE-07 1 (}[JE-O7 7 65E-OE)4 OB+02, 1 32E-,O7, 2,0"1E-07' 2 1OB-Q7 :1 GSB-O7 1,42E..O'/ ] OllH-O7 7 fibl!',-O[_7,O1_;-_02 l 321_-.O7, ] 91_;-O7' 2,0131_;-07 1 651_-.O1 1,42F,-0"/ L 081_-C)7 "1 64B-O8.I,O1!:'t03 ' I 321!_-O7' L t_11",-0"1_ 2,05E-O7 I 65F,-.O'1 |,421,?,-D'1 J OBI!],-O7 7 fbi,-OB2,OE+03 L 33P,-O7. I 66E-07' 1,92E-07 ! 65E-O1 1.42'E.-0'1 1,081_-O'1 1 65E-,OEI4,OE_03 I 33[,I-O7. 1 54E-DT* 1,75E-.0'1' J 64E-O7 1,421!,'-.07 1,O_11_;-O'/ 7 64E-08"/,O1_.t03 I 34E.O'/* 1 41l!;-0'1' 1,63E-07' 1 !i91,7,-O/ .[,411,3-,07 ],OBF;-O'/ 7 641_;..C)8],OB-lO4 I 35E-07_ 1 44E-(V/_ 1 "__ , ,,,J.)l_.-Ol* 1 bbE-O7 J 4OE--(}7 l OEIl?:-()'/ 7 64F,-O8
• l½_2,O!!:+04 I 36E-O-I_ [ 391_-0"I_ 1,,141_-01' ] _13E-O'I .1,3_L,..07 J OlE_(}7 "1 631!',-0B
Ac'_c."lll._lCtyl A _ I'c._r-Jr]lL",le Error C],.:o_l.t-er 'L'han ]0%t_ - I_o_ilylo l_zror (treater 'l'han 11OO%
OCJl_by.'_hev .... [!'ILLIn%., Pa_janlet, e!:a 1o_: Fli._L:,oCoeL[it:tenl:_
ElllJ II "_ ] , OF,-IO0 oV o [!;lll_.IX ::: 2.01_-I04 eV
blEilez'gy(l_V/_mtl) AO AI ,A2 A3 h4 A5 AB '
25000° -:11,6698 ,Ol189'15 , OO'13c]492 ,(JO._b 3"19() ,DOl 19)OO I , 935c)3OE-O4 -I, 14925_1E-O4-1OOOO, -30011686 -,3OO540 -, IO2"187 , O265'i66 ,03755728 4,406"/791_-O4 -,012EI33240(}OO, -30,94_O ' -, 164365 -, ID4B16 .-,O]901lO , O030(16,l1 , O14t]191 ,OOEI12484'lOOOO. -31,2792 -00415flS2 -. O33"1922 - O2J4710 -.,O135033 -, OO5(ID_g? -,OO106044lOOOOO, -3i,5530 -,01OB539 -,O1025_15 -. 00[18"134I -,OO653162 -,OO400398 -,OO213914200000. -32,O9_5 3, "tEIt31091_-04 -I. 5 I'79FilE-04 - 3,5"/4C)'/6E-O4 -,1,43561'1E-04 - 2.,366[13.]F,-O4 - L,O24L41E-O45OOOOO, -32,773fl -8,38(192OE-O4 -5,41'/49gE-O4 -3, O693OHE-O4 -Z, O'15qf3F,-04 - l, 5986LIlE-O4 -6, 145641E-O5
8e_._ appencl.ix tor' (:heby_Jl,ev [ :It: deLal..l,,:n
O
D-'.I, 2 5
QLi + H+-> Li+ + H+ + e
[ m
10,0
7,5 II _t-'r--t--rl'--ffl'-+-H-_-' .' ,...., ;-H_,l ..:.. :e-ft..tr-ft,_'_l,.u_ .... I _,_ , , ''.... ,......__]_ 1 1 ! 1 III
lo0 ld lo_ lo_ lo4 lO_H+ Temp. (eV)
r
D- 12 6
(21.'oi:i_Se(:',t:,l(_ni_.I!c_i:t:hc_.lorl:[_at:.Ltm'_:_iI_,'[by lie' Irm_i° i
He i -r lJJ.-.--.,I.le._ + I.,I.'.ie
t_,nercjy Ve.l.oc:l.t.y Ct'c_s[J Sec't:.i oll,(eV/anl{i ) ( t_lU/U) ( r!lll;!)
8,21_.].!03 .I, 261,;'r08 [, 6"/I_-;I 59,0_-t.03 .[ .32_,t0_3 .1. 661_',-:1.51, O_H-04 :L,39F,+OB .I. 65B-.I5:1.5P,,+04 ;1, "/01_.rO[_ 1 5-li_-:l 52, OI]H-04 .I. [I61_-rOB :1. 38I_-152.5t_.IO,'l 2.20I!',-t08 :I 17I_]-:153,0L_,-t,04 2 411_.r08 9 3.I1.,+-163,41__,+04 2,561.P,.t0l] 7 5,}3I!;-16
, ,
R_e,,,_:e,L,.e!_ce0 L 232, -/39
AOcur_cy!, Unkllown.
Not:eBl (1) !l'he theo[etical crosu _}ect:.ion o.f 'l':l.WaL'y' et a.l., (Re.f, 139)ct,oil t;.:[.riile B to .tilclrease at: elle r(4:i_ s les_ thall ![ 04 eV/allltl, ( 2 ) Tileexper_]luenta_t data oi. DuBo_l.s (Ref, 232 ) .t.lldicate a luaxillttllll irl the (:;reESEIaecttol_ al: 104 eV/ainu0
Cl_.!ebYs[lev I".LttJ.nc I Pal:ametet's £or CroFJs SecLtons
EIII.[I1 = li, 21_t()3 I._V/alllll, I' =: 3 4l!:r04 eV/allltl"lll_IX
AC) A1 A2 A3 A4 Ab A6
-68.5495 -,3583:[7 - , :t41 ].O.l. -, 039136.l -,00786211 ,00262636 ,O0278367
The fit: represerlts t;he above cross section w:lt.h ali rlll_.t devtat:]Ol], of O,0%,The IllaXil]li.llll dev.t.atioil J.s O, I% at: 2,5f_3-i-04e.V/allltl,
See append_t.x for Chebyshev I/li deLaJ.l,,.i,
l_-.:12'1
0He+ + Li -.> He+ + Li_'+ e
o. Cross Sec:tlonv_. Ener9ylC) ,"'-- 17,0 i............. 1-- q T -r
16,0 ....
15,0 -
14.,0 -
_ 13,0 -
c '©
"_ 120 - Recommended_.> DataL,qo9cn II0 -8 '
U Chebyshev Fit
10,0 -
9,0 -
8,0 -
7,0 J 1 l i _1......5,0 10,0 15,0 20,0 25,0 30,0 35,0
Energy (eV/amu) • 10_
Ii- 12 r.I
!
Cross Sect.l(_llt] .[or lolll_aLl.oll u[ I.,.I. by Ile '!_ loll_J W
11o7,0 .r i., I -:-., i+I021 .I, l+.ii 4 B
lJlllnt'c]y Vt-__]cit+1.t:y CtoaS SecLJ oil( nV/allitl ) (cllt/s) ( (Jill<)̀
6 6E.i03 1 13I.,]1(}8 5 621]l-167 01_.103 :1.+IGUIi.O8 6 85B-'.16
':1 £1 Ii_ "t:[ 0_-1-04 .l ..... 08 ] 42l!J_:1.5.H.+'i'04 l 7Ol.i;'tOIt 2 771_-.I.510 it
2 01_-t-04 .i 96E-108 " 3 80U]-;152 4B+i04 2 +I.5E,i()B 4 061_-1b40E-i,(J4 2 781_-iOU 3 02F,-1570U;+04 3 68UIt08 .t 86E-15I Ot&-105 4 39lM'I08 ] 351_-15
. iI <ii 5L,l-rO5 5 381.,+01-I 9 4311J-.162 01-i:-I'05 6 2]I_.r08 7 36,'1!,,-.1640l!;-t-O 5 8 78 l_;-rO8 4011_- 167 o_-ro5 i,;1.61l;.i.09 2 5].II;-1671Ol_J.l.06 .1,39E-I-09 1 841B-].6] r_]+06 .i, 70E-t 09 ] 281_I-16
References!. 232, 234, 264, 731, 735, 737
ACc3n,acyl E > 2x]O 4 eV/alllU - 30%t_ < 2x104 eV/alllU -. UIIkliowil
Notesl (1) The theoret:ica.l, data of Sh.i.pt_ey, lOqt_ al. (Re[, 264) have beenuaecl to extell(:t the exl)ar.l.lllel]t:al r.lata be].c_w 2x eV/allltl, Al; h:l.£ther ellergJ.esthe theoret:tcal data of. this pap_.r are apl:)rox illlat:ely. 50% be.low thee}{pertillellta], data, (2) See Shah, et al, (RetT, 234) [oi: double .[OllJ.zatiolland' t;rallalTer :l.otlJ zatJot],
_#llev Fit, til]el Parameters for Cross Sections
Emtll = 6,6t.,1-l.03 eV/6mlti, Elna× = 1,5E-l.06 eV/allltl
AO AI A2 A3 A4 A5 A6
-69.7410 -].20403 -.864397 ,480069 -.,1716]8 .-.01B]494 .0678290
The fJ.t represents the above cr,oss sections with all rillsdevJ.atlol] of 3.8%.Tile IllaXilllttlll deviat;torl .[s 6+,,5% at 4, OE-t04 eV/allltl,
Bee appei_dt× for Chebysl)ev flt: deta.l.lf_,
ii
l)-129
QHe"_++ Li -> He_+ + Li+ +e
Cr-oss Section vs, Energy10"*-.... , , , ,,,,,,. , , , ,.,,,,, ., , , ,,,,,, , , , ,,.,,,
_, -
("1
Co
+-' ' - Recommendedo 10-15
" Data
0'1Oq
_ -LP _. ..... Chebyshev Fit
- \,
I_ -16_ _ J I IJl_ll I I. i ll_lll l I _ l.lllll [.__L.A_A.A_I_/U
103 104 105 ld ldEnergy (eV/a m u)
D-130
QIoni-,,attnn Rate Coeificients for
bi t He 2+ -> [,[_ -t lte 2_ + e
Be_ll MaxwellJall Rate Coef [i clents (cm:_/s)
He 24
Telllp. Li El]e r gy ( eV/atoll )(eV) 10000. 20000. 40000. 70000. 100000. 200000. 500000.
1.0E+O0 1 97E-07 7.45E-07 8 39E-07 6.84E-07 5.93E-07 4.57E-.07 3 27E-072.0E+O0 1 97E-07 7.45E-07 fl 39E-07 6.84E-07 5.93E-07 4.57E-07 3 27E-07
4.OE+00 1 97E-07 7.44E-07 8 38E-07 6.84E-07 5 93E-07 4 57E-07 3 27E,-07
7.0E+OO 1 97E-07 7,44E-07 8 38E-07 6.84E-07 5 93E-07 4 57E.-07 3 27E-07I OE+01 1 97E-07 7.43E-07 8 38E-07 6.83E-07 5 93E-07 4 57E-07 3 27E-07
2 OB+Of 1 97E-07 7.42E-07 8 37E-07 6.83E-07 5 93E-07 4 57E-07 3 27E-07
40E+01 1 97E-07 7.40E-07 8 37E-07 6,83E-O7 5 93E-07 4 57E-07 3 27E-O7
70E_OI 1.98E-07 7.39E-07 8 36E-07 6.83E-07 5 93E-07 4 57E-07 3 27E-07
10E+02 1 98E-07 7.38E-07 8 36E-07 6.83E-07 5 93E-07 4 57E-07 3 27E-07
20E+02 20IE-07 35E-07 8 34E-07 6.83E-07 5 93E,-07 4 57E-07 3 27E-07
4 0E+02 2 06E-07 7.32E-07 8 32E-.07 6.83E-07 5 93E-07 4 57E-07 3 27E--07
70E+02 2 ]3E-07 7.28E-07 8.30E-07 6.83E-O7 5 93E-07 4 57E-07 3 27E-07
i OE+03 2 20E-07 7.23E-07 8.28E-07 6.83E-07 5 93E-07 4 57E-07 3 27E-07
2 0E+03 2 44E-07 7.12_;-07 8.23E-07 6.82E-07 5 93E-07 4 57E-07 3 27E-07
40E+03 2.87E-07 6.95E-07 8.15E-07 6.82E-O7 5 93E-07 4 57E-07 3 27E-07
7 OEr03 3.38E-07 6.81E-07 8.03E-07 6.81E-07 5 93E-07 4 56E-07 3 27E-07
i OE+04 3.77E-07 6.72E--07 7,89E-07 6.79E-O7 5 93ff,-07 4 56E-07 3 27E-07
2 0E404 4.63E-01 6.57E-.07 7.52E-07 6.72E-07 5 92E-07 4.56E-07 3 27E-07
Chebyshev Fittillq Parameters for Rate Coefficients
Ellljl] = I.OE+00 eV, Enlax = 2.0E+04 eV
Ene,rgy(eV/amu) AO Al A2 A3 A4 A5 A6
i0000, -30.4517 .363146 .218568 .0797980 .00504386 -.0143333 -.O104786
20000. -28.2941 -,0576610 -.0273357 -,00812937 3.616003E-04 .00260866 .00171889
40000. -28.0291 -.0386370 -.0241107 -.0131556 -.00664902 -.00299352 -,0010207]
700OO. -28,3978 -.00517514 -.00356459 -.00231958 -.00145198 -8.487303E-04 -4,870846E-O4
100000. -28.6764 -3.661189E-04 -4,106187E-04 -3.730240E-04 -2.606518E-04 -1.714793E-04 -7.710836E-05
200000. -29.1978 -8,8).4731E-04 -6.105531E-04 -].205126E-04 -7.285731E-05 1,063444E-04 7.216290E-O6500000. -29.8691 1.603658E-04 -9.V79805E-05 -3.895455E-05 -5.564509E-06 2,962654E-06 -4.029762E-07
See appendix for Chebyshev fit details.
D-131
, Li + He_+ --> Li" -t- He2+4- e
@E. Projectile Electron Loss or Stripping Cross Sections
(* denotes rate coefficient data also)
Page
H + H -> H+ + H + e ............ E-2
H(2s) + H(is) -> H + + H + e ........ E-4H + H2 -> H+ + H2 + e ........... E-6
H(2s) + H2 -> H+ + H2 + e ......... E-8H + He -> H+ + He + e ........... E-J0*
H(2s) + He -> H + + He + e ......... E-14
He + H -> He _ + H + e ............ E-16
He + H2 -> He + + H2 4- e ........... E-18
He + H 2 -> He 2+ + H2 + 2e .......... E-18
He* + H2 -> He or He + . .......... E-20
He* + H2 -> He + + H2 + e ......... E.20
He* + H 2 -> He + H2 ............. E-20He + He -> He" + He + e ........... E-22"
He + He -> He 2_ + He + 2e .......... E-22
He + + H -> He 2_ + H + e ........... E-28He + + H2 -> He 2_ + H2 + e .......... E-30He + + He -> He ;_'++ He + e ..... E-3 *
E- 2
Projectile E]ect1:on Loss or Stripping Cross Sect ions fol;
H + H -> H" -t- H + e
Energy Velocity Cross Section(eV/rural) (cres) (cre2 )
i. 2E+O3 4.8]E+O7 2.89E-182.0E+O3 6.2]E+O7 ]. 501_-174.0E+03 8.79E+07 3.65E-176.0E+03 i. 08E+08 5.22E-177.0E+03 1.16E+O8 5.87E-17i. OE+O4 i. 39E+O8 7.68E-17i. 5E+04 1.70[5+08 i. 07E-162. OE+O4 i. 96E+08 I. 26E-164. OE+O4 2.78E4 08 9.64E-177. OE+04 3.68E+08 7.35E-17i. OE+05 4.39E+08 5.98E-171.5E+O5 5.38E+08 4.49E- 172. OE+O5 6.21E+08 3.57E-174.0E+05 8.78E+08 1.96E-177.0E+05 I. 16E+O9 1.27E-17I. OE+O6 1.39E+09 9.67E-18i. 5E406 ]. 70E+O9 7.08E-182. OE+06 1.96E+09 5.76E-183.5E+06 2.59E+09 3.88E-18
References: 33, 34, 209, 296, 297, 298, 299, 300, 301
Accuracy: 20%
Note_._.__! To our knowledge there are no known experimental ionization crosssections for H interacting with H atoms.
C_.hebyshev Fittin¢ Pareuueters fol_ Cross Sections
Eml n = 1.2E+03 eV/rural, Ema x = 3.5E+06 eV/ainu
AO A] A2 A3 A4 A5 A6
-77.1794 -.451408 -].51760 .543975 -.0355154 .00258954 -.0750900
The fit represents the above cross section with ali rms deviation of 8.0%.The ma×imum deviation is 10.3% at 7.0E+03 eV/amu.
See appendix for Chebyshev fit details.
O
E-3
0H +'H -> H++ H + e
-_' Section vs. Energy•t,--,"15IU _ _ , ,_,_t l"'_"i"_'"r'r_ , _ _ _,_1 '_ -i'_ __u
1_;- 4
Projectile Electron [,oas or Strlpp].ng Cross Sec;tJ.ons ]or O.
H(2s) -i .H(]s) -> H_ -, H 4- e
8nergy Vel.oc.lty Cross Sect: .ion( eV/aJI1U ) , (C111/S) ( till 2 )
5. OE+03 9.82E+07 2,24E-]66.0E4-03 1,08E+08 2 39E-]67.0E+03 I,]6E.I.08 2 5]E--]68.0E+03 ] 24P_+08 2 62F,-]69.0B+03 i 32E+08 2 69E-16
1.01_+04 ]. 39E4.08 2 75E-]61.5E+04 I 70E-I08 2 95E-]6
2.0E+04 ]. 96E+08 2 94E-163.0E4.04 2 41E+08 2 60l_-164,OE-I-04 2 781_].08 2 291_-165.0E4.04 3 11_]-t-08 2 10E-166.0E+04 3 40[_+08 1.99B-16
7,.OE+04 .,'3.68E+08 ].91E-]68. OE+04 3.93E-108 ] . 84E-169. OE;+04 4. ] 7 E.I.08 l. 79 _].--161. OE+05 4.39E408 1 ,74E-] 6
References' 33, 285, 302
Accu_acy: Unknown
Note: The experimental data t]f I Hi].], et al. (Ref. 33) have beenextrapolated from 20 keV/ainu to I00 keV/ainu using tile theoretical data ofAbr.l.nes and Percival (Ref. 285), and Prasad ancl Unllikrishnan (Ref. 302). IIn the energy range of overlap the experimental and theoretical data agreeto within 25%.
C!!ebyshev Fittinq Parmneters for Cross Sections
Eml n = 5.0E+O] eV/mnu, Ema x : 1.0E+05 eV/mm!
AO AI A2 A3 A4 A5 A6
-72.0121 -.164818 -.174972 .0460650 .0293401 -.00879104 -.0113468
The fit represents the above cr0ss section with all rnls deviation of 0.4%.The maximum 'deviat].on is 0.5% at 4.0E+04 eV/ainu.
See appendix for Chebyshev fit detai].s.
0H(2s) + H-> H+ + H4- e
Ct-,,'_sSectio_-_vs. Energyi©_ _ , /* 30,0 T _ ,- _ i , , _'1 ...... ' , -r w _ i ,
]28.0 \ -
/ \/ \
26.0 - / -
E /""24.0 - / ""LT_0
'-_(bO a/ / --DQtoRec°mmendedoo22.0 - -
L Chebyshev FitU
20,0 -
\\
18,0 '_'
16,0 _ 1 1 1 1 1 i 1.11 I 1.... 1 1 1 I 1
_o_ lO• lo_Energy (eV/am@
I_-6
AProjectile B.1ectron l.,of;_£_ or St._:.[p|_Lu£1 C.ro_]t_ 8e..(-_t:.t.(:_11t_ for
H-r [I 2 -._ tl o -t. II;: -r e
F,nergy Ve.1.oc_lty Cross S_,r;t:lon( eV/_uml ) (cm/a ) ( c_m")
6.0 F,.t 01 t, 081_-t D7 :1. :t 7 F.;- l 97.0 E-t 01 1,16 UI.t 0 '1 .1.. 9 .[B-- 19]., 0 t_+02 ], 39 [{;+07 5,24 I]:- ].91,5F.,+02 ]. 70B-t 07 .l. 37_-182. Ol_.',-t'02 ] 961!:-1.07 2.39E-.184.0B+02 2 78_'t.07 8.32B-.I.87.0 t_4.02 3 68 .P,'t-07 2.09 l!:- ] "11.0 _;+ 03 4 39 P,+[)7 3.37 I,_-171.5E-I.03 5 38F.4.O7 5.08P.-]72, O[_+03 6 2 ] I_-t-0 7 6,36 F,- 1 I4.O1_4.03 8 79E+07 8.631!;-]77.OE+03 1 16[_.r08 9.09l_-171. OB-I.04 i 391_-I.08 9.21B-.171.5_;+04 1 70_-r08 ].O6E-:162,0 E-t 04 1 96 _:+ [) fl ,!.. 36 E- .164.0EI04 2 78EI-08 ].54_:-167,3E4.04 3 7.5E-t08 1.34l!:-.161. OE+05 4.39E408 1.10E-16'1.5_;-105 5 38E-r08 8.611_-172.0B+05 6 21E+08 7.O41_-174. 'OE +05 8 78 l_:-t08 4.20 I]:- 177.OB+05 1 16E+09 2.63B-171.O_]-I06 i 39F..:i09 1.91F;-].71.5E+06 .1 7OE+09 1.30_.;-]72.0E4.06 ] 96F,+09 9.741!;-].8
4,0E+06 2 77E+09 4.60E-187,0_:+06 3 65_+09 2.46B-.[81. OE+07 4.36E.r09 1.65I.,_,- 181.5E-t.O7 5.32E-t-09 1. O2B-182,0 E +0"I 6.11 B+ [) 9 7.34 i,.I- 19
References: 26, 27, 28, 29, 311, 33, 3"1, 45, 47, 49, 51, ]43, 269, 270,296, 298, 299, 301, 303, 304, 305, 306, 307, 308, 310, 313,315, 316, 321
Accuracy: 30%, , .
Note____!_ Many Ii]vestJ.gators have been lllvolved iii these llleastl rellletlt: 8.Consequently there .is large scatter in the data, but most: of t:hemeaeurement:s are within the quoted accuracy of 30%.
Ch.ebyshev Fittlnq Parameters for Cross Sections
EIII:[FI = 6. OE+O1 eV/alllLI, [_lllax = 2. ()I]:-t.O7 eV/alllll
AO AI A2 A3 A4 A5 AG
-79.0892 .346403 -3.04496 .508490 -.0"15866] ,108006 .O0593450
The fit represents tile above cross _]ect:_on wJ.tll an rl]ls dev.lat::l.o_l of 10.7%,The ma×J.mum devlat:lon J.s 29.8% at: l,Oi_;-t.()4 eV/ainu.
See appencl]x _or Chel._yshev fJ.t: clet:a.Lls. 0
iI
_-7
0 H ,Jr- Mi2 - > Pt+ + H2 + e!
, (....% _ 4,.Cross . e.ctlonvs. Energy10-15---_.-I-T-ITI-ffI_TTT-TITf_TTI_F---T--1--rI-FNIF--r-IL i i1 ill I - TTTrlTI_----T--FTT1T[
10-1C ," y,c__,,:- . .,s__.,- X .
I_1E - I ,_ ,
,,p 17 Recommended10- - _ Data
@ - ju_ F-
0 ...... Chebyshev FitU
10-_E
10-_ __L__W__uL.L_LU_U_--4-LLU_--LU_ld lo_ lo_ lo' lO_ lo6 lo_ lO8
Energy (eV/am@
Pi:OjeCt ]. te l_;.1f:H:!t l:'iJll l.,tlti0 Ul: 81:.r I.pp:l Ilg (:_it-iI:llJ _(:._c!L.lciilll 1!01. O
H(2ti) .t. 1.1;_ -> II _ .I I1,, i {;
.. , 71ciLi:lie i:{]y Vl{!.l o1:I.II:y ' Cl(ltlfl Cl,q.tll'_) [: t iiii( nV/allltl ) (C,'lll/[I ) ' (
5,01_.t,02 ,3, .1:1li',.t07 6° 141!1-] 77 0Bi.02 3, CiSgi 07 1,091_:-.J 6j Og.i.03 4° .]91!;.t07 .I, 901#l-.1.6i 51!H.03 5o 3ij1!',.t07 2 F]91!I-]62 0B+O] 6 2:[l,.I-t(i7 3 331!I.-164 01_-t,03 8 '19I!H.O'I 4 05iii.-:| 67 C)B-i.O] I 161!',.t-08 4 361!:,-[6] OB-t.04 1 391!',.t08 4 501!l-.16I 5B-t-04 1 701._;-i08 4 G3B-I62 01!;+04 J 96B-r08 4 761!:-:164, OB+04 2 781!H.0[I 4 0()I_:-.I 87 0 t:I-t.04 3 6 8 I!',:t.08 3 0 C)l!:- :16I 01_-t.05 4 7-19t_.t-08 2 481!',-.l.GJ 51_-105 fS 3 81!I:108 1 95g-J620IP,-tO5 6 2J1_.108 :1 591_-.16
4 0 !_',.t.0 5 8, 18 l_t C)8 9 56 I_-..1750l_t05 9,821!;i08 8 131_:-:11
Re£_r_llCgBl 21, 33, 3C)6_ 326, 321, 328, 329, 331, 3:12
AccU_;ac78 bO_
Rotel Due to the uiu::el:l;a.tnt.t.en :tn lilr:,attul"_t.nc I t:he 11(2s) lliet:astab.lo [:r'ac, t:t.oll_
tl_-T_erl:ol:.B .[I1 IlleaBtlt':[llC] the croo._ tlOet::[OllS Illay l)rj .[attie0 O
c l!ebv_ilev lq.tti.jle,.1 l,at_mlet;ez:<,;_ .{:o.t C;l:o_t_ 8ETCLIoIIB
= " = 5 C)I!H.O5 eV/alllUl}:lll.J.11 500lgtO 2 nV/allltl, l],llla× ,
A0 A1 A2 A3 A4 A5 AG
-72,3651 -,0686522 -, 93907"I ,1606"I0 -,0746703 ,07].4502 -, OC):]10"138
The fit repreBentB tile at)ow_, croafl aec:t.t.oll w.t.l:h an i;lllf_i devJal:.l.oi] ol 3.2%,Tile maXilllUlll deviation .iB 7,()% at 7,0P,.t.O2 eg/aniti,
See appendJ.x [or Chebyshev [].t. det, a.l. ls,
t-l(2s:)+ t-I2 -. > H+ + t-I_-t-.e
r,I
c0
_ 10-I__ Recomrnended
_ ..... Data(,/3
,_.
_- ....... Chebyshev Fit
10 17 1 1 I IIIJ_L!, I ..L__L_Jliil! L__L_L_Li!!II 1_ J I ILU.[
•1o_ lO_ lc; lo_ lo_Energy (eV/am u)
II_-,J0
Ol:'l'o21(_(:_k.] iii], }!',JLH:!t;1:(.)II I.,()UFI tit' Sl. t' [I]l) lllt2J C:I(')HH _il(_(_;t;.I()IlH [(:_t'
Ii I II(, ...> li' .I Ilo .i f,
l!_ll_ rgy Ve]*oo.l L.y Ct:o_IE1 ,_ti.,.(_t..l,m(c_,v/_LmL) ((mWd..1) {cml;')
50E-I'OJ .el [l"_i_,I_,106 2 251!',.-'19' 7 0 l!','l'01 ;I. L OI_:.¢,07 !J 2 'I I!;.,.I.9
'I Olg-lO2 1 39F, i.07 I (}BI!I-Ill20L_-I.02 ii 961_,l.0'1 i] 4_)m,L,-.,184 01_.I.02 2 71lE00/ !J 541!I-.II]/ O1!1.1.02 il 131]I_.}07 2, 061_;-.I./I ,lD- (}3 4 39E.I0"1 ]-I 311!:-172 0 l._-t0 3 t'_, 2 .L[!_.t 0 '/ (i 8 .Ilg- ] 74 OB'I'03 I] 79E-I0"/ L ()'11_-..167 OB I'03 [ .161_I08 :I 28Li',-.16
• i_I. 01!',104 .I 391!]-I 08 I 331.,- 162 0L,I+04 ;t 9{:iE-i08 I. 301_-.I.64 01]',-t04 2 '18E't-08 .I 2.LI!l-ii 6
. i'70F,;-t.04 3 681.,t08 ii 051!;-./6.i 01]_-1.05 4 39E.I0|I [J "l "/I]',.-.L"/2 0 t_-i 05 6 2 .I I!:t-08 5 4.1.Ill- .I '14 0L,G-t.05 8 78l,.1+t.08 :J .I 2l_.- I'l70Bi(}5 I ]61'1409 J. 9]lf',-.;l/;[ OE-t06 I 39E-I.09 ' .I 3{iE,-.[72 01!]-i.()6 .l. 9fll'.i.t,09 "/ 201_--;184 01_',+O6 2 77 l!',.r09 3 68 I!',- .I.87 0W:i-06 :1 65L,;.i.09 2'.1.3l]',-181 0B+07 4 361:I-i.09 .1 49E-]8li<, 0 IZ,,'i-07 6 ] ;1E-i'09 7 3 ;l E .-19
iRe_.._{__aJl 26, 27, 28_ 29, 47_ 49, .51t .I03_ 268, 269, 270, 286, 287, 296,
299, 3000 303, 30"I, 309, 3;13o 314, 3116, 3;17r 3.1.8 o 3J9, 32(Ji32.11 322
NoLO_J I No I 11:"
_, .e_b_7'f-]1'lev FJ.I; I;.1llq P,_ii _illiO1:a l; l_i .[ol; tT,r o i_l_i Secl: l.oi'i_
Flll:l.ll = fS, Ol!;-i 0;1 t.-:V/allltl, I.,111_1×_'= 2 ,01!:t'O'/ (-:V/_UlItl
AO A1 A2 A3 A4 A5 A6
•-79°0638 ,101432 -2,86460 ,47/4!J.I ,09t]99413 -,0319510 -,0136"105
't'llt_ .[ .li: I'.'(-.,|;lI.eEl,!_llt:li t:lle _ibc_vt:_ (:!l(;HJ[i f.l_,(.'l.J (iii w.l.t;ll _lll I lIKI d_:,vJ_ll;;l.ori ()l: 4 ,'/t,,'l'h_ lll_tl(:[llll.ilil dev.l._lt; ioii li]_ 9, c)% _.il: 2,, I)l!',iU4 (_,V/l:illlti,
_e[# _lpl:)ellcll × f.r_r Cllebyflhev l' Lt clet:_l.i l,,l,
.,,:L.L
'0H-F t-le -> H* + t-le + e
C:l--_css-"Section vs. Ener-gy10-'5
--l-[irl-rlr---r--r-T'TTrtTl---'i-l"T_iml-_w i i i'rITIF---r-rTrTITI1 _ t I rTTI'TF-'-T-'T_TITr
10-'__
_E(D
c-O '
,_ t7 Recornmendedo, 10- -'® : .... Data
_ _ ,
0 _ Chebyshev FitU
10-'E_
10-1_ _ !lllllll. 1 l illiiii i f lllliil i t lilllll i i illilll i i liillll J-,L,L.LJ.JJ
_o' lo-_ .io_ lo' lo_ lo_ lc# lo'Energy (eV/amu)
®
i
I.'_-]2,,
i
, ProJect:L.Le 1311ec_,tt.or= 1+,o_1 c')r BLrJ.I_p-I nq Rat'(-_ (.c)_."-,,[f t(" I ehi:r:+ for: 0
II + l.lc_ -> H+ +I. I+Io -i. o
Mc-tgwe]J] all - Ma×well ian Rate +,-_t_e[.[ic,'JenLtJ (Clli3/+:i)
I!
Tolnp, Etltla ] ll[_ 'l't+mp, ( eV )( eV ) 'Pomp, 1O, t O0, _00, t OOO, 5O00, t OO00, ,',OOOO,
I,OE+O] 2,;9E-13g 2+?.9E 13# G IOE-12 A I,O9E+.IO 3,69E-10 3,tifF,-09 7 601+-O9 1 3Ol,",-Otl
2,0E+OI 2,53E-12 A I,[I6E-'12" 1 ,I,9E-11 1.25E-10 3,94E-tO 3 lldE-09 "! 69E-Eq 1 30E-Ofl
4,0E+O1 1,40E-1l 9 69E-12 : ;] 48E-11 1 60E-lO_ 4+47E-LO 3 91E-09 7 ldE-09 1 30E.-086,OE+OI 3,35E_Ii 2 28E-II d 34E-II 1 9tll.,l-lO 5,01E-lO 3 9fE-09 7 80E-09 t IIE,-Ofl
8,0E+01 B,OdE-I.I 40flE-tl 6 6dE-LI 2 dOE-lO 5,58E-10 4 05E-09 7 fibE-09 i ]IE-,Ofi
I,oE.,02 9,38E-11 6 33E-11 ' 9 3lE-11. 2 fdE-lO 6,16F,_10 4 12E-09 1 90E-09 1 3.1E-Ofi
' 2,0E+02 3,44E.-10 2 35E-10 2 fdE-10 5 ddE-IO 9+;17E-10 4 46E-09 f 16E..09 1 33E-Of
4,OEr02 1,09E-09 7 76E-.10 fi d7E-IO l 18E-09 .1,62E-09 5 lP.E-09 8 riTE-09 1 36E-08
6,0Et02 1,97E-.09 I 45E.-09 1 5.]E-09 I 88E-09 2,34E-09 5 76E-09 9 15E-09 I dOE-OB
8,0E_02 2,fifE-09 2 16E-09 2 "+5L,_E-09 2 61E-09 3,06E-09 6 36E-09 9,62E-09 I 43E-08
I,OE_O3 3,77E-09 2 [19E-(}9 2 97E-09 3 33E-09 3,'17E-09 6 gSE-09 ] OIE-08 1 46E-Ofi
2,0E¢03 7,6dE-09 6 _2E-09 6 29E-09 6 58E-09 6,95E-09 9,50E-09 I 2LE-Off I 60E-Ofi
4,0E¢03 1,30E-08 I IIE-O_ 1 12E-08 ].,14E-08 I,16E-08 1,34E-08 1 53E-08 I 83E-Of
6,0E¢03 1,66E-Ofi 1 46E-Ofi 1 d6E-08 1,48E-Of 1,49E-08 1,53E,+08 I 7fiE-08 20JE-Ofi
8,0E_03 1,93E-08 I 72E-.Ofi ,I 72E-08 't,'/'.IE-Ofi 1,75E-08 1,86E-Ofi 1 9[IE-Ofl 2 lgE-,Of
I,OE+Od 2,15E-Ofi 1 93E-Ofi I,gdE-O8 1.95E-08 1,96E-08 2+05E-Of 2 [5E-OR ,_33E-Of
l,SE+04 2,55E-08 2 33E-08 2,33E-08 2,34E-08 2,35E-Ofi 2,4_E-0EI 2 48E-08 "261E-Ofi
2,0E+04 2,81E-Ofi 2 6]E-08 2.61E-08 2,61E-08 2+62E-08 2,66E-08 2 71E-C)8 ._fIE-OB
Accuracy| * - Possible Error Oroater Titan 10%li - Possible Error Oreate[ Thai] 100%
CllebysJ)ev Fittinq ParameLers l.or Rate Coefficients
F'nlJn = ], OE+O.1, eV, I+'.,toa× :_: 2.,.OE-t-O4 eV
Fie
Tflllp,
(sV) AO AI A2 A3 A4 A5 AO
IO, -.44.O257 5,7[_463 -I,21932 ,0247503 -,0292957 ,O6193"13 -,0219438100. -42.5585 4.48698 -,446257 -, 330879 ,0963611 ,025'/805 -.0137058
500. -40,6373 3,03270 ,121fi04 -, 344684 ,00515230 ,0559/]08 -,0081 ]670
1000. -39,6384 2, 349"72 ,269827 -,258791 -,044091fl .0450062 ,0055061"2
5000. -37.3658 1.00814 ,315318 -,0289392 -,054399fi -.00704923 .00822057
I0000, -36,5490 .622335 .247753 ,0221122 -.,0286150 -,0130702 4. 392519E-04
20000, -35,8634 ,357047 ,16(]697 ,03711094 -,00809424 -. 00961fi02 -,00307060
Eqtlal Tslup. -43,5995 5.668"12 -1,35443 ,I09s172 --,0570829 ,0"16644 l -,0349995
See apperldJ× [!or Chebysllev flt: clet:a:ll[:.
E-13
iOl H + He ">H* + He +e
Maxwellian Maxwe lian
I ,i ' I I i I III I 1 I I I illi I I I"'"( I"-I'Tlil :He Temp.
(eV)
lO_a A --10.
x --100.
Chebyshev Fit
10-':Equal Temp,
10-':ld 1# I8 104 10s
H Temp. (eV)
O
E-14
@Projectile Electron l_,oss or Strlpplng Cross Soc'I-Ictus for
H(2s) 4 He -> H + + He + e
F.nergy Velocity Cross Sectiol](ev/ainu ) (c.!/s) (cm2)
_'i 5. OE+02 3. lIE+07 3.08E-177.0E+02 3 •68E+07 8.29E-171.0E+03 4.39E+07 i. 37E-16I. 5E+03 5 o38E+07 i. 94E-162.0E+03 6 21E+07 2.39E-16
4.0E+03 8.79E+07 3.28E-167.0E+03 i. 16E+08 3.42E-16i. 0E+04 1.39E+08 3.42E-16I. 5E+04 1.70_;+08 3.32E-]62.0E+04 i. 96E+08 3.07E-164. OE+04 2.78E+08 2.23E-167.0E+04 3.68E+08 I. 61E-] 6]. 0E+05 4.39E+08 ]. 26E-16i. 5E+05 5.38E+08 9.97E-172.0E+05 6.21E+08 8.78E-17
4. OE+05 8.78E+08 6.97E-175.0E+05 9.82E+08 6.72E-17
References: 29, 324, 326, 327, 329, 332
Accuracy: 50%
Note Due to the uncertainties in measuring the H(2s) metastable fractionthe errors in measuring the cross section may be large, For energies lessthan 1 keV/amu the data should by used with caution.
Chebyshev Fittinq Par_neters for Cross Sections
Eml n = 5.0E+02 eV/6um], Ema x = 5.0E_05 eV/ainu
AO A1 A2 A3 A4 A5 A6
-73.2008 -.0"752112 -.927667 .363861 -.0349147 .08236627 -.0565338
The fit represents the above cross section with an rms devlation of 2.6%.The maximum deviation is 4.8% at J.5E+03 eV/amlu.
See appendix for Chebyshev fit details.
@
E-15
i
• ,H(2s) + He -> H. + He + e
Cross Section vs. Energy
10-151 , , , ,',,,,i , , ' '''"I , , , ,,,ulj' , , , ,,,,,
- F" "\Eo
c- / \\
o 10-16 / \ \,,, Recommended(.p \
@ - ', Dote- \\\,
cn - "-_or)0 -"
...... Chebyshev FitU -
- t
10 -13 I I i llllil 1.1 I llllll _ i I II1111 i i 1 llllL
,102 10s 10" 10s 106Energy, (eV/o m u)
I _ -- _1. 6 l
Projectile Electron l,oss or Stl:Ipl)il_{ Cros_ Sections [or I
I-le -t H -> t.le_ t. H 4. e
Energy Velocity C ro,'_s Section(ev/ainu) (cm/s ) (cre_)
5. OE+04 3. l]g108 1.56E-166,'0E+04 3.40El 08 1.42E-] 67. OB+04 3.68E-I 08 ]. 3 iN- ]68. ON+04 3.93E+08 ]. 23E-169.0E+04 4.17E-t.08 ] ; 15B-16i. OB+05 4.39E+08 ] .09E-161.5E+05 5.38E+08 8.49E-]'7
2. OE+05 6 21E+08 6.87E-]73.0E+05 7 61E_ 08 4.80E-17 "4. OE+05 8 78E+08 3.68E-]75.0E+05 9 82E+08 2.93E:]76. OE+05 ] 08E+09 2.44E-]77.0E+05 ] 16E+09 2.07E-17
8.0E+05 ] 24E+09 I;85E-179.0E+05 :1. 32E+09 ].65E-17i. OE+06 ] 39E+09 ] .49E-]71.2E+06 1 52E_09 1.23E-]7
References: 301, 398
Accuracy: 15%
Notes : None
QChebyshev Fittinq Par _,eters for Cross Sectxons
Eml n = 5.0EI04 eV/m_lu, Eiuax = 1.2E+06 eV/amlu
AO Al A2 A3 A4 A5 A6
-75.0809 -1.28466 -.136342 .022920 .0]44810 -.00700300 -.0037'7068
The fit representsthe _{bove cross sect:ion with an r,lls devlat]on of 0.4%.The lila×imunl deviation is :1.3% at: 7.0E+05 eV/aluu.
See appendix for Chebyshev fit det:ai]s.
B-17
0He + H -> He+ + H + e
Cross Section vs. Energy, -15I0 ' ' ' "' '' I -- " , , '"r", , , ,, 1 , ,' ,'", , rTr-
l"q
',.,..,I • '%
C:: "",
",Nx,_0. -I_+_ lo \ Recommendedo __ -
© - Data(.,009OO0 ""k_CP _ Chebyshev Fit
s
1710 - , _ , , i __ , ,_j_1 1 I 1 llJ_ 1 I I111
104 10_ 10e 10'Energy (eV/ainu)
_:-ii.8
SingJ.e and Ooubl.e ProjO,c.t.i..lel!I.lect-rort bo:3v oy: St:vIl_l)IVlclCro::IN S_:,t"t,l.c)n,q [oy
lie ! H2 -> lte} H:! .f e oOl
Fie t tl 2 -> tie ;!' I t.I2 .r 2e Oo2
(Ool) (Ooe)
Energy Cross Secti.oxl Energy ,C,ros,_ Sectioz](eV/ainu ) (cre_') (eVlamu ) (c:'.mz I
5,0E-I.02 9.96.E-]9 5 [)I!i+04 2,591'.?-]87.0E+02 2..13E-18 60E-I04 3, 1.4E-.I.[_;I.0E+03 4.68E'-.18 7 01;]+04 3.5].E-]81..5g+03 9.24E-.18 80[';+O4 :1.78E-182.0E403 1.33t!]-[7 90Et-04 3.98E-18
4.0E+03 2, 13E-] 7 10L_-t()5 4 .i07[_- 1.[ai7.0E+03 4 261;I-17 I 2E+05 4. I01_-18]. Ob]+04 5 33E-.1I l !:_E-I.05 3.93E-]_8].5E404 6 75E-17 20E-i-05 3.46E-].82.0E+04 '7 93E-[I 3 og105 2.44E-184.0E4.04 ] liE-J6 q OE+05 1.75E-1870g-t-04 1 27E-1.6 5 OB+05 1.31E-18I og+05 ] 23E-].6 6 og+05 1.09E-181. 5E4-05 [ 08E-16 l 0E_05 9.38E-]920E+05 9 38E-]7 80E+05 8.21E-.I.94 0E+05 6 08B-..177 OB+05 4 O1E-]I10E+06 3 C)0E-17
Ref e_rexlues : (Single St r.tpp.i.llg) 94, 97, 99, 102, 103, 143, .1.98, 3C)I, 3]61399, 400, 401, 402, '403, 404, 405, 406,
407, 408', 409 If'(Double Stripping) 400, 405
Accuracy: o01 .- ]5%
o02 - Uilkilown
Notes: (;I) The strippi.rlg cross sections are measured [ii two ways: (al ' bythe att:enuation Of tl,e He benton .i_lt:he H2 gas eel.l; (bl by the fornlatilon of
He + .' Tile attezluation method gives tile sl.llllof tile slngl.e and dotlble
stripping cross sections. Since tile double-strippirlg cross section J.s atleast a factor of 30 ].ems than that for slrlg].e-strJ.ppivlg, the two methodsgive the s6mle cross sections w.l.thivl the measurement errors. (2) The datafor double stripping do not pe£_nl:[t ai] error eva].uat]orl.
Chebysllev Fittinq Par6ulleters for Cross sections
o01 Eml n .= 5.0E402 eV/ainu, l_luax = I. ()E-I-O6 eV/ainu
002 Eluin --_ 5.0E+04 eV/ainu, Ema x ::, 8.0E+05 eV/anlu
AO Ai. A2 A3 A4 A5 A6
°01 .-76.5'793 ]. 584'18 -I. 39950 .0531448 -..0845579 .089 10.12 .023 ].543
°02 -81. 3261 -.669570 -.425168 .091 ] ].I'I .O266527 .00757867 -.00546826
The fit represents the o01 cross sec.:t.ioil with an .rms cleviat]on of 2.5%,
The maximum deviation ]_,i; 5.4% at 1.0E-t02 r:V/amtl.
The f :i t repr'esent:s the o0_ c.:,)c_,:_s sect_].c))l wJ til atl rms devi ati on oti 0.7%.The maximum dev.i, at:i.oll i.s 1.8% at 5.01:;r05 eV/ainu.
• •See append] x for C:lleby,_llev f i t. cleta i ] s.
E-19
OHe + H,.-> He+ + H2 + e _c_o,
He+H_'-> He_+ +H_+2e Cro_
/
ection vs. EnergyCross ._.,,.-.-15
IU _"---'--r---_ i 111111 1 J---TTTIIII ' , , l I Jill I---'--I_Tr-ITF'I_
AZO"- ,0I
X-- 0"o_
c,4 //
©
C©
'-_ 10-17 Recommended
(.,.,) --' /
O ¢_ - _-- DataU0 "(h
o _
_- -_ x/" X,_XX_ ...... Chebyshev Fit
U
"10-1_-_--
i_
10-19_ 1. i i 111111 i i i 111111 i i i 111111 ,1 i i 1111
10,_ 103 104. 10s 100_,Energy ,eV/arnu)
I?:-2 0
Total Me, ast:able I)_,_it.luUt LOll, L!',lot.:L._[_ll StrLppilEI0 allCl l>e-t.,xcl tat [|'_1_Cro_s Sec-;tlens [cn
lie . .t I1_ -> He or l-le,j (oT)Fie* t 11_. -> He' I 112 t c._ (volt)IleA -t Ii 2 -, He I H? (vo_o)
OT O0 * L 0 0 AC)
_,lle [gy o t.,]lle tCly o I?',ne L-t.}y o( eVl_mlU ) (e:m_ ) (eVlamu) (c:m2 ) (eVlamu) (c,I _:)
.[, 8Ei-03 3,72E-16 2 5F>I.03 2,34F_- L6 6,31_;.103 2,091_.- I G2,0_+03 3,94F,-16 4 0E+03 3,BIF,--.L6 / DE.I.O3 2,D9E-.IG4.0_:-I-03 ' 6.J.6F,-L6 7 C)F,+03 5.4Li.l-16 I 01!;.I.04 ?,.O.L_-J67,0E+03 7,49E-t6 B 6EI03 5,53E-16 I 5EI04 .L,V71_-.L6B,4E-I-03 7,631_-L6 .I OB.lO4 5.4BE-,L6 20EI04 .l,52E-.L6I.OB+04 7,54L_-16 1 5E-I.04 4.881_]-.16 4 OF,lO4 B.20E-171,5B+04 6,69F,-16 20E-I.04 4,43E-16 7 Or-I-04 ],661_-.L72.0E+04 5,98F,-L6 40F,-I.04 3,38L,_-16 l OEI05 .L,B4B-.174,01,]+04 4.32F,-.L6 7 0[_]-I04 2,661_',-16 ] 2F,I-05 ].,211,',-.17
7,0_+04 3,13E-.16 I Or+05 2.211']-16], OE-I'05 2,49E-16 1 3F,+05 ] ,90E-16],2E-1.05 2,26F,-16
Referellcea. l 1.02, 198, 402, 408, 410, 4111, 412, 4.13, 414, 4L5, 416
Accu_-acz! 50%
Notesl (.l) 'l'aw_a (Ret_, 102_p hastL.Ist:eci_. the exc..ited ni:aLe ltl:c_t:.illlel-J( roy: tie ,_IFJL[_i _tp _ 5,6xI0" . sec; (b) - ' ,05xtO -7 aec; tc) 2tS - 0,14 sec; d) 23S - 10 _sec, (2) o,j, = o0_ t .l o0, 0. (3) Benton, ct al, (Ref, 4.12) _uu1id tlle rural destruct.|.ottcross sections of tile triplet: llletastab Le st:ate t;o be 6,0}{l 0" 16Clll_' at therma.lellergies. Fol.' e 1.6,ct t"Oll strJppJllg cross sect.[ OilS or oi:hey e×c.l tecl star:es see
Pederserl (Ref, 4:14 ) , /
(_lebyshev F'ltt.Lnc_ J_.ar_ll#ters Lcr Ctoas Sect.l.olls
°T Ellll I1 = I, 8E't 03 eV/altlU, l..]lua× = t. 2E-F05 eV/tlllltlv0*t EIlli n = 2,5E+03 eV/aluul, rills x = I.,3B-t-05 eV/alllu
o0, 0 Bluin = 6,3B-t.03 eV/all|u, l_luaX = ,t, 2E+05 eV/allltl
AO Al A2 A3 A4 Ab A6
'_T -70.748] -.3]0880 .-.437383 .0B56563 .0221175 -.0286798 .01398]6°0,I -7].3457 -.218099 -.407518 .142300 -.0{31160 -.02"10893 .0189680
°0,0 -74.1810 -].38382 -.434J91 -.0390903 -..003]2428 -.00143317 -.0009"10525
The fit represeuts tile oT cross sect:[(_ll witll ali rills deviat Ion or O, 6%,The nlaxi.lllUlll deviat:lon i.s 0.6% at: I .8l!;.t.01 eV/ainu,
The f.Lt represellts the o0,1 cross section w:l.th ali 1-111_tclevi a£1ou of. 0.5%,The ma×t.nlulll dev:latlou .is 0,9% at 1,5I,:.t.04 r_V/_ullU,
Tile [,Lt represetltS tile oo, O (;[oa_.l sec:L.[Oll w.[ t-h _tll [llll] Gevli{ltI[[)ll [)I () , (l_, .
'I'lle IllaXillltllll deviation t s O, 1% al: '/. 0E.104 eV/alllU.
See appendix For C?l_el:)yntlev t'.t.t dotal.Iu,
O
1!_-2,].
Pie -I-I-I2-...He+ -I-H_,.4-e (cto'_)He* + I-I=- > He -I-H_. (oo'o,)
II
S.lncjLe mid I._oub.Lo l'tc:_Je,c:_l:tLe I_.loc_t.rcm l,c:m_l ht _t:l Ippi IICJ Cv(:nifl _gc!t: [{_lltl J_'of
I/c-t .I IIo -> Ilo ° t Ilo i o (tloi }, II_ .I II{-_ -.> l.h_,?+' .r II_+ -I 2_v (oo_)
001 00;:
|_]lle+l_q_ Ct:Otil+ S(:_ot;.lorl lt_tvatuy C'.t?(_L+U_ecJt; IoII(PV/aJlILI) (CJlll_) ' (f-.+V/allltl) (Olll")
5,O_.l.Ol t, .l9F.,-'19 5,OI_H04 3 921_-Ill7,01_-I.01 2,301{:-.L9 7 01!3'104 5 00_]-lB1.OB-I.02 3,4OF,-,L9 .t0[_,.I.05 5 _151+~]BL,5_-1.02 4,.19F-J9 .[5E-I05 5 04111,-182.01]H02 4,3"2_:-.L9 2 01_-105 3 B31_:.-]84.0PH02 .t,37B..LB 40E.105 t 721%.1B7,01_i02 3,36F,-.I B 1 01_.t-05 B 7 ] I_]-.L9I, 01_'I03 5, '/91_-II] .t OI]HOG 5 501,.3-+.L91,5B+03 ], 07F,-172,01_:103 ], 64_-174,0 L":-t.03 3, 17 IP,-1"17, OB+03 5,3 7 !!',-17I, Ota+04 6,74 F,- 171,5F,+t04 B. :t61_:-,_172,0F,+04 9.21B-174.0g+04 I,OSt_,-;I67, Ol.e+l-04 .1, O()g-" +t6J_,OP.H05 9,3;L_- 17I, 51_-I.05 [',, 37E-- I'I2, Ol_.t.O5 7,4 O1_-!tI4,0F,+05 4,89E-] 7
5.01_'1"05 4, t Bl!:-.t"1 i
RI3fet'ellrJeBl O01 - 97, 99, .I03, 198, 304t 316, 399, 400, 401, 404, 405, 407,408, 410+ 465, 466, 467, 468, 469, 470, 471
002 - 94, 400, 401, 405, 470, 47]
AoouracYl 0o1 E > ixJ03 eV/ainu - 20%L'l< ]×I0 ] eV/al0tl - 100%
Ooz 100%
NotoI Most of tile data have beell t;akell f(3r a mlxect boam o£ ClrOUnd st:at(_ all(:l_I:abJ+e states of llloLdettt tie,
Clmbvshov _iJ:.ttlD.qParameters for Cross 8ectlolIs
o01 I!:liHII = 5. OI]H01 eV/allltl, l;kllfl× = 5, OB-t05 eV/allltl°°2 l_ill.tii = 5.01!:-104 eV/ailitl, l_lllax ---: 1, OF,i 06 eV/alilU
AO Al A2 A3 AO Ab A6
°ol -78.6342 3.2054 f, --J.375"10 .-,3!:,9168 .188553 -.,(i.i15646 -, O913B45°02 -81.2673 -1,09626 - 43819] .]46687 -,010295B -,0324691 ,O 19"16B()
The fit represents the (JOt Or(]lS,q t:ieCl:lOll W.tth fill l'llll:l devlat;lon of .t0,2%,Tile niaXtllltllll devJ+at t()ii .] l:l ] 2,7% ai: 2,01!',i 02 _,V/allill,
The fJ.l; repreBellt;s the o07 cJi:Oss _leci:J(:)ll w]q;h _111 illlS clev:latJ.oll of 0,1%.']°llt:J lua×t iliUlil dev;l at J.orl J[I O. 2% al: 2,01!',.t()fS (gV/alllU,
See api)end.ix for [:lml)yshev fit det:a|.l,l],
I--le+ He .- > t--le"+ He + e,.(o'_.)....,/ 01' ,
He -t- He -.> t-le:_'' -t- He-k ,..'e_cro.,,)
Cro,:'_:'_.:,_J::,ectlOnvs. Energy-15
1() --"r-r"r-r'trm .... t--FrTrmr---,'--r-r_Trm----r-r-rrrmr---'l--T_rn
lJl-2'I
H.LlicJIo Ptoj_,_t l.:l._ l_,.Lclt:_tt't.)ll l.,(.)lltl ()t' _t t' tlJl.)l rlcJ RaL(, C!c:,:,[[+l_-'(+t,lltll E(_l O
Iii+..F llr:l -> II_' I IIo + (:
MaXWc_1]..[all - M_.IX',_'_.I.L.I_11 Rat:t--, (:'c)(.:,I:I! 1c_I (+111:r:t ( C,Ill3/FJ)
Ilo
q'oml_, I!:cltlal IIo 'i'm,p, (r_V)( _V ) !l'ollq_, t o, l OO, !_()0, 1000, 5o(-io, 10000, 2000o,
I,OI,',+OL' ,'T 50_-lOId ;3,501!:-IOH 9,951_:-I:I* L 531,:.,L) !i,gt'di'..ll I 131,:-09 2 90E-09 6,521_:-09
2,01q+Ol 3 551!;- L ,I /d G,Ttll_',,.tS# L tq.W,-t_ _ I 5IIF,-II 0 lOl_',-It l 14P,-C)9 2 9fil,]-,09 6,521_..09
4,01q,*Ol 4 05F,-13# 9,'/21:,:-I,I# i !:,(-)l_,..l;_' I "POl,:-.ll C) 341,',-LI. L l,ll¢,+O,c) 2 9",_I+:-09 G,531_',.+(')96,Ol_,Ol L 19L,';-12' 3,171q-13# 2 021,:-12' I [t31,:-Ll I_ 591+:..,11 I 151_:,09 2 _tll_:..O,:.) 6,5,11_:-()9
(I,01_*01 2 (.)2P,-12 '_ 0.301_-L3 4 2 ,lf.W,-l.;i _ I 96I_-L1 G [151!:- I .l L IG1._:-09 2 9t.lL,_-09 {_+5,1E-()_
l,OEo02 ?, 931_-i_:_ 9,r..)51_,.13 _ ;_ 931_-1.2_ _ lOl,:.,it / iC)L_-LI L I.'/E-09 2 9'.Ji.*,_09 (._,551_-09
2,0F+O_ 9 t_LI_-.L2 3 1"/I,',-12 _ 5 5:1_-L,'3, ;_ I_51_-.1L f._ 40E-11 ! ;!Ol",-O(.l 3 0:11_._-0c: G,51iE_09
4,.01_+0_ +3 '13_-1L I.,011_:-1L ! "lE-II ,1 "/,1_-1.1. I LSI_:.,LO i 2'1F,-09 3 101_-09 6,651_',-09
0,01_+0_ t_ 401_-11 _,1"/I_-|1 ;! fI5R-11 '; lOi_-tl L 50F:-.LO | 3,1E-09 3 L[II_-D9 G,7217,.09
f*,OP.,+02 I 501_-10 3,0:117,-ll ,1 "I41_-}L 9 9:IF',-LJ i [ItlE-IO I 4rE-09 3 _'31_-09 6,'lflP,-OC)
,0 I_ +0 3 _ 3 t Y,- 1C) b, g (_P,- I I I I 0 I_- t t L 3 2 P,- 10 2 3 t I,;- t 0 L ,I f+iL+I- 0 g 3 3 2 l;:- 0 9 6, tl 5 F+-,0 9
2,0E,03 ? 9,IF-tO ?,,331,',-10 2 53E-10 ,] 50E-10 4 117F,-IO I 85F,-C)9 3 69P-09 7,|[1I,:-09
4,01!:103 2 21_-09 "1, 9'11+:-10 f_ 2'lE-lO 9 GOl,_-lO t 13F,..09 2 5[1t,_,-09 ,I 421,:..09 '/+ti3l;l-09
6,0E+03 3 691+-09 .1,49L+",..09 I 57E-C19 I 6'iI!',-.09 t /151+:-09 3 37+E-09 5 13l?,-O t) /I,4"11_-09
fl,OE+03 5 I.:IE-09 ?.,221_',-O9 ',? 25E-O9 2 ,101,;-09 ;I 5UE-OCj ,1.O6E-.O9 5 I131,+.-09 9,0[IE-09
1,01_,04 o 52E-09 2,9G1_-09 2 99I,:,-09 ] 141_;-0_ :1 3,.1_,-0.1 4,7"1ti-0¢) (i 52t:-09 9,691,:-09
1,51_,0,1 9 figF+-C+9 ,l,'/Ot+:-O_._ ,1 tILE-09 4 95I?.-09 5 13E-09 6,5_E-o.q t] 15E-09 |,LLE-O_
2.0_104 | 251:',_0[I 6,52E-09 6 5bI_-(19 0 58F,-09 6 EI5F,-09 [I,.L5E-09 9 69E-09 l,_5t_-O[I
Acc+tlr.acy I * -. Ikmu l.bl e l+;]:_:or Civ:eat:r+_ ']'hall .LO%II - l-'oa+:+.Lb.l.t!: l+trot CJt+t+at:c+r 'l'l'lall .100%
O+ Cl_ebyahev t+'!_t,_;.LncI l+atalllet,et_ [(._t" Rate Co_tflc!lel_ta
+' = ] 01_:-t0 ] eV, :+- 2,01_:I 04 (_Vl"lllJ li ' _llldlX
Ilo
Telll[3,
(eV) AO AI A2 A3 A4 A5 AG
'£0, -51,7583 _I,06294 ..| ,_,155tl ,4110900 -,345667 ,0016[I045 ,09[19086
J.O0+ -47,7268 4,716f19 "1?.'183 ] -, 3[,fi'/flO --,.134711 ,0403620 ,0326103
500, -45,2262 3,19'.152 i'172249 -., 155633 -,153319 ,00295,141 ,0304114
lm,O, -43.7465 2,41803 8061tl9 - ,0302l[19 -, 1;_2t]90 -,0208521 ,02059335000, --,10,06[14 892003 4357"19 ,II'r:"t'', ,-,+,, -,00729485 -,01797]7 -,,005'/6'143
I0000, -31],657"I 504603 ,,,-r. ,_ , -,, ,../493_ 0941'141.13 ,013"/433 007553211 -.,00472901
20000, -37,3fl17 ,2617"]7 L5241'I ,06 |fl{191 ,0157f168 5,99102E-0,I - ,00L113208
Equal q'elt|l+,,-49,6003 7.93762 -I 5fl9ill ,635046 -,5'19197 .290394 -,04504fi0
See al.)periclJ.+,< for ClIc:,by+:illc:,v l!:l.t, ch:+t:,:.tJJ.ti,
O ' He -t- He --:.>He+ 'F Ile + e
O
,Ut.-2 6
N.LllCl].e Project lie l_.l oct:votl 1.,o_._f:l orr NI: r.l.tJl_l nel Ililt:e Cue 1' t :icl _,,It. u for ' 0
lie ,t lie .-', lie _ -t lie ,I c_,
llf.:_alll - Ma×we.I..I,.iarl I:_ltc._ (_oel f Jcl_-_llt:s ((:]l_l]/[-_)
tieTemp, I.le ENergy . (_..,,V/alllu)(eV) 10000, 2(JO00, 40000, '10000, lOC)O00, 200000, 500(}00,
10Et.O0 8,89E-09 2 37l_-08 30(Jl!',-08 ] 68E-08 4,09E-08 4 60F,-.08 2 051_-(.)8tt20E.t.O0 9,34E-09. ] 90E-08 300E',-08 3 6"1E-08 4,091<-08 4 59E-0B 2 05E-08tI',10E-tO0 9 361!:-09 I 81E-08 300E-()8 3 67E-08 4,09E-08 4 60i,_-.08 2, 051_-08tt7 OE+O0 9.35E-09 1 8]E_08 :_ 0011_-08 3 6"I1_;-08 4 09E-08 4 60F,-01t 2 051_',-08tt
, i, '39E-08]. OEtO1 9 351",'-09 .l 81E-08 3 OOE-08 3 67E-..08 4 091_,-08 4 2 05E-08tt2 OEtOI 9,35E.-09 1 81[",-08 2 99E--08 3 67E-0_ 4 09E-08 4 59E-08 2 05P.-08ti4 OEt.O1 9,35B-09 1 81E-08 2 99_:-08 3 6lE-Of{ 4 09E-08 4 !39B-0_.1 2 051_-08117 OB+Oi 9.35E-09 i1 81['i-08 2 991!',-0_1 3 6"11!',-08 4 091-_:-08 4 59E-08 2 ObE-OBtt] OEt02 9.36E-09 1 80E-08 2 99E-08 '1 6"11_-08 4 09E--O_I 4 59E-08 2 051!',-08fl
2 OB.l.02 9,381_,3-09 1 80E-08 2,.98E-08 ] 67F,-08 4 091!:-08 4 59E-08 2 Obl_-08114 OEI02 9.43E-09 ] 81E-08 2 971.']-O8 3 6"II!;--O8 4 O91_:-O8 4. 59E-0_,_ 2 041_-OBII7 OF,+02 9.51E-09 | 8II__:-08 2 97E-O8 I 6"IB--08 4 O81!:-O8 4 58E-08 2 04E-08111 OE't03 9,60E-09 .l 8].E-08 2 96E-08 3 67F,--08' 4 08E-08 4 58E-08 2 041_-08tt2 OEt03 9,91E-09 1 83E'08 2 95E-08 3 67E-08 4 08E-08 4 5'1I_-()8 2 031!]-08tt4 OE+03 1,05E-08 1 86E--08 2 951.'I-08 '3 6"1E-08 4 08E-08 4 5"1E--08 2 021_-08tI"l OE'l'O3 l.J4E-08 1 9]E-08 2 95E-O8 3 681!',-O8 4 O81_-O8 4 55E-O8 2 olr_,',-OSll]. OE._04 1,22E-08 1 96L-O8 2 95E-O8 3 681!:-08 4 081_-O8 4 55E-08 2 001_':-O8112 01_-I04 1.461_-08 2 IIE-O8 2 98U;-O8 ] 69E--08 4 ()8E-()8 , 4 "" _._21.,-08 I 98U_-.O811
Ac'cfffacyl * - Possible Error Or eaLer 'l'llan 10%,II - PossibLe Error Oreatei: Than 1OO%
Chebyshev .Fit, tillq Var_m_et:ers for Rate Coefficients
F',illi n = 1, OE.i-O0 eV, El]la × ': 2, OE-t.04 eV
lteEnergy(eVlamu ) AO Al A2 A3 A4 A5 A6
[OOOO, -36,8050 0170883 ._.O1708 ,O672106 ,C)[56617 ,0105"/96 -,0035638420000. -115,5374 -,O1318"19 ,O93"/563 -,O235657 ,0434438 -.0195503 .O14252640000, -34,6583 -,OO778924 6,32056E-O4 00349830 ,00265169 ,O0125371 4,62226E-O470000, -34.2378 9.38356E-O,1 ,OO134041 ' 9,0266,1E-O4 4,3]O72E-04 6,92929E-O5 -20 11386E-O5IOOO00. -34,0260 -6.94332E-04 3,47489E-05 ",_,894 ] 5E-O4 6,88603E-O5 -2. O8349E-O5 -8,O9043E-05
200000, -33,7994 -,00708522 -,00341665 -,OOL68503 -3, [6686E-O4 -3,04255E.-04 ] ,O4496E-04
500000, -35,4225 -,O144815 -.OO74653,1 -,OO291476 -9,54856E-O4 -?,, 93045E-O4 -9,76578E-O5
See append].x ' [cir Chebysll(-:,.v l:l.t deta] Is.
E-27
He + He ->He + + He + e
Beam MaxwellianO_
I0
ss.o lHe Energy
50. 0 (eV/a rnu)
-IOOOO.
45.0 -x --20000,
5.0
10o 10' ld ld ld 1#He Temp. (eV)
' 0
il
,1
E.-28
Electron. Projectile boss or Stripplng Cross Sections for O
He _ + H -> He ?.+ 4. H + e
Energy Velocity Cross Section
(ev/mllu) (c.I/s) (c_ll_),
i. 2E+04 i. 52E+08 ]. 66E-19
i. 5E+04 i. 70E+08 4.7 IE-192. OE+O4 I. 96E+08 i. ] 5E-184. OE+04 2.78E+08 "7.O3E-187. OE+04 3.68E4 OSm ]•liE" 17l. OE+05 4 39E+08 1 O4E_171.5E+05 5 38E+08 9 34E--182.OE+O5 6 21E+08 8.17E--]84.0E+05 8 78E+08 5.26E--187.0E+O5 1 16E+09 3.63E--189. OE+05 1 32Ef09 3.O4Ei18
References_ 301, 476
Accuracy: 20%
Notes : None
Chebyshev Fittrinq Parameters for Cross Sections
Eml n = 1.2E+04 eV/mllu, Ema x = 9.0E+05 eV/_11u i
AO AI A2 A3 A4 A5 A6
-80.7839 1.O4755 -1.36971 .44]034 -.0292764 -.0527228 .0184479
The fit represents the above cross section with an Ims deviation of 4.3%The luaxinlum devation is 8.7% at 2.0E+04 eV/aJllu.
See appendix for Chebyshev fit details.
E-29
0He+ + H-> He2+ _ H + e
Cross Section vs, E__nergy-16
10 i I I I , I I i I _" I t_ 1 ..... I I I I I
10-17 /_
E /
/©4-' Recommended
@ Databf}
I / ,
©L " ...... Chebyshev FitU 10_1_ ,,
lO-,g , I 1 ,t I I A rl 1 i. l i i _ lt
10" 10s 106Energy (eV/ainu)
E-30
QProjectile Electron boss or Stripping Cross Sections for
He + + H2 .-> l-le2_ + [-I2 .l- e
I
Energy VeJocity Cross Sectioll( eV I ainu ) ( cm/s ) (cm 2 )
5. OE+03 9.82E+07 I. 29E-]97.0E+03 i. 16E408 I. 99E-19i. OE+04 ]. 39E+08 3.25E-[I 9I. 5E+04 i. 70E+08 6.18E-]92.0E404 I. 96E+08 i. 06E-184. OE+04 2.78E+O8 5.77E-187. OE+04 3.68E+08 1.45E-17
I. OE+05 4.39E408 2.02E-17I. 3E+05 5. OIE+08 2.16E-17]. 5E+05 5.38E+O8 2.16E-172. OE+05 6.21E408 i. 85E-174. OE+05 8.78E4 08 i. 13E-177. OE+05 I. 16E+09 7.81E-] 8
9.5E+05 ]..35E+09 6.29E-18
References: 94, 96, 97, iO0, 101, 296, 30], 464, 476, 478
Accuracy: E < 3x104 eV/6uuu - 40%E > 3x104 eV/ml|u - 20%
Notes : None
QChebysl]ev Fittinq Par6uueters for Cross Sections
Emi n = 5.OE+03 eV/_llu, Ems × = 9.5E+05 eV/muu
AO AI A2 A3 A4 A5 A6
-80.9631 2.17474 -1.29222 -.291348 .317779 .0620566 -.0993825
The fit represents the above cross section with an rms deviatiorl of 2.3%.The nlaximum deviation is 5. i% at 2.0E+04 eV/muu.
See appendix for Cl]ebyshev fit details.
E-31
0He+ + H2 -> He_+ + H2 + e
L ross ._ection vs, ELnergy,_,.-,-16IU .... i , _ I i r"r,i i _' i i l i ill "' i-- i i lT'r-
Y \/10-r/- / ""--,.
E_ - / "',u - /c-O -
'.__-5 Recommended
® - Data(./3or)Or)O,k._
L.> 10_1o Chebyshev Fit
--
10 1 __1_, I I I I Jill . ,l l I I I IlJl t,. l i l. JlLl
ld lo_ lo_ _o_Energy (eV/am u)
E-32
Cross Sections for Projecl:i].e Etectron boss oi- Strlppln(.1 forlte _ Passi,lg Through Hellulll
He + + lle -> }le 24 + He -t. e
Energy Ve] oc:'[ty Cross Section
(ev/_ml) (cm/s) (cm2)
3 5E4.03 8.22E+07 2.63E-i94.0E+03 8.79E+O7 3'68E-]9
,7.0E+03 i..16E+08 ' ' 1.O2E-].8i. OE+04 i. 39E+08 1.64E-18i. 5E+04 I. 70E+08 2.74E-182. OE+04 l. 96E+08 3.87E-] 84. OE+04 2.78E+08 8.89E-]87. OE+04 3.68EI08 ]. 67E-17
I.OE+05 4.39E+08 2.14E-17i. 5E+05 5.38E+08 2.35E-] 7I. 7E+05 5.73E+08 2.36E.-I 72. OE+05 6.21E+O8 2,34E-1"74. OE+05 8.78E+08 i. 69E-] 77.0E+05 I. [6E+09 1.07E-17I. ON+06 i. 39E+09 7.73E-18I. 5EI.06 i. 70E+09 5.21E-]82. OE+06 !•96E+09 3.91E-] 84. OE,f06 2.77E+09 1.98E- 18
References: 94, 96, 97, i01, 296, 375, 471, 477, 480, 481, 483, 48 _ 486, Df ,
487, 488, 489, 490, 491, 492, 493
Accuracy: 20% O
Notes: None
Ch__ebyshev Fittinq Parauueters for Cross Sections
Eml n = 3.5E+03 eV/_nu, Ema x = 4.0E+06 eV/_uu
AO A1 A2 A3 A4 A5 A6
-80.4254 .937124 1.62973 .0029"/670 .154841 .0696031 -.0892584
The fit represents the above cross see:tj on with an rills deviation of' 1.6%.The maximum deviation is 3.5% at 40E+04 eV/_uuu.
See appendix for Chebyshev fit details.
O
i
t
B-33
QHe* + He > He_+ + He _- e
C"C.t-oss _:,ectlol7vs° Energy
-16IO _ ,-, ,,,_rl_r---r-m-,,,,ll , , , r,,,,j r , , ,,,,,
m
- _,i__ X// \10-_7_- // \\\
- / \o - / \
- I \c I \
,..0. - / X_ Recommended,.... / \
O @ / Dataco - /03
8 ..... Chebyshev FitLP 10_,__
--
--
10 -1 __ J J.J JZ4.1._L__.J,_J JiJJll i t I Jll_ll l i J J.L..LL
103 104 105 106 107Energy (eV/a mu)
Projocttl_ Ele(_tIol_ L,(-m_ or St.t.tpplng Rate Coeffilr'tellt:_l Eor
lie .I l-lo_ -> LIe _!_ .t, tlo .i o
Beam .- Ma×we..l.l_l'.an Rat._) c;cJe[ [ .t.(:].e.nt.e:; (cm3/u)
lte'
Telllp. Iio [",llel'gy (raV/allltl)(eV) 1.0000. 20000. 40000. 70000. 100000, 200000, !,0o()00.
E
1.OE+O0 2 93E-10 .l 20E-09 _ "/SE-IO 4.39E-()9 ],O6E.-O8 1 4r, r',_-08 :[ 381!1-082.0E¢00 2 381'.'I-10 8 92E-:10 1 ,q2E-09 5,6 r.Jl!.'-O9..... 9,9OF,-09 :l 451_.-O8 I 38['3-,084.OE+O0 2 2BE-lO 7 7lE-lO 2 38t'.':-09 5.99[_I-O9 9 37E-09 1[ 45l!',-O8 l :1_I!-O8
7.0E-_.O0 2 28E-]0 "l 60F,-]O 2 4!1._;-.09 6,0917,-09 9 31E-09 .l 45l!'.-()8 I 3E-li!I-OIll,OE-t.O] 2 2Bg-].O' 7 6:1["1,'].() 2 47E-O9 6.:12E-O9 9 3BE-O9 :1 45P.,-O8 I 38E-082.OB+O]. 2 2.8E-10 7 61E-10 2 47P,-09 6;]3E-09 9 38E-09 .[ 451/',-08 ]. 3BE-OB4.0E-t-01 2 28E-10 7 62E-]0 ,2 4"1E-09 6:12E-09 9 3FIE-09 1 45E-OE1 l .38E-,()_t7.0B-t.O1 2 29E-:[0 ''l 63L,I-10 2 47E-09 6 12['1-09 9 37E-09 .[ 45I!:.-0a 1 38In-0_3
1.0E+02 2.30B-10 7 64E-10 2 47E-09 6 121!1-09 ' 9 36E-09 :1 45E-.OB l 38E-082.0E+O2 2,32E-1.O "l 67E-10 2 48L!1-09 6 ]1t!1-O9 9 35E-O9 .1 451!',-OFI I 381!1-()_..14.OE.I.02 2,36g-i0 7 '74E-].O 2 491!1-O9 6 IOE-09 9 34E-O9 1 45E-.O_3 I. 38F,-O87,OE--02 2 43P1-IO 7 85E-I0 2 5017,-,O9 6 l,Og-O9 9 32E-O9 1 4411',-OP, .I 38[;',--081.OB-t03 2.50E-10 7.96E-lO 2 52l!',--09 6 .lIE-09 9 31E-09 ' 1 44E-08 1.38B-OL12.OE-I'03 2.'12E-10 8..32lg-:IO 2 57E-'O9 6 1.31_1-09 9 291i]-09 .I 44[!:-()8 1.381!1-O84.OE+O3 3.19L,]-I0 9,05E.-10 2 68E-O9 6 19E-09 9 291/:-O9 :[ 431_-()8 1.38E-O87.OE-¢O3 3.92E-I0 1,02E-O9 2 831:_-O9 6 281i3-O9 9 3OE-09 ] 42E-O8 :I.31{'11!',-081.OB+04 4.70E-10 ]..131'.',-09 2.99E-09 6 38F,--09 9 321!;-09 I 42E-08 1,38E-082,0E+04 7.54E-i0 1.52E-O9 3.46E-O9 6 611.;I-09 9;4]I'3-09 :I40E-08 1.38['q-()8
ClLebyshev Fittinq Pardi|el;ors for RaLe Coefficients
0E;tlli n = :1. OE-t-O0 eV, gitla x --: 2. OE+04 eV
He
Energy(eV/ainu AO AI A2 A3 A,I h'i A6
I0000. -43,8442 .378813 ;344057 ,IC_5569 ,0867559 -,00821300 .012905620000. -41,5895 .123902 .270872 ,011.5805 .088'2436 -,O161519 .012672940000, -39,7835 .385155 -.]45042 ,223297 -,0998296 ,0753339 -.032690070000. - 37. 882'/ . 110612 - ,0493705 , 0701363 '- ,0309008 , _,,.'_'_5"_'_r"n.,,_.._v -, 0129206100000. -36.9382 -,0374325 ,0312796 -,01B8116 .01661311 -.006284fl6 ,0020"1'152200000. -36. 1132 -,014984B -.00760145 -, 002E10029 -El, 61479E-04 - I, 69493F,-04 -3, 20142E-.05500000. -36,1937 -5,70799E-04 -4.55366E-O4 -3.44110F,-O,I -,_,361'75E-O4 -i.47246E-04 -9,193766F,-05
See appendix .for Cllebyshev f.ll: det:a.t.l,s,
0
i
_11 He + He+ ->He _'+ + He +e
Beam - McixwelJan
,IU7t,-x- "---I--T'I i'tli,I I I i-ITTrff----r-T-TTI'rlTF----r-"T' I iillll I r-F-rTl_
- He Energy
- (eV/arnu)
A -- 10000,
x -- 20000.
.,,.... . _., _ - 4-0o00."-'. 8
.._. 10- _-----. @ _< -- 70000,ffl
o ,/_ @ -- 100000CE
@ ,../,_ E3-- 200000.;+_. 4-- --'_
m -500000.o
U@ ,/X Recommended
+" ,v -._tr_-9 _ '_ Data
_ _ Chebyslnev Fit
'_.._ _
p
10 -10 _ ] li|Iii , I l | !]_!11[ 1 .1 IJtlU.J._ I 1 I I ILLLL.___L_LLLL
10o 10' '10_ Ir.P 104 'lOsHe+ Temp. (eV)
OF, Electron Detachment Cross Sections
Page
H- + H -> H + H + e ........... F-2
-> (H + H + e) or (H + H-) .... F-2-> H + + H + 2e .......... F-4
H- + H+ -> H + H+ + 2e ......... F-6
H- + H2 -> H + Hp. + e .......... F-8-> H+ + H 2 + 2e .......... F-10
H- + He -> H + He + e ......... F-12-> H+ + He + 2e ......... F-14
, - F'I6He + H -> He + H + e ...........
He- + H2 -> He + H2 + e .......... F-18-> He + + H2 + 2e ......... F-18
He- + He -> He + He + e ......... F-20-> He _ + He + 2e ......... F-20
Li- + H 2 -> Li + H2 + e .......... F-22-> Li + + H 2 + 2e ......... F--22
Li- + He -> Li + He + e ......... F-24
O -> Li + + He + 2e ......... F-24
O
i
Lr- 2
c!ro[I(l FJo(._tl.oll f 0X _iltr_j.L_9 I?:lf:_i!t:l'r3l| I],;_t;ziclltltLmlt:nlld IPot, tl._ I1" leorlllettJ(;llt l: ['Oltt II- oli tl g
I1" t II-> II-t II i _
t1" -t- II -:" (11 't II .I [_) or (11 -t I1") ['l'ot:al 11 Prc_d, I
II F 81 't o 'l'rlt:a.I II I'rod,
I_ll¢:_r.qy C;routJ. _lJ_t:.LC:lll I_alor_iy Ct o_]_]_ _otlL LOll(_w I_u,u,) (c_,__) (_w l_,,ui (c,,i;')
1, i[I+:1()_ f.I 651!1._,L6 6 01_.tO.t 6,641!I-.L52,0 lT,.l.0 2 ;l 2II1_- 15 7 0 I!I+i(I .I 6, "I5 I_~_t!:J4, O_ +0 2 I 4,1t_,-.t5 .t (}1_+O2 6,79 _',-.t5'! OB-t.02 .L 39P,-;L5 ;I. 51_.I02 6,481_-.151 OB-t.03 .| 321[]-15 2 O1_.tC)2 6 .tll_',-15I 5B-t.03 ;t .1.91_-15 4 OI}:-1C)2 4 921.4-152 OB.t03 1 .l.ll!;-]5 7 OB.tO2 3 [lIB-lh4 O1_.t.0'] I Oll,.:,.]b .[ OI!HO] ] L3F,-[5"10B+O3 9 751_,-.lCi 1 51=I103 2 4%"..U,-15;1 OB.t04 fl "/21!I-.|6 2 O1!:.103 2, ()3F,-lb] 51_.t04 '/ ][ll_-.16 4 OI,;t03 1 261]]-152 O1_.!.O4 6 26_-]6 '/ 01!;.t03 J O1B-1540_#.O4 4 25P,.,16 I O1_,.10,t [] 741;-[(i7 0l;-I04 2 908-16 l 5L_I04 '1 ][|_:-]6.t OI_.tO5 2 211_- 1O 20 !],t 04 o 26 I,;- .16I 5B-t.05 ] 6]L_-]G 4 01,_.t04 4 2h1_-162 01_.t.05 .[ 27U1-16 7 01,.It.04 2 901!I-.1640l_.i0b ' 7 04I_-].'1 .1 or.,l.i05 2 2,.11?I-;L670B.tO5 4 24U1-17 ] 5P,-t.C)!$ 1 61t?:-161 OB.t06 2 99L_,-1'1 20P,.tO5 I 2"11_-].6] 51_.t.06 2. O91].I-;1'1 4 O1_.t()5 "/ 041Z,-1720_.¢_6 I 591_',-.t'1 7 _ '0 I.,t 0 ._ 4 24 l!_- .t"14 OF,'FU5 tl 23U;.-Lt3 ] O1=>I06 2. 99F,---.1"1
.1 5R't 06 2 . 091_-J'/20U]'tO6 I 591!;-I140l!:i06 II 2]i_-.1ll
__ 1620 2Ill, ]010 395, 524, 525_ bb4o ._"'.J'-'i.
ArJP_Ui.-acT, L 30t
Data £or iota] II ° l}orlilat Loll repi:e_iont: t;h_t HIIIII cii the croEiu l]r:,ct: l.OllfJ lc.ll-, oollislonal det:ae._hlllont alld c_l_arcjo elicllal_CjO, 'Phe ¢_ll_rcji3 oxehallCJe c:_ont:r.l.btlL.l.on LLi
ilecj-l..IC.l.lb]f_ aL OllF_l'{J.l.eIB aboV£_ .10 keV/alllU,
C lebTuhev .... l_l{L J.il_...I,.. t'ai. fillii-_Lel:_ [(:ii CJLOlJtJ _2tCl;IO!lE!
II .t il .i-e !!illJn "= I,.LU].t02 eV/ailltl, !!ilia× -' 4,01!',t06 eV/ailluTot:ai. I1 Prod, it;lll].l 1 ft, Ol_tO;l 19V/t:llllU0 l!,lllaX = 4,OI!;'t06 E,V/_IlilI.I
AO A.I A2 A3 A4 A5 AG
II-I H i o -72,0699 .-.2,47924 -.,936325 ,01H36!]30 ,01"15192 ,O5452'Ii'{ -°0645320Tot:a.[ II Prod, 70 7835 -3 4;1032 - 545 '_"- , ..... ,08 ,00370]9!7 -, 0606.116 , Oil i917[i ,0()(;26[l'/7
Thn lit: repi:ef_enl:s H i I-I -i e C.Jl'C]_lli lJ[-_(:.'t.Jehi w.{ l:li ali t'llll:i cl_,vJ_:ll; i.Oll c)f. 2,75,Ttie litaX.llllUni deviat;.toll .Is 5,4% al; 201)I,]i0;I (.,V/aulu,
The [ lt: rr_prOelli:._ Tot:a.l H Plc;l(l, C:I'CJEtfi F]ir#Ct;.[ C.I11 vii i;h ali rllltl (ll:!v | _.-It i()l*l ill ] , '7%,
<Tile lll_.{illtlill dev.l.at l.oil .t _l ] 2 °4% aL 4, OF,t ()] c)V/allUi,
See appelid_t.x for Cliel_yf:l lev ft t clc!_i:alJ s,
ii
0I-I-.t-H- :;:.,(I-I-F t-I + e)c,,,: (H-t- t-I'.')
H- -t-t-1--.';, t-I-t-H-t- eI
._,.:,.::,ect.ionvs. Enc-,r-gy10'" I,I _--_r_-r.r_fTrrtF---r--_-_rT.rr_j---t-r-_r_t.rrr_---r-_-rTr_rrrF_r---r._r-tTr_Tf-_.r-_T1
"\_,
" ,-.""-"'- 't,,,:,,,X ' _ = ro t.cli.x-H + H..t- e
'10-'_-' ,,,/]
.!-.,
r,(
0'.__'3 trx- 16 Recomrnendedo Iu -
¢> - _, Dora_/') _-09(h
(._) ....... Chebyshev Fit
10-1:,_
-- q
I0-18__L_L_LU.LUL__LZ_LLLLUL__LLJ_U_uIL__LL!_____i 1 l.,J ilJllj I I II..LLI
lo' 1o_ 1o_ 1o_ lo' _o_ lo"Energy (eV/clm u)
11-- 4
C,t'o_i__oc_t.|.o'll_oIt:ItD_tlbl.f_I!_l.ec_,trollDet:a¢!hlltOi_tof II" Irl H OJ
H" -I.II -,> FI' + H .i.2e
i
EIle rely Velocity {;r cJss 8e(_t.i oil( eV/alitL1 ) ( Clll/D ), ( C,III2 )
1,8I_-t.03 5 89I_-t.07 . 3,1 :l t7],-.|82, Oi!l+03 6 21E._()7 3, .5'7B-:184,01B-103 8 791!H07 9,35_-.187. C)g-l.03 .l :L6E.I.08 ], 501!3-:L71, O_+04 I 39E.t.0B .1,77_-.1 '/1, b_l+O4 I 70t_.t.OB lt, 87 _:- 172, OE-t.O4 1 961_',-tO8 1,85B-] 74.0E+04 2 78LS'-l-0E1 ] • 431_1-:I.77.0E-l-04 3 68E+08 9,40E-.18
, 1,0_-I05 4 39E-I-0R 6,191_;-181,bE+Ob 5 38E.t.08 4,61E-182,01_-I.05 6 2]E..I.08 3.5:1E-183,0E+05 7 61B+0[i 2,5OE-1B
Ro ferellOeSl 524 t 5_r"
AcouraoyL '.2,0%
Note I q'here is Oll].y Olle Bet of expei;J.lllellta] lUeasurelllerits.
Chebvshev ,!_'it:gin_, Pai:alllel:ers ]:.or CroB_ Se_i:t.Ol!S i
Eiilill = ]. 8r.,1+03 ev/allltl0 Eiila× = 3. OE.t.05 eV/allltli
AO A1 A2 A3 A4 Ab A6
-79 0633 -.259"/90 -,938476 .:I54218 .C)364I]4 .00411484 ,00724986
The fit represeptB I;he above cross section with an rlllsdeviation of 0.9%,The IllaXilllUII1 deviation is :t. 8% at: 2. OF,+03 eV/allltl.
See appendix for Chebyshev fit: deta.t.:ta,.
O
H- + H-> H+ + H + 2e
,.,.._.,'
C0
u "Iu- - Recommended
(b ..... Databr)gl
Chebyshev FitU
"lO -'16 _. ,1 1 I I i , J I I J _L_L__..L_.LI II --L_.._..,4_.I_-Z_I_U
703 104 10s 14Energy (eV/_rn u)
F-6
Cross Sections for Single Electron Detachment of H- Colliding with H. O
H- + H" -> H + H _ + e
Energy Velocity cross section(evlamu) (cm/s) (cm z)
2.8E+03 7.35E+07 3.99E-163.0E+03 7.61E+07 6.57E-164.0E+03 8.79E+07 1.55S-15
5.0E,03 9.82E+07 2.24E-156.0E _)3 1.08E+08 2.73E-15
7.0E+03 1.16E+08 3.11E-158.0E+03 ].24E+08 3.4OE-159.0E+03 1.32E+08 3.64E-151.0E+04 1.39E+08 3.82E-15
1.5E+04 1.70E+08 4.23E-152.0E+04 1.96E+08 4.18E_15
3.0E+04 2.41E+08 3.88E-154.0E+04 2.78E+08 3.51E-155.0E+04 3.11E+08 3.19E-156.0E+04 3.40E+08 2.92E-157.0E+04 3.68E+08 2.66E-15
._eferences: 69, 569, 572, 573
Accuracy: 40%
Note: Accuracy taker] from the only experimental data available.Te-_etical calculations presented by Fussen and Claeys (Ref. 572), andErmolae_ (Ref. 573) agree uery well with experimental data.
Chebyshev Fittinq Par_l_eters for Cross Sections
Emi n = 2.8E+O3 eV/_uU, Ema x = 7.0E+O4 eV/mllu
AO A1 A2 A3 A_| A5 A6
-67.3879 .650676 -.658353 .211309 -.0972717 .0547639 -.0359904
The fit represents the above _ross section with an rms deviation of 2.6%.The maximum deviation is 5 71 at 2.8E+03 eV/_ml.
See appendix for Chebyshev fit details.
[_' "" '7
OH- + H+ -.> H -+:H+ + e
Cross .Sec.tior_vsoEner9y- 14
1() , ' -- I , , , ,- , , 1 , ---1 , I , , , T
//" "_
,.,.,
0
/,O endedo 10-I" Recomm
@ _ DataOr)(j-)Or)0
Chebyshev FitU -
10-1' , I 1 I l I 1 I LI 1 , ] l 1 1. I__L_L
10:_ 104 105Energy (eV/amu)
F_8 ¸'
Cross Sections for Single Electron Detachment of H- in H2 O
H- _ H 2 -> H 4 H 2 4 e
Ei1ergy Velocity Cross Sectlon
(eV/muu ) (cm/s ) (clu2 )
2.3E+O0 2.11E+06 8.91E-174. QE+O0 2.78E+06 I. 92E-167. OE+O0 3.68E+06 3.18E-16]. 0E+OI 4.39E+06 3.68E-16
i. 5E+OI 5.38E+06 4_.14E-162. OE+OI 6.21E+06 4.28E-164.0E+OI 8.79E+06 4.15E-167. OB+OI 1.16E+07 4.36E-161. OE+02 1.39E+07 4.80E-16I. 5E+02 I. 70E+07 5.60E-162. OE+02 i. 96E+07 6.29E-164.0E+02 2.78E+07 8.41E-167. OE+02 3.68E+07 i. OOE-15I. OE+03 4.39E+07 i. 06E-15]. 4E+03 5.20E+07 ]. IOE-152.0E+03 6.21E+07 i. 13E-154.0E+03 8.79E+07 1.14E'157. OE+03 i. 16E+08 i. 09E-151.0E+04 ]. 39E+08 i. 02E-151.5E+04 1.70E+08 9.24E-] 62.0E+04 1.96E+08 8.36E-164.0E+04 2.78E+08 6.33E-167_0E+04 :' 3.68E4.08 4.82E-161. OE+05 4.39E+08 3.95E-16i. 5E+05 5.38E+08 3.06E-162.0E+05 6.21E+08 2.51E-16 I4.0E+05 8.78E+08 I. 43E-167.0E+05 ]. 16E+09 9.02E-17i. 0E+06 1.39E+09 6.43E-17
1.5E+06 I. 70E+09 4.41E-I 72.0E+06 1 •96E+09 3.29E-174.0E+06 2.77E+O9 1. 553-177.0E+06 3.65E+09 8.13E-181 _0E.+O7 4.36E+09 5.16E-181.5_/_07 5.32E+O9 3.17E-18I. 7E+07 5.65E_09 2.72E-] 8
References: 27, 32, 82, 269, 299, 301, 303, 307, 321, 395, 513, 514, 515,516, 517, 518, 519, 520, 521, 522, 523, 524, 526, 527, 541,542, 544
_, 25_
Note_.._.'For total detachment cross sections (o_i0 + o_11 ) .,_ee: Muschlitz,
Jr. et al., (Ref. 514, 516); Stedeford and Hasted (Ref. ;52); Hasted andSmith (Ref. 515); Risley and Oeba] le (Ref. 520); Risley (Ref. 544);Jorgensen, Jr. et al. (Refo 32); Lichtenbert et al. (Ref. 523)
Chebyshev Fittinq Par_ueters for Cross Sections
Eml n = 2.3E+00 eV/_uu, Ema x = I.'/E+O7 eV/aJllu
AO Ai A2 A3 A4 A5 A6
-73.1506 -1.75695 -2.00168 -.]90280 .0171353 .12/083 -.152313
cross section with an rms deviation of 7.2%. IThe fit represents tlle aboveThe maximum deviation is 16.6% at 7.0E+0] eV/_uu.
See appendix for Chebyshev fit details.
F-9
, ' i
, ' H- + H2 -> H + H2 + e
Cross Section vs. Energy-14-
0 - 11 illlil I I I IIIIilr'-'Cl"TTTTTT1 _l I llillll ! I II]1il I ( I rlifii i i i illmi ! i lira
10-_5 _...
.-/
c-
,o 10-16+-' RecommendedLP¢_ _Data0U?U?0L.
U Chebyshev Fit
10--1_
I
10 ,18 ._J_J_LUull I l llllul_l ..1 J lllJlJl ! I llunl .J,JIiIUll I l JlllJd 1 I llJl.
lO0 lo' lo_ lO_ lo4 lo_ ld ld lo'Energy (eV/bm u)
F-] 0
0Cross Sections for Double l_]].ectron Detachment or H- .In H2 '
H + H2 -> 1-I4 -t 1!2 + 2e
Energy Ve]ocit:y cross Section( eV/ainu ) (cm/s) ( cm 2 )
1. OE+03 4.39E+07 1.48E- ].72.0E+03 6 2]E-t07 2.3]E-.174.0E+03 8 79E407 3.24E-177',OE+03 I [6E¢08 3.79E-17I.OE+04 i ]9E_O8 4.03E-171.5E+04 ]. 70E408 4.16E-172.0E4-O4 I 96E408 4.11E-17
4.0E+04 2 78_+08 3.97E-177.OE+04 3 68E+08 3;36E-]7
I.O_+05 4 39E'+08 2.84E-]71.5E+05 5 38E+08 2.20E-]72. OE+O5 6.2lE ¢O8 1.76E-:] 74. OE+05 8 78E+08 8.7]E-187.0E+05 i 16E+09 4.98E-18i. OE+06 ] 39E+O9 3.42E-181.5E+O6 i 70E409 2.23E-182. OE+O6 1 96E409 i. 67E-]84.OE+06 2 77E4.09 8.]2E-]97.0E+06 3 65E+09 4.52E-19I.OE+O7 4 36E+09 3.]3E-]9
2i,References: 269, 299, 303, 30"I, 3 518, 52] , 522, 524, 525, 526, 556,
563 , 567
Aqcuracy: 30%
Note: There are no e×perimenta] or t:heoretical data for energies below 1keVZ_llu.
Chebyshev Fittinq Parauueters for Cross Sections
Eml n = ].OE+03 eV/_uuu, Ema x :: ].OE+O7 eV/6uuu
AO Ai A2 A3 A4 A5 A6
-79.0159 -2.10252 -].24073 .174799 .i]06249 -.000434273 -0.0465674
The fit represents the above cross section with an rlllS deviation of 2.0%.The maximum deviation is 4.3% at 4.0E+05 eV/_uu.
See appendix for Chebyshev fit details.
O
F-].I
0 H- + H2 -> H+ + H2 + 2e
'_ , i/'
C,,,'--,c:_o.,,,,,_13iec:tionvs. Energy, -16 ' ' fI0 -- , , _-+'m:'r(...........f....._r'-r"-r-r-rm------T---',, , ,,,,i , , _ , ,,,,
7/ ""\_,. _,,/ \
,, \\
10-l_
° \rf__
._o - \4-' \ Recommended(D
\ _--Data
(.,0 \\
° \ED Chebyshev Fit
10-_8__ \\- \
- \- \
X
-- t
10 19 I I I I Jllll I I I J IlljJ l .J I I JJllJ I I{....LL.LL£.I.
lo_ lo* lo_ lo_ _O'Energy(eV/amu),
, F-12
Cross Sections _ro.[- Single, El ec*tt-oi_ Detaqhlllerlh or I1" lr} Ile Q
H- 4-Fie -> FI + lie .t. e
Eue _:gy Velt_city Cross Section
(eV/ainu ) (c,m/s ) (cm 2 )
1. OE+O0 ]., 39E+06 6 ,,13E-172. OB+00 1.96 E+O6 :1.25U;-LI. 64. OE+O0 2,78E i06 2.33B'16
7. OE+O0 3.68E+06 2.94E-]6
I, OElOl 4.39E IO6 3.03E- 16
i. 5E+Ol 5. 381_;+06 3.14E--] 6
2,OB+Of 6.21E+06 3.22E-16
4. OE+O] 8.79E+06 3.42E-16
7 OB+Of 1.16E+07 3,701_-16
] 0E+02 ].39E+O7 3.91E-161 5E+02 ].70F,+07 4 21E-16
20E+02 1'.96B+07 4.48E-164 OF,+02 2 78E+O7 5.10F,-16
70E+02 3 68E+07 5.60B-16
1 0E+03 4 39E-I07 6.02E-16
i. 5E+03 5 38E+07 6.38E-16
2.0E+03 6 21E+07 6.53E-163.4E+O3 8 fOE+07 ' 6,78E-16
4.0E+03 8 79E407 6.73B-]6
7.0E+03 i 16E+08 6,34E-16
I.OE+04 i 39E+08 6.08E-I[6
1.5E+04 I 70E408 5 501i:-16
2.0E+04 ] 96E+08 5 0lE-16
4.0E+04, 2 ;'8E-t()8 3 838-167.0E+04 3,68E.08 2 80E-16
I.OE+05 4.39F,_08 2 24F,-16
1.5E+05 5.38E+O8 1 728-16
2.0E+05 6.21E+08 ] 42B-]6
4.OE+05 8. 'I8E.108 8 33E-177.0E+05 ].'. 16E+09 5 27E-] 71.OE+06 ] 39E409 400E-17
1 5E+O6 ] 70E+09 2 92E-172.0E406 1 96E+O9 2 27B-174.0E+06 2 77E409 I 23E-17
7.0E+06 3 65E409 6 988-18
I.OE+07 4 36E+O9 4 63E-181.5E+07 5 32E+09 2 82E-18
Referencesl 27, 82, 269, 299, 300, 303, 307, 318, 321, 518, 519, 520, 521,
522, 523, 525, 527, 529, 543, 544, 545, 546, 547, 548, 549,
550, 551, 552, 553, 584
Accuracy_ 25%
Notes_.....!(1 ) For total detachmellt cross sections (oI,0 4. 2OTl ) sees Stedeford
and Hasted (Ref. 82); blchtenberg et al. (Ref. 523); R[sley (Ref. 544);
Hasted (Ref. 553); Bailey et al. (Re[. 543); Ris]ey and Geballe (Ref.
520); Champion et al. (Ref. 545); Alldersen at al. (Ref. 551); Anderson et
al. (ref. 547); Huq et al. (Ref. 548); R]sley and O]sol] (Ref. 549); Ris]ey(Ref. 318).
(2) For D- + Fie -> D sae; Risley (Ref. 544); Berkner et al. (Ref.
307); Champion et al. (Ref. 545); Al]dersol.} eti al. (Ref. 547); Htlq et al.
(Ref. 548).
Chebyshev Fittinq Pareuneters for (;ross Sectiol]s
Einir I --. i. 0E+00 eV/allltl, Ellla x = .1.. 5E*07 eV/_ml
AO AI A2 A3 A4 A5 A6
-73.7795 -1.54839 -].84526 -,140437 -.0282087 .183809 -.132562
Tile fit represerltS tile above cross section with all rms deviation of 3.O%.
The maximunl deviation is 14.4% at 2. OE-100 oV/m]Rl.
See appendix for Chebyshev fit details. O _i_
P- .L3
0H + He -> H + He + e
Cro._s<_Section vs. Energy10-15
j \j \/ \
JJJ
\\\
10-1_ \
E \
c \o \
'-_ Recommended
o _Data
0
U Chebyshev Fit
10-': \\\
l
10-1
loo lO' lo_ lo_ lO" lO_ lO_ lO_ ,o_Energy (eV/om u)
F-] 4
Cross Sections for DotLble Electron Detachment of H" on He _I
It- -t-He -> I-I_ + He + 2e
Eneegy Veloc.l.ty []rosa Sect ton( eV/ainu ) ( till/s ) ( rJill2 )
4.0E4.02 2 '781,3-t,07 2,03E-]87.0E+02 3 6884-01 7.10B-!8.I,0B+03 4 398.I07 .1.30E-171,5E-I.03 5 38F.,',+07 2.32B-].72.0E+03 6 21E.t.07 3.16t']-174.0E4-03 8 79[,7+07 4,9617;- 177.0E+03 1 t6E+08 5.51E-171. OE+04 ] 39E4.08 5.4 6t_I-] 71,5B404 .l. 'lOE+08 5,,12E-172.0E-t-04 1 96E+08 4.66E-].74,0E+04 2 '78E+08 3,25E-].77.0E+04 3 68E+08 2,011_-.171. OE+05 4 39E+O8 1.371!;-]71.5E+05 5 38E+08 8.92E-182.0E+05 6 21E+08 6.54E-]84.0E405 8 78E+08 3.16E-]87.0E+05 1 16E+09 ]. 75E.-18I.OE+06 ] 39E-I09 1.191_-181.5E+06 i 70E+09 7.74E-192. OE+06 1.96E+09 5.59_:-194. OE+06 2. /7B-t09 2. 681Y,- ].97. OE+06 3.65E+09 1.48E-191. OE+07 4.36E+09 ], O1E-191.5E+07 5,32E+09 6.53E-202. OE+07 6. ]1E+09 4. 891_,]-202.3E+O'I 6.54E+09 4.16[,i-20
References : 268, 269, 299, 303, 307, 318, 321, 5.18, 521, 522, 523, 525,552, 556, 561, 568, 584
3o_
Note:_ There are no experimental data for energJes below 400 eV/_uu.Theoretical caJ.cul.ations extend down t.o i00 eV/_mm.
CI]ebyshev Flttinq Parameters for Cross Sections
Emt n = 4. OE+02 eV/alllu, Ellla x = 2.3F,+O/ eV/ainu
AO A1 A2 AI] A4 Ab A6
-81 .1984 -2.71121 -1.946[ 0 .784427 - 131737 .0264605 -.006979]5
The ,fit represents the above: cross sect:]oll wJt:h ali rills tier.tat]oil of 2.6%.The max]lm lm deviation ].s 5.1% at: 2.0E-105 eV/_.mlu.
See appendix for C'hebyshev fit deta t.]s.
_11 Ji iillmm_[I
1_'-.1b
H-+ He-> H+ -t-He + 2e
Cross Section vs. Energy,10-_
101¢ 18 1¢ 10_ 1¢ ld 1¢
Erlergy (eV/amu)
O
Ii'- ;16
Cross Sectiolls [_t gillC.llC<_ [,11_7,cl;l.Oli lJ_,t;achluelrL (-_[ lit,- iu II
I.Ic4" .i. II -> I1(:_ .i II I o
_llerg7 Ve 1o(.'.1.I!.y Cros[i Semi Inn( eV/allitl ) ( till/[,1 ) ( (".Iii7' )
'3.7E-t'05 II, 45E'I.08 6 39L']-.L64,0E+05 8.781_I08 6 16E-;I_6
7.0E-i'05 ].16E'i09 4 29E-]6l. OE'i06 1.39EI09 3 29E.-J6
1.5E+06 1,7OIDI.09 2 39E-.[62. OE'I-06 I .96E-I09 '.[ 8['IF,-164.0E+06 2. 7717]+09 1 04E-]6"I.OE'I-06 3,651.i:-109 6 34E-179,0E+06 4.14EI09 4 99E-I'2
References.!, 301, 583
Aocuraczi. 40%
Nntel There is nnly one set of e×perililental meaDuremeiltEi.
_Chebyshev Fittlllq l'ar_neters fnr Cross SectJnns
Elllil]= 3.7F;-IO5 eV/alllU, Eluax = 9.0E+06 E:VImlIU O
AO ,:_i A2 A3 A4 A5 A6
-72.3804 -1.28777 -.0622952 .0122474 -.00652473 .000145452. -.00224648
Tile fit repreBents the abnve cross section wltli arl flUS deviation of 0.1%.The nlaximum deviation is O.2% at 2.0E+06 eV/ainu.
See appendix fnr Chebyshev [it details.
li'- ]."1
He- +H-> He + H+:e
Crc,s__._ o Se.,c:tior-1vs. EnergylC)-is ,.... , ,.... , r-r-r_--r J - ,- w--r--T-r'-r-r-
.-
- \\
_ \
,\r',l "\
o
c©
16 Recommended
t_I _ 10- - \ ,, ' .@ - \ ---_ Dat.a(./')
0 -"
U .. Chebyshev Fit
1('.)-17 1 1 l ! ,1 I I I I 1 1 1 1 I__L_LI
•14 lo0 lo'Energy (eV/amu)
l"-10
C'_.oslj SectLC)t]_ [o[ l.]irlg.|o L;III(I Dotll._lo I_]]O[_tl._OII DotaC.,'hltlef||; el ilo" Ill I1..,
tie- r II_ -.> fie ! t12, t _-> tlo ) i. I-I;) -t 2o
He t t1_ .r e Ilo ) -I lt_. -I 2e
li'Imftjy Cretin _ec!t[oll r_llle, l'frly tJl:'Om_ Soct. Lorl( eV / allltl ) ( till" ) ( eV/allltl ) (o1112)
1 354.02 2,15L_-.1,5 2,61_'t+04 3,86Ii.1-'17,,
2 01_.t-02 2,17B-15 3,0E-t.04 3,895.-.174 0_¢02 2,1,t_i-]5 d,OlO-t04 3,92F.,-17"I 01_'IO2 2 091_-15 5,05I04 3,94E,.17I 01_+()3 2 061r,-15 6,01_rO4 3 91_,-.LII 51_J-I.O3 2 O2_-15 7,OB+04 3 911_;-J72 OBlO3 I 97l!I-15 B°OB-r04 3 86_-174,0F_-r03 .l 841%15 9,0i_-t'04 3 B2L_,-ll7,0E+03 ,1 69E-15 l,OE4.O5 3 73L,3-17l,OE-r04 1 56B-15 .1,51_-105 3 31E-171,5F,-t-04 1 41L,;-15 2 01!I#05 2 96E-17 .
, 2,01_.t-04' I 30F_-15 3 01_-t05 2 42B-.174,0E-r04 9 76E.-16 40E-t05 ' 2 O1B-177,0Et-04 7 151_-.L6 5 OB.t05 .l 721_-1'11,017H-05 5 6-)_-16 6 01_-i05 1 501_,3-II 'I°55-l.O5 4 27_-16 7 OB-I05 .I ,.'.13L,'_-l'/2, OE-t-O5 3,44111-J6 8, Ol_,_-i-O5 I', 191r,-.I74, OI!H-O5 I, 9lE- if7,0P'+05 1,24E-168. Og-t 05 1.11F,-.'.I 6
._B,, t.)2,,i _)25, 51'11 580, t -, 583Refe_ellcL?.._. 32, 301, 519, 52.11 r. o ,
_LOr.Jti_;aCyI 30%
<-Pile total electron ,(letaChlllellt sectloll alld has(1) uross ( utllgle dotlbJ.e )
lloamlred by dor.qellseil aild Ktlyatt" (Ref, 32}, V
(2) Vet relllgle detachl_lent aecl Ryd.l.nej et al. (t1_[. 577)2 SImpsoll and Otlbody(Ref, 519)t Ile.tlmmeter et al,' (Ref, 581)t HeJnellieter eL al. (Ref, 521)t CoC]cdJ.ol.a(Ref, 582)t Hvelpltmd allcl Ai]dersell (Re[, '30.1),
(3) For double de.tac'hlllellt: set#i llyd.l.ilcj ct: a.l., (Ref, 577)I llelnellle:lei: et a.l.,(Ref, 581)I lle.inellleler el: al, (Re f, 52;I),
Chebvshev lqtt.t.r N Par_ulieter_. for C'tose SeCt;lOllS
SincJle dot. _lllill "-" I, 3E't 02 eV/allltl, _lllax = 8,0E-105 eV/alllClDotlble clot, [_111111-- 2,61_,-l.04 eV/alllll, 17,IIV.IX= 8,01_;l'05 eV/allltl
AO A1 A2 A3 ' A4 A,5 A6
SIrNIo clet.. -69.4085 --1.41471 -,58J042 -,0905120 ,032.1529 .0250996 .()003637[i2l)otlb.Le dot. -76,3306 -,578433 -,226903 ,0(l11455"1 .O.112528 -., 00347156 ,0004 02.14[I
Tile fit; representu tjle _J]llg].o detao'hlllellt croe_e_ t_ec:i'.:l.C)ll wJ_tll ali rlli_i dev.latloll of 0,4%Tile IIl_lXJ.llltllll dovlat: .lOll 1.13 O. l]% at; I, ()1_.)04 (_V/flllltl, ''
Tile f lt leprortellt.8 the dotlblt-_ (.letac'l'illlent. (:l:ofj£1 f_ectiOli wJ t:h _111 llila d(_,vJ.at.{C.)ll oi: O, 4%.,TIle lilaXhilUlli clevlatton is 0,7% at 6.01_t.O4 eVlallltl,
See apperldJ× £ol (:lleby.<|hev f_Lt. det.al.l.a,
O
=i
I_- ;I9
i ,
Ho-+H.,->Ho+__+oHe- + H2_-> He+ + + 2e
Ctoss Sectionvs. Energy'-'14
' 10 :--, _', ,,,,'rr .... , , ,'_,_",,i ...... i , , ,,,_n:'-r--r--r-r-i-rrr,i
i
_=He
X=He+
.-. 10"'Is.- _ "
Q.) ,--
c-,0 -_ Recommended
rb _ Dataor)09Or)
L) 16 Chebyshev Fit10- -
i ,,10- 17_J_L__L_J__L.L_LLIil __. i 1 ! LA.I-I.LI_.= .1 I _L_.L_L_LI_I.
"ld ld ld ld 10_Energy (eV/amu)
F-20
Cross Sections for Single and Double Electroll Detachment of lie- irl lle O
He- + He -> lte + He + e
-> lle_ _ lle ¢ 2e
lle + He + e He _ _ He + 2e
Energy Cross Sect_ on Energy Cross Section
(eV/anlu ) (tin2 ) (eV/ainu ) (cm 2 )
i. 2E+02 i. 27E-15 2.7E+04 4 18E-]72.0E402 1.29B-]5 3.0E+04 4 16E-17
3.0E+02 1.32E-15 4.0E_04 4 05B-17
4.0E402 1.33E-25 5. OE+04 3 90E-] 7
70E+02 1.35E-15 6.0EI04 3 82E-17
10E+03 1035E-15 7.0E+04 3 71E-17
20E+03 1.32E-15 8.0E+04 3 58E-17
40E+03 1.23E-15 9.0E+04 3 47E-17
70E+03 1.12E-15 1.OE+05 3 37E.-17
10E+04 1.04E-15 ].5El05 2.98E-17
20E+04 8.07E-16 2..OE+05 2.66E-17
40E+04 5.72E-16 3.0E+05 2.23E.-17
7 0E+04 4.07E-16 4.0E+05 i. 93E-17
I OE+05 3.22E-16 5. OE+05 1.72E-17
20E+05 ].94E-16 6.0E+05 1.58E-]7
40E+05 ],.lIE-16 7.0E+05 1.47E-17
7 0E+05 6.98E-17 8.OEr05 1.36E-]7
References: 519, 521, 522, 525, 575, 576, 57I, 5"18, 58], 582, 583
25_
Notes: (i) The total electron detachment cross section (single and double) has
e_ measured by Windl1_u et al. (Ref. 575); Nicholas et al.. (Ref. 578); Simpsonand Gi ibody (Ref. 519), W
(2) For single detachment see: Sweetman (Re]. 576); Ryding et al.
(Ref. 577); Heinenleier et al. (Ref. 581); Helnemeier et al. (Ref, 52]);Coggiola (Ref. 582 ).
(3) For double detachment see: Ryding et al. (Ref. 577); Heinemeier et al.(Ref. 521).
Chebyshev Fittinq Par_lleters for Cross Sections
Single det. Elnin = 1.2E+02 eV/anlu, _El,lax = 7. OE+05 eV/a]llu
Double det. Eml n 2.7E+04 eV/_uu, Ema x = 8.0E+05 eV/_ullu
AO A1 A2 A3 A4 Ab A6
Single det. -70.3313 -1.40200 -.626470 -.0569330 .0458639 .0]02]79 -.0052767/
Double det. -76.3309 -.57]055 -.112122 .0109146 .00565444 .00046]742 -.00146987
The fit represents the single detachment cross section with an rms deviation of 0.5%.
The ma×]mum deviation is ].1% at 4.OE+03 eV/aJllu.
The fit: represents the double detachment cross sect/on with an rms deviation of 0.4%.
The luaxil|lum der]at:loll is 0.6% at 5.0E+04 eV/ainu.
See appendix for Ci]ebyshev fit details.
F-21
He-+ He -> He + He +eHe- + He-> He+ + He .+2e
CrossSectionvs.Energy•,,--,-14"
ILl , , , ,,,,,l , _ , ,,,,,,j , ", , ,,,,,iI I IIIIII
: 1\=He + He
x = He + + He
_r
10 -E - \ \
_,D - \
C \\0 \•.+5 \\ Reco nnm ended(D \(u \ -- -Data
Of) \\\09 \CO \0 \
\ Chebyshev FitU -le \
10 - \\_ \_
•-\
NN.
\N
lf'_ -1: I 1 1 l I 1111 I I I t I1111 I 1 1 I I I1ll 1 .,,1 t I IlLIU
10_ 103 10¢ 10s 106Energy (eV/a m u)
F-22
QCro_s Sectior, s for Single and Dc_ble Electron Detachment of hl- in 112
bl" + H2 -> [,i + H2 + e
-> bi . + H2 -I- 2e
l,i + H 2 + e bi + i H 2 _ 2e
Energy Cross Sectioll Energy Cross Section
(eV]ainu ) (cm 2 ) (eV/ainu ) (cm 2 )
i. 5E+03 1.89E-15 1 5EI04 1.0OE-16
2.0E+03 1.91E-15 20E+04 8.79E-17
4. OE+03 1.81B-15 3 OEr04 7.40E-17
7.0E+03 ].64E-15 40E+04 6.67E-17
1.0E+O4 1.50E-15 50E+04 6.27E-17
1.5B+04 1.34E-]5 60E+04 5.98E-17
2.0E+04 1.23E-15 70E+04 5.76E-.]7
4.0E+04 9.45E-]6 8 0E+04 5.55E-17
7. OE+04 7.43E-16 9 0E+04 5.43E-17i. OE+05 6.30E-16 ] 0E+05 5.28E-17'
1.5E+05 5.15E-16 i 5E+05 4.83E-17
2. OE+05 4.46E-16 1 8E+05 4.67E-174. OE+05 3. IOE-16
References: 250, 522, 583, 588
',Accuracy: 25%
Note_._! For total electron detachment (single and double) see: Ailision et al.
(Ref. 250). For both single and double detachment see: McCullough et al. (Ref. 588).
Chebzshev Flttlnq ' ParaJueters for Cross Sections O
Single det. Eml n = 1.5E+03 eV/_unu, Ema x = 4.0E+05 eV/_ullU
Double det. Eml n = 1.5E+04 eV/ainu, Ema x = 1.8E+O5 eV/amlu
AO A1 A2 A3 A4 A5 A6
Single det. -69.2].00 -.932154 -.]98400 .0257913 -.001!]248 .00258484 -.00164526Double det. -74.5383 -.376194 .0491243 -.00831956 -.00]49259 .00388870 -.000530605
The fit represents the single detachment cross section with all rms deviation of O.2%.
The maximu,n deviation is 0.3% at 1.OEr04 eV/mm|.
The fit represents the double detachment (;ross section with an rms deviation of O.2%.
The maximum deviation is 0.4% at 8.0E+04 eV]ainu.
See appendix for Chebyshev fit details.
F-23
0 Li- + H., -> Li + H2 + eI_i- + H2"-> l_i* + H_ + 2e
Cross Section vs. Enen_ly-I¢
I0 , , "'r , , ',,, I , , ',' 'T-r"r-TTq --- , , , , , TTf
Z_=Li
x =Li*
"'"--.-._......._
10-1_ "_ ..IN
E _c- _-
'._ "-- Recommended¢2 "_® --Data
br)
0©
Chebyshev Fit
u 10- _1('1-17 l l I l II I|l l l J l LI.Jll t/'_.J
103 104 10_ 10_Energy (eV/a mu)
IIJ
i
F-24
Cross Sections for Total Electron Detachme_]t of bi- on }le O
bi- + He -> [,i, 5i +
Energy Velocity Cross Section(ev/_uu) (cm/s) (cm2)
1.8E+02 ]. 86E+07 4 22E-162.0E+02 i. 96E+07 4.56E-164. OE+02 2.78E+07 6.65E-16
7. OE+02 3.68E+07 8. O7E-16i. OE+03 4.39E+07 8.83E-] 6i. 5E+03 5.38E+07 9.57E,] 62. OE+03 6.21E+07 9.93E-] 64. OE+03 8_ 79E+07 I. 05E-157. OE+03 I. 16E+08 i. 04E-] 5i. OE+04 i. 39E408 i. OOE-15
i. 5E+04 1.7OE+O8 9.42E-162.0E+04 i. 96E+08 8.87E-] 64. OE+04 2.78E+08 7.43E,16
6. OE+04 3.40E+08 6.46E-!6
References: 250, 522, 551, 583, 587
Accuracy: 25%
Note: Reported values for cross sections correspond to the sum of thoseo_-6-_-sin gie and double detachment.
Chebyshev Fittinq Par6m_eters for Cross Sections 0
Eml n = 1.8E+02 eV/mllU, Ema x = 6.0E+04 eV/_llu
AO A1 A2 A3 A4 A5 A6
-69.6625 .18135 -.342099 .0241112 -.0117377 .00823347 -.00361753
The fit represents the above cross section with an rills deviation of 02%.The maximum deviation is 0 4% at 2.0E+03 eV/_uu.
See appendix for Chebyshev fit details.
L_-25
0 Li- + He -> Li, Li+
E©
c-O
RecommendedQ.) -- _@ - Data
0 L/) - ..-f"f _'_.... --(19 - ./'/"
U Chebyshev Fit/
Z
lO ,6 , , i L _JJJl l _ J J l Jill .I 1 I l_l
ld lo_ 1¢ ldEnergy (eV/amu)
OG. Cross Sections for Dissociation of Molecules and Molecular Ions
Page
H + H 2 -> H- + (H4 + H _) + e ....... G-2
-> H + (H + + H +) + 2e ....... G-2
-> H+ + (H+ + H+) + 3e ....... G-2
-> H + (H + H +) + e ........ G-4
-> H+ + (H + H +) + 2e ......... G-6
-> H- + (H+ + H) .......... G-8
H + + H 2 -> H+ + H + + H + + 2e ........ G--10
He + + H2 -> He + + H+ + H+ + 2e ....... G-12
He 2+ + H2 -> He 2+ + (H + + H) + e (via isocj) . G-14
-> He 2+ + (H _ + H) + e (via 2pou) . G-16
-> He + + (H + + Hl ......... G-18-> He + + (H + + H ) . e ...... G-20
-> He 24 + (H* + H +) + 2e ..... G-22
-> He + (H+ + H+) ......... G-24
O H2 + + H2 -> H+proj. . ............ G-26
H2 + + H -> H+proj. . ............. G-28
H2 + + H2 -> Heroj ............. G-30> (H _ + H) + H2 .......... G-32
H2 + + He -> TOtal H' . ........... G-34-> (H + . H) + He .......... G-36
H2 + H2 -> H+(Fast,Total) .......... G-38-> H(Fast,Total) . ......... G-40
-> Total Destruction of Fast H 2 Proj. G-42
H3+ + H2 -> Total Destruction of H3 + .... G-44
H2+ + H 2 -> Total Destruction of H2' . . . . G-46
H3+ + H 2 -> H+(Total,Projectile) ...... G-48
-> H2'(Total,Projectile) ...... G-50
-> H(Total, Projectile) ...... G-52
-> H2(Total, Projectile) ...... G-54
G. (Cont'd)
H3 _+ + He -> H+(Tota I) ............ G-56-> H2 + ............... G-58
HeH + + H 2 -> Total HeH + Dissociation Prod. . G-60
Hell+ + He -> Total Hell+ DissoCiation Prod. . G-62
q •
.' 0-2
Cross SectJ.cms for Double (DtsSoc.[at.l.ve) lonJsat:lon, Doub.le loii.l.zation with O 'Stripping, _ild Electron capture with lollizatloll for H-Atom ll]1[)actOli II2
li t- It,_ -> tl -t (H t .t I-t') -t. 2eH t t.t2 -> t-1' -t. (t-I4 ..t- t4_) -I 3e •tl .t tl 2 -> 11" .t (1t' + II')..t e'
(H + 2ti t 4. 2e) (1t_ -t. 21-I_ .t. 31_) (H- -t 2H + .t. e) ,
ElleiL'gy o I_] 11(3 l;'g y tj F]11_, i' cJ y t,
(eV / allltl ) ( 'ciiI2 ) ( eV/ illlltl ) (C,'lll2 ) (e V/ i:llllll ) (Clll2 ')
5.0E+03 1 62111_19 '5.7E-i.03 ]..061!',-20 4,7E-t-O3 2 /8PJ-..206.0F_+03 2 59E-19 7.01_403 t.65E-20 7,011.+03 6 6515-207,0E+03 3 90E-19 1.0E-i04 3.871.q-20 8.5E+03 i 001_-198.0E-I-03 5.401_-19 1,31_+04 9,90E-20 9,01g-I-03 I 17iE-199.0E4.03 7 O4B-.[9 .l 5B4-O4 ' 1.38It;-19 .[ 0E+04 .1 51E-191,0E+04 8,88t_-19 2 0[_.t04 2.'19[_-19 .1 5E+04 3 22E-.t9]..5E-#04 1 9],I_-].8 2 5_:4.O4 4.68l!:-19 20E+O4 3 69F,-192.0F,+04. 2.58I_-.L8 30E+O4 6,32E-]9' 2 5E-i:O4 ] 471_.-193.01_+04 3 22E-18 ' 3 5F,+04 7.82_I--;19 3 0I_+04 3 0517,;--;1.94.0E+04 3.35E-]8 4 OEr04 9.19E-]9 3 5lg+04 2,70F,-]95.0F,+04 3 lIE-18 4 5E+04 1.001};-18 4 01_;.IO4 2.43E-19
5 0E+04 ;I.]41_-18 4.5_1:104 2.22E-]95 2E-t-O4 1. ] 71!:-]8 5,0[..1-t-O4 2.051.,i-19
Referencei 30
Accttracy I Ui/kllowl_
NOtE,Oi liJ.lletic, enercly of tile slow H+ .Lolls t s at_lgrO× inlate] 7 9 eV,
Chebyshev Fittinq Par_mleters for Cross Sec-:tions
(H -t- 2tt + # 2e) l_inll 1 = h, 0I_i-t03 eV/anltl, t'.imax =. 5. OEt-04 eV/ainti= 5.7It]-t.O] eV/aliltl, _, 5 2E-i-04 eV/ailltl( It_ -_ 2H* -F ]e ) F-'lllill t"]lllaX °
(H- + 21.1_ -I- e) I_mill = 4,7E4-03 eV/ainu, [qiuax = 5.OE+O4 eV/ainu
AO Al A2 A3 A4 A5 A6
(H _ 2il # _ 2e) -82,,5844 1.50087 -.51416[] -.0138263 .O274858 -.00853833 .-.0116637
{H # 4 2bi 4 4 3e) -S6.q'235 2.46221 -,30;1192 -..10511,12 .0379990 -,00412294 ,O122290
(H- _ 21.1 + _ e ) -86,,8910 1,09636 -.754871 -.0093284,] .08554"11 ,03001122 -,0393792
q'he f lt: represents t:lae (H -t 2li' 4 2'e ) c:17o£I,<_sect.LOll with aJl rills devtat: .fOil O|: 0. ,q%,The l'IlaXillltlIlldev,tat.t.Oll ].s ], ] % cat 6. ()t!',f()3 I._V/7lllltl.
The fit represent;s the (1t+ 4. 21-1+ -t 3e) cl:os,q Bec't;JOll Wil;h 6111rills ¢levial;Jon cJf .I,R%,The Illa×J.¢llUlll devJatJ.oll ].s 2.9% at 1,01!',.04 eV/alUU,
The fit represents til(, (11" t 211' i o) c'i'olJ!l; sectiC_l_ with _111rlus ...... iat.toii c_f .1.3%.Tile IllaXillltllll (_lev.tat[oll t.s 3,O% ElL B,SEi03 _)V/_lnltl.
See appendJ.x for Chel:,ynhr_v !ii: clot at .ts,
O
0-3
G_4
OCross Ssc,trolls for Dissociative,. Ionization or
I.I2 .Ill Co/.li,o.[ons with Hycl[ot]el% At:olllS,
II -O I1_ -> II t H _ II _) I- e
. via ]so_j State (Curve 1) v:ta 2t)0_1 State (Cul:ve 2)
F,nergy Cross Sectiol_ I_zlerqy Cross Section( eV/ainu ) (cm2) (eV/_uu ) (cre_)
50E+03 6.40E-19 5,O_+03 2.''_"-182al'.',
60E+03 8.21E-19 6.0E+03 3,23E-1870E+03 9 67F,-[9 '/,OE+03 4.12E-18
8 OB+03 ] 09E-]8 ' 8.0E+03 4,97B-]8
9 OB+03 i IBE-18 9.0E-I03 5.761_-].8
10E+O4 1 25E-.18 }.OEr04 6.4/I_--].8.I 5E+04 i 40E-18 1,5E+04 8.07E-18
2. OE_04 I 38E--18 2. OEr-104 7,49E-18
2.5E+O4 1 3'1E-.18 2.5E_04 6.24E-18
3,0E_()4 ] 23E.18 3.OF]t04 5.13F,-J83.5B+04 1 17E-18 3.5E._04 4.]1E-18
4.0B+04 .1 .I2F,-Ig 4.OE+04 3.24E-184.5E+04 1 06E-18 4.5B'I04 2.51B-1_
5.ONTO4 I 00F,-18 5.0N+04 ].97B-18 ,
Reference: 30
Accura'cy I Unknown
Notesl (i) Cross section values plot;ted 111 curve I re[sr to t,hc, d:Issoclatiou (_f the
H2-_"_u from tlie .Isog state. Energy of t:he _II.ow loll .Is Appro×imately zero. (2) Cross
SectiOn values plotted ill cuive 2 refer to the electron transitiolls to Life 2po u state
,and also to all the excited electron states of the H;!_ ion. Eile_gy of tile slow ion
is approximately 7 eV.
Cheb_vshev Fittlnq Parmnet:ers for Cross Sections
(via iSOg state Eniln = 5,0E+03 eV/an|u, Ems x = 5.0F,+O4 eV/ainu
(via 2po u state [_'HIII1 = 5.0E+03 6,V/allltl, Ellis x = 5.0Et04 eV/_ul_tl
AO A I A2 A3 A4 A5 A6
(via 'Iso state) -82.7739 ,176787 -,277606 .0497140 .-, 0008033B;' - '002"/7426 -.OO425677
(vla 2POgu state) ' -80,O(_22 -,0507"17 -,553490 -.O1,I0905 ,00B50407 -,00531411 -,O0795596
The fit represellts the cross aecl:ion via iSOg state) w:[th 6111 [lli[lclev.latioll of 0.2%,The maximum devlatlou is 0.4% at 3,0B_04 eV/ainu.
The fit represents tile cross section (via 2po u state) with all rms deviatiorl or 0.6%.
The maximum clev:[atiorl .is ].2% at- 4.5E+O4 eV/ainu.
See appendix for Cllsbyshev fit: details,
O
61-5 _
OH + H_ -> H + (H+ H*) + e
10-19 i i i i i _ i llo_ lo' ld
Energy (eVJam u)
G-6
OCross Sections for Dissociative Iouization of }I2 by li-Atom InlpactAcconlpanied by Stripplnq of tile H Projectile
1t ,+ t-12 ->, H_ t- H 4-I-1 _) + 2e
. via Isog state (curve ]) via 2po,t st atc=_ (Curve 2)
E1_ergy Cross Section Energy Cross Section
(eVl_uu ) (cm 2 ) (eVl_uu ) (cre2)
5.0E+03 2.49E-20 5. OE+03 2.38E-20
6.0E+03 3.27E-20 '6.0E+03 5.83E-20
7. OE+03 4.07E-20 7. OE+03 1.07E-19
8. OE+03 4.91E-20 8. OE+03 1.66E-19
9. OE+03 5.77E-20 9. OE+03 2.34E-19
i. OE+04 6.68E-20 i. OE+04 3.07E-19
i. 5E+04 ] .15E-19 i. 5E+04 6.88E-19
2. OE+04 i. 66E- 19 2. OE+04 I.04E-18
3.0E+04 2.73E-19 2.5E+04 i. 26E-18
4. OE+04 3.65E-]9 3.0E+04 i. 37E-].8
5. OE+O4 4.10E-19 3.5E_04 i. 37E-18
4. OE+04 I. 3 2E-18
4.5E+04 i. 23E-18
5.0E+04 I. ]3E-18
Reference: 30
Accuracy: Unknown
Notes: (i) Cross section values plotted in curve 1 refer to the dissociation of tlle
H2--_'_n via the iSOg state of H2_ . Energy of tile slow ion is appro×imately zero. (2)
Cross section values plotted in curve 2 refer to tile dissociation of the H2 ' ion via
tl,e 2po u state and also all higher excited electronic states of tile H2. ioll. Enerc4y
of the slow ion is approxinlately 7 eV. I
C._hebyshev Fitt inq PaL-_,leters for Cross Sections
(via iSOg state) Etllin = 5.0E+03 eV/muu, Eml x = 5.0E+04 eV/mllU
(via 2po u state) Ernin = _,OE+03 eV/_l|U, Emax = 5. OE+04 eV/auu
AO AI A2 A3 A4 A5 A6
(via ISOg state) -87.2426 1,43882 -.0948243 -.0308580 -.0190257 -.00744929 -.00364561
(via 2po u state) -84.8972 1.86566 -.764017 .0497586 -.0434187 .0151155 .00206675
The fit represents cross section (via ISog state) with an rms deviation of 0.1%.The maximum deviation is 0.1% at 2.0E+04 eV/_m_u. '
The fii: represents cross section (via 2po u state) with an rms deviation of O.3%.
The ma: inlum deviation is 0.6% at 1.5E+04 eV/6uuu.
See appendix for Chebyshev fit details.
(]-7
0H + H2 > H+ +, (H -k I-t+) + 2e
Ct-ossSection vsoEnergy-17
IU , I I i--"r" i i i I i i , i i i J i
10-18_ ,,c_ - .I
_ _
c- /© -
'-_ Recommended_) -
® --Data(/-)Or)C./1
8U 10-lg _ Chebyshev Fit
10-2c I .... i l i i i Ill l I J l ii I l
1o_ lo" lo_Energy (eV/am u)
4
G-8 O
Cross Sections for Dissociative Electrot% Capture fr:ore H 2 by H-Atoms
H 4 H z -> H" 0 (H+ + H) ,
via isog state (Curve i) via 2po u state (Curve 2)
Energy Cross( Section Energy Cross Section(eVl ainu ) cm= ) (eV ImllU ) (cm 2 )
5.0E+03 8.20E=20 5.0E+03 2.91E-196.0E+03 i. 05E-19 6.0E+03 4 •72E-19
7.0E+03 1.26E-19 7.0E+03 6.57E-19
8.0E+03 1.45E-19 8.0E+03 8.34E-199.0E+03 1.63E-19 9 0E+03 9.97E-19
1.0E+04 1.79E-19 1 0E+04 1.15E-18
1 _.5E+04 2.18E-19 i 5E+04 1.45E-18
2.0E+04 1.81E-19 2 0E+04 i.13E-182.5E+04 I. 31E-19 2 5E+04 7.75E-19
3.0E404 1.02E-19 3 0E+04 5.33E-19
3.'5E+04 8.51E-20 3 5E+04 3.61E-19
4.0E+04 7'.39E-20 4.0E+04 2.48E-19
4.5E+04 6.68E-20 4.5E+04 i. 78E-195.0E+04 6.17E-20 5.0E+04 I. 27E-_[9
Referencez 30
Accuracy: Unknown
Notes: (I) Cross section values plotted in curve 1 refer to the dissociation of the
H2-_--_n via the isog state: of H2 . . Tile energy of the slow particles is approxlmately
zero. (2) Cross section vah, es plotted in curve 2 refer to the dissociation of the qPH2 . ion via the 2po u and also all excited electronic states of the H2 _ ior,. The energy
of the slow particles is approximately 7 eV.
Chebyshev Fittinq Par_lleters for Cross Sectioils
(via isog state) Emi n = 5.0E+03 eV/mllu, Ema x = 5.0E+O4 eV/muu
(via 2po u state) Eml n = 5.0E+03 eV/a_]_u, Ema x = 5.0E+04 eV/edm_
AO AI A2 A3 A4 A5 A6
(via ISog state) -87.2731 -.218951 -.522211 .073662'7 .0971637 .00270336 -.0307]72
(via 2po u state) -84.2975 -.438944 -.978064 .0211660 .0476037 .001_9449 -.0175091
The fit represents cross section (via iSOg state) with an rms deviation of 0.8%.The maximum deviation is ].5% at 2.5E+04 eV/ainu.
The fit represents cross section (via 2po u state with ali rms deviation of 0.8%.
The maximum deviation is 1.1% at 4,,0E+04 eV/_uu.
See appendix fo,: Chebyshev fit: details.
0
(]-9
OH + H_ > H- + (H + H+)
Cross Section vso Energ.y-174f'_
/U I-- ' I I J I'lll I I ' '1 I' f Ii,II
- _=2
×-1
1O-18 "'fX'-"X//
E - / \o - / \_-- _ / \c / \o - / \
"+_ ' \ Recommended_ - _ \¢) ----Data
rr) / \ \O / \_- // \U \ _ ......, Chebyshev Fit
lO-- x,/10__ / \Nx\\\
-- "'x
10 -2 _. 1 1 L 1 1 i I I 1 1 l l i J I I L
lo_ _o" jo_Energy (e_v?'am u)
ill
C_-I 0
Dissociative Double Ionization Cross Sections for
H_ + H2 -> H _ 4. LI+ + H _ + 2e
F,nergy Velocity Cross Section(evI_llu) (cmls) (_:n,2)
I. ON+05 4.39E+08 3,96E-19i. 5E+05 5.38E+08 1.79E-192.0E+05 6.2 IE+O8 i.O2E-193.0E+05 7.61E+O8 4.9OF7-207.0E+05 1. ]6E+09 I•]7B-20
I.OE+06 I. 39E+09 7.16E-21I. 5E+06 I. 70E+09 4.30E-21
2. OE+06 i. 96E+09 3.26E.-213. CE+C6 2.40E409 , 2. _9E-2]
Reference: 365
AccuracY: Within factor of 4
No_._te_ The data are reported for' the H 2 irlternuclear axis oriented at: 90 °
and 300 relative to the ion bemu direction and no apparent difference wasfound between the measured cross section va].ues.
C!lebyshev Fittinq Par6mleters for Cross Sections
Elllin = I. 0E+O5 eV/a111tl, Ema x = 3.0E+06 eV/mm_ O,
AO AI A2 A3 A4 A5 A6i
-90,4247 -2.58979 _ ,296205 ,0536430 .007476U6 .00133207 .00152342
Tile fit represents tile above cross section wlth an rnls deviation of 0.6%.The maximum deviation is 0.9% at 2.0E+05 eV/mini.
See appencllx for Chebvshev fit details.
G- 11
,.
0H+ -f. Iq_-> H+ + H+ + H+ + 2e
Cross .__u,ction vs. Energy-119
10 / i-------T--'--T ', , '',' ,",'1 _ , ....... 1 1"1 ,111
i0-'_IN
E
c" .©
'-D Recommended(D
_ _Data_O
0..... Chebyshev, Fit
G-12
Cross Sectiolls for the Dissociative Double ]on.lzat]on of 112 Ely Fast lle_
lle_ + H2 -> l-le_ -0 li_ I FI_ I 2e
Energy Velocity C_:oss Sec".t.iolI( eV/ainu ) (ClU/S ) (clu _ )
2.5E-103 6,95E-t-0l 5. C)0E-1.83. OE-103 7.6 iE-1-07 4.22E-] 84. OB+03 8.79F,-1.07 3.12E-]87.0E+03 i 16E+08 1.62[,I-]8I.OE+04 1 39E+08 ],02E-]81.5E+04 1 70F,+08 5.89E-]92.0E+04 ] 96E+08 3.9]E-]94.0E+04 2 78E-t08 ]..4()E-.197,0E-I(14 3 68E+08 5.95E-209. OE+04 4 17E+08 4.02E-20
Reference' 482
ACCu[.ac'yl The absolute cross sectioll values are estimated to wltllin afactor of 4,
Note_ The data are reported for- the H2 interluiclear ax.|.s oriented at 90 °
slid 30 ° re.lat:ive to tile JOll be_uil direct.l.on, £-llldno apparellt d.|.fllel:ence wasfound between tile cross section values.
Chebyshev Fittinq Par_ueters for Cross Sections iv
Emi n = 2,5E+03 eV/ainu, Ems x = 9,0E+04 eV/ainu
AO AI A2 A3 A4 A5 A6
-84.2206 -2.43620 -.]34853 .0237"112 -,00240081[ ,000622206 -,00103783
The fit represents tile above cross sect-ion with an rms deviat:lon of 0,]%.The lllaXJlllUIlldeviation is O. 2% at ]. 0E+04 eV/ainu.
See appendix for Cllebyshev fit details.
g-13
QHe++ H2-> He+ + H+ + H+.4-2e
Cross v,ec,tion vs. Energy-174z"_
/U -- _ r I I I I '1 ' I 'l I ' ' r_" I '1 '' 1 I' I 1
- &
- \\\
\\
\
10-, _ ",,,r,_ - \
E - \_ - N
_ NC \,0 - \+-' \ Reco m m ended
LP - \ xk -Dato(/'_ '\
_ \V) \bO \0 \
\ Chebyshev FitU -19 \1(') - \\
"" _X
- \- \
"\
--* \
_ \\
,-?
lC)" _ _ , ,, _ ,,l J, l l I I_Z_.L_t_
.lo_ _o_ lo_Energy (eV/e m u)
0...14
q
Cross Sections for the Dl_Isc_ciatiw_ 1onizatlcm oI'. I.I_ by Fast l-le2!
He 2+ -t 1-12 -> He"_ t (I.1_ -t, H -t- e
Energy Velocit!/ Cross Sect:lotl(8V/all[|i) ( C,III/S) (till2)'
3.8E+03 8 56E+07 1.10F,-194.0E+03 8 79E407 1,38F:.-].95.0E4,0'3 9 82B+07 2.74E-1.96.0E+03 1 08E4.08 4.31[_:-197.0E+03 :t 16E+08 5.63E-198.0E+03 1 24E-I08 6,27E.-199.0F,+03 1 32E+08 6.48E-19].OE+04 1 39E+08 6.57E-191.5E-F04 :1 70E-t-08 6.65E-192,0E+04 1 96E+08 1.04E-182.5E+04 2 20E-I-08 1.81E-18
Referencel 95
Ac.curacy_ 20%
cross sections ' .values refer to the ionizat:l.oi_. wJ.thThese
ciation of H 2 , La the Isog state of the 1-I2_ ion.
_shev FittJ.nq Par_ueteL'F.] for Cross Sections
.-z' I_mi n = 3.8r.,:+03 eV/mini, Ema x 2.5s-t-Ozl eV/a.mu -
AO A1 ' A2 A3 A4 A5 A6
-84.1813 1.1209.1 --.170391 .3].9582 .0335842 -,O467173 -.0198"199
The fit represents the above cross sec:t_on witll an nl_s dev_atlol_ of ]..0%,The lllaxilllUII1 deviat.[oll is 1.3% at 5.0_:-t03 eV/£Hiiu.
See appenctix for Chebyshev £J.t detalls.
r
b
a-15
2+
He + I-I.2 -'> I-le2+ + (PI+ + H) + e
<-.r-,:,ss::;ec:tionvs. F-nergv--17rlf'_
lO r--- , ' ' , , ' ,'l , "-r " ,_", , ,T"_
E /0
c.0
'-_ 10-le _ / Recommendedo / -- -Data(') /
©
UL Chebyshev Fit
/////
- //i
,]0 -1_ I J , I ,_, I I I II ,_ l I _ J _ i J
lo_ lo, .lo,Energy (eV/a m u)
0]-./6
Cros_ Seotj.oi]s .for. the l;).t._lsociat:Lve [Ollizat.l.orl oi! II;i by FaKtl: He 7">t ' @
lte. 2° -t- 1.12 -> 'He 2_ 4 (1-1_ + H) .i e, ,
[']liergy Ve].oci t:7 Cross ,getr ] o11( eV/alltU ) ( till/u ) ( Clit _ )
2 5E-I'03 6,95E+0I ],46E-1930E:I-03 7,6 ]I.'1.IO7 2,05E-]94 0E4-03 8,79E-IO7 4,28B-1950E+03 9,82E-I.0I I, 94E-1960E+03 ],08[{',-f08 ], 05l{',-187 0 E-t-03 ]..I. 6 l?,-t.08 1.23 F.,- ;l 88.0 E+ 03 ] 24 F,-I.08 I. 35 ['I- ] 89.0 E.t,03 ;1 32 E -i.08 ].. 42 I!',- ]. 81. Ol.]-i 04 ]. 39E-i.08 :I .46[_-181.5E-I-04 i "/DE+OB 1.53E-18
2.0E+04 ] 96E'I08 2.23E-182,,5E+04 2 20E.,-t.08 3.13E-.|83.0E+04 2 4]E+08 4.221_-]8
Referencei 95
Accuracy..!, 30%
Notes i (1) The cross sect:ton valtles are for the J.ollizat i(:ul withdissociation o]7 H2, via the 2[)ou state of 112+, SeE: re,[erence 95. (2) The
llleasured energy of the sJow JOl] is approXilllately 7 eV.
@.Chebyshev FittJ.l]q Parailetei.'s .tor Cross Sections
= , , _' = 30 I.']+04 eVlamuElllill 2 5E-i-03 eV/mllti Lilla × .
AO A1 A2 A3 A4 Ab A6
-82,9850 1052994 -, 280].53 ,246249 .0922114 -,0977812 -,00881272
The fit represents the above cross sectioll wit;h ai] rills deviatioi] of 2, ]%.The lllaximunl deviation is 2.9% at; ]., 5I_,_+04 eV/allltl.
See appendix for Chebysllev _it detailS,
(:1- .1."1
q
t-le:_+-.I-.I-1_-.'> He_+ + (H+ -t-I--I)+ e
-17
(Dx,._J
C0
'-_ 10-lE Recon'imended
O Lp -® - Data
l r )
o - FitU - _.euysuev
10 -19 ,, i 1 i 1 1 i _ Jl 1 l _ J i i _ l
"1 d' 10_ I 10_
Energy (ev/a m u)
g- 1.8
Cross Seottol|s for Di_laoc_.l.at lye I!lloct:rorl O,:.lpl.ttre frolll t1., 13y F'_-I_II' l-le 2_ @
He _'_ .t. II2 -.> I-le _ .t (11_ + H)
Energy Velocity Cross Sect:.i oll(eV l_ml ) (c m/,_._) (cm _')
1,3 F,+03 5 01 E.I.07 2.7 "1[!',- i 81.5 F,-t.0 ] 5 3 8 Br C)1 3 0.1.E- 182.0 Hl+03 6 21.I_-I.0 "I 3 47 I__;-183.0E+03 7 6lE-I-D7 4 37E-184.0F,+03 8 79E-I.07 5 25g-:L8 '5.01P,.t03 9 B2B-tO/ 6 17E-186,0B-t.03 I 08E-I.OB 6 96E-:18
7.0B+03 ] J 6E:t08 7 79E-188. OB+03 I, 24B-t.08 8.5.[E-:I 89, OE+03 ]. 32E-108 9.3 :IE-181.0E4.04 i. 39E-I-08 1,02E-- 17
1.5E+04 1,70E-t,08 1.27E-172. OB+04 I. 96L,_-I-OB 1.29E-.| 72.5B-t,04 2.20E-F08 ]. 29E-17
Reference: 95
Accuracy1 20%
Note: The cross section values ale £oi: capture wiLll dissociation II:ore the
_state of the H2 * ]on,
Chebyshev Fit tillCl Pat_llete_s for Cross Sectlolls @
Eml.n = :l.3E-103 eVlamu, Emax : 2.5E-I04 eV/_mul
AO A] A2 A3 A4 A5 A6
-79.1499 ,840316 -.0633082 -.078]071 -.0271766 .00205805 .00727217
The fit represents t.l_e above cross secLio_i wit:ll al_ tlil£1deviat ion of 1,0%,The maxlmtull deviat.l.oll :l.s:I,5% aL 2,0[,;-I.04 eV/aillu.
See appendix for Chebyshev lit details,
I
i
i
O-19
He2+ -t- H2 -> t-le+ + (H+ + H)
C
C oss ,:Jectiortvsl -F-nergy-16 ('If",
IU w t" i i--1--'T-T-I I r--;:-- , i I I i i ,
f-_
E©
,._i"
c, /.-_--A0'.,cs 1 __ Recommendedo lo-- /
i ® - _DataW-) //
c> - /I_-- - ..... Chebyshev FitUt/
_ //
-_,
'],__0"'1 i 1 i i i i i i I 1 i 1 i i _L_L_I_
lo' lo_ lo_Energy (eV/a rn u)
O , .
G-20,
CroSs Sections [or Dissociative Electron Capture withIonization in Collisions of Fast He 2. with H 2
He 2. -t. H 2 -> }.le _ + (,I-|"r 4- H_ ) + e
Energy Velocity CrossSection
(eV/ainu) (cmls) (cre_)
i. 2E403 4.81E+07 i. JOE-16i. 5E+03 5.38E+07 i. OIE-162.0E+03 6.21E+07 8.84E-17
2 5E+03 6.95E+07 8.01E-173.0E+03 7.61E+07 7.47E-173.5E+03 8.22E+07 6.84E-174. OE+03 8.79E+07 6.01E-175 0E+03 9.82E+07 5.04E-1760E+03 ].08E+08 4.90E-1770E+03 1.16E+08 5.11E-17
80E+03 1.24E408 5.53E-1790E+03 ].32E+08 6.10E-]71 0E+04 ].39E408 6.54E-17I. 5E+04 I. 70E408 "l.88E-1"I2. UE+04 i. 96E+08 8.57E-] 72.5E+04 2.20E408 8.70E-]7
Reference: 95
Accuracy: 30%
Note: The measured energy of tl]e slow H + ions i._ approximately 9 eV. O
Chebyshev Fittinq Paramleter s for Cross Sections
Emi n = 1.2E,03 eV/6uuu, Ema x = 2.5E+04 eV/_uu
AO A1 A2 A3 A4 A5 A6
-74.1562 -.104398 .2"17805 .00632922 -.101311 -.0247870 .05]]068
The fit represents the above cross section with an rms deviation of 2.9%.The maximum deviation is 3.9% at 2.0E+03 eV/ainu.
See appendix for Chebysl]ev fit details.
G-2].
'i
2+ e + +He + H.) -> H + (H + + H ).+ e
Cross ,c_ectlonvso Energy ,IO-;5 , , ',....., , , ,,I , ,, , , , , ,,
-. ,.
--
t'1
EO
'_,.j
c-O
.._ le _...._.._ Recommended@ _- Data
bo
0o . _....__?...LOL-. ' ,U \ ..... Chebyshev Fit
10 -17 I I _. J I I.I, I I I J i i .j 1
lo_ lo_ lo5Energy (eV/o m u)
0-22
Crosa Sections for Double (Dissociatlve) ]ioll]zatioN of H2 By Fast He _+ O
He 2+ + H2 -> He 2_ + (H 4 + II*) + 2e
Energy Velocity Cross Section(eV/auuu) (cre/s) , (cre2)
2.5E+03 6.95E_ 07 ]. 44E-19
3. OE+03 7.61E4 07 2. ]5E-194. OE+03 8.79E+07 4.24E-]95.0E+03 9.82E+07 7.90E-]96. OE+O3 I. 08E+08 i. 07E-18 "7. OE+03 i. 16E+08 I. 25E-]88. OE+03 I. 24E+08 ]. 35E-189. OE+03 i. 32E+08 ]. 39E-] 8]. OE+04 I. 39E+08 i_ 44E-18i. 5E+04 ]. 70E+08 I. 52E-182. OE+04 i. 96E+08 2.24E-183. OE+04 2.4] E+08 4.23E-]8
Reference: 95
Accuracy.! 30%
Note_.__!The measured energy of the slow H+ ions is approximately 9 eV.
Chebyshev Fittinq Parmueters for Cross Sections
Emi n = 2.5E+03 eV/aullu, Ema x = 3.0E+04 eV/amlu
AO Al A2 A3 A4 A5 A6
'82.9515 1.54494 -.254833 .255864 .07496]3 -.i]3726 -.0359609
Tile fit represents tile above cross section with all rms deviation of 2.0%.The maximum deviation is _.4% at 4.0E+03 eV/ainu.
See appendix for Chebyshev fit details.
G-23, q
OIb
bte2++ H2 -> He2++ (H+,+ H+),-I--2e "
L t__,_s{:-.,ectioIlvso Ener-gy• - I'1
I0 , , _--r---__l T_, , , , ,1-,-
#
J
f'N ,,
E(J -t
,,._j
_ , ,
0
i 0 10- - Recommended¢) - _'DataDO
cs)
U - ---- Chebyshev Fit
10-19 i i i i i i 1 li i , i i i i i ii
'ld 10+ ldEnergy (eV,/omu)
I1
G-24
Cro_s Sectton_ for (Dtssoctal:Jve) Doub[e E]ect-ror_ CapLure from tt;, lty F'a_4t. l-lc __ 0
l-le __ + 1t2 -> He + ( H) -t I-I) )
l_:t]ergy Ve]ocJty Cross Section( eV/a.llltl ) ( cl,J./B ) ( C'lll z )
:L. IE+03 4.6 ].E+O'I 5. ]. hF_,-,I 7i. 5E+03 5.38E+07 3. OOE-172. OB+03 6.21B+07 1.7OF,- 1,72,5E+03 6,951']+07 ], 45E-173, OB+O3 7,61E+07 ],42E-17
4. OE+03 8.79E+O'l ]. 68P]-175, OE+03 9,82E+07 2,14E-] 76,0E+03 ], 08E+08 2,55E-177. OE+03 1. ]6E-t-08 2.90E-178. OE+O3 i. 241_]+08 3.23E-179. OE-I-03 ]. 32E-F.08 3.49E- 17I. OE+04 1.39E+08 3.75E-17i, 5E+04 ], 70E+08 4,42E-.]72. OE+O4 ], 96E+08 4,59E -]72.5E+04 2.20E+08 4.48E-I7
Reference_ 95
Accuracy: ]5%
Notes : None
Chebyshev Flttlnq Parmueters for Cross Sections O
F,1]llll= ]. 1E+03 eV/__UllLl, En|ax : 2.5E+04 eV/alliLl
AO AI A2 A3 A4 A5 A6
-75,9688 .211347 .43"/455 -,355845 .023[353 .0708411 -.0517123
The fit represents the above cross section with an rms deviation o[ 1.2%.The maximum deviation is 2,9% at 2,0E+03 eV/ainu.
See appendix for Chebyshev fit details.
z
®' He_:".-i- H:, ....:> I--le-i- (H" .-4-H+)
i
C,"c r<->_:<--._:,,->:,¢_¢ti<-,i_v_:,Er-leiqy(i- i 6..... 1-------F---_--r---q---r--i--l--i j 1 --T-----F---T--iF-T_T-F -
i '._ RecommendedcD® ----Data
or)cs30L. Chebyshev Fit
'L)
, ,
10 1: I , I i I i i I I 1 l . I_ 1 i i i i i
ld _o_ _dEnergy (eV/amu)
0-26
Cross SecL.l.olls l:or t.h(_ C.'oiwo r[_:Lon of |,'ast II;. _ Ions :1tlt:o O
Fast: l"rot on,q 111 l'assage 'Ph Lo*,iCjll II_:
II_:' _ I-I., -_ H_rro:).
bow Energy HIgl] Eliergy
Energy Cross Secttoil l,]iie]:cjy Crc:lsu: Soc;t.:t oil,( eV/allRl ) (Clll i' ) ( C-:V/_-IIIItl ) ( Clll 2 )
].6E-t-O0 3 3.[E-17 .I. 5E-tO3 2,O9E-162.0E+O0 6 46E-1'I 20E.tO3 2.26E-.[62.5E+00 8 09E-17 40E+03 2.42F,-]63.OE-I.O0 8 66E-17 7. OE+03 2.3]E-]63.5E+00 [4 67,g-17 _I OE-i-04 2.13E-]64.0E4-00 8 58E-.17 .I hE-104 1.88E-164.5E+00 8.33E-17 ] 8E.iO4 ].8GE-165. OE+O0 7.96E-].7 20E-t 04 1.86F.,-:L6
3 0E-1.04 2.23E-1640F..-I04, 2.30E-[65 OF]+04 2. _6E-]680I,H-04 1.99[!:-] 6.l OE+O5 .1,80E-,] 6] 5E.) 05 1.46E-162 0 E-i-0 5 i • 21 E- .i 640E-I-05 "1.43E-1770E+O5 4,22E-1"110E+06 2.70E-],71 5L":+06 :I, 46E-]72 0E-lO6 1.11E-1740E-t06 6.21E--18
7 0E+06 4. ]lr.,',-.l.8 J.I 0E+07 3.28E-18
References. 86, 208, 210, 2]4, 2]8, 219, 527, [$28, 53J, 557, 558, 559,57]., !$90
A c___c_ 25 %
Notei No attenlpt has been made, to .tnterpo]at:e between tile .lu,,q-ellelFgy data al]dTdata taken at hJ.cJhet energies.
C!lebyshev F.Ittlnq Pairanmt:ers for Cross Sections
LOW Ellergy Blllirl = ]. 6E-t00 eV!alllLI, = 5 01_i]+00 eV/allltl
Hi qh Bl]ergy gnl:t.rl i 5E403 eV/_llt.I l!:lll_lX '. =" . , glila × = i. 0E-t-07 £#V/_.lllltl
AO Al A2 A3 A4 A5 A6
Low Energy 74 4493 .351878 .249279 .0781924 O" ,.r . -.- • .... , 29.)._2"I 00853617 00490330Higll Energy -74.9261 -2.19443 -.855834 .042.l.30I .216227 .0921147 -.0893079
,
The flt represents the Low Energy cross sect:ion w:itil an rlils deviatlori of 0.2%.The rllaXillltllll dev:iIatJ.on :l.s O. 3% at: 3, '7""t00 eV/allll.I.. l_5
The fit represents the High Erlerc.ly cross se(<'t::t.oll wit:h ali 1:111;-Itier]aL]oil (._t} 6.3%.The luaxiinuiil dev.iat:.t ori :1s ] 2.4% at: ]. 8t7;i-04 f:_iV/allltl,
Ser append±x for C'.hebysllev ]:Jt. del:aJ.l.s, _ilP,
q
0-27
I--t.,+ -F H_ -_ bl+ ',. " ProJ,
Cross Section vs,,r:-_-..rser-gy,
1O- 15z__rTTTITIIT__I_rI_Tm[__7_I_FTrmI__T_FITrlTIT__I_F_TTmI__I___I_ITIIF__I_I
-- "
L_= L.OWE
_.#_ _'"_ × = HIGH E
.--.. 10-'6_ '.
,.C..:_
LT..0
'+_.s Recornrnended,(.,..) ,-
® __ Dat.a(/-)(,f)(li
8..... Chebyshev Fit(.)
- :1C)-17._
i,
1O- 1___LJ_LUmE.__LJJ_U_L_z.__Jm! : '_LLLU]L__LU_LU___J_L.LU.U4___LL_U_
IG lo' lO_ lo_ 1o_ lo_ td_ ldEnergy (eV,/cirnu)
C:I- 2 ftq
'(_itJBI_ _c._c:L.ILJIII.J l.c_v t. ll_ ('(*lllV(.,tNl(Jll (.:if I,'ilflt. I1,,__ l(lllFI lilt:li Ql_'ar.lt: Pl ()L('_IIII [ i1 I_:lfilf.i:i(;f(", '(Girc_il_.jll II AI. imm
tl;! ° -t II -> tl_pr_,.i,
l_;nei:gy V(_I (.x'_t l,y C_lc)ltll _(i._(_LI,()rl( eV/amti ) ((ml/,u) (_'m _ )
_1,,bl!l+O] !), ]tlF', t UI .I, 601!',-. l 62, OLd,40,_1 (i, 2 I I!;-J()/ ii, 1131!1-I 64,01!_t 0 3 B, 1_:l_;lO/ 2,1 GITI.-;I"7 01!;.t.03 I _161!]-i-C18 2,2,( I.,.-l 6i, OE-i.04 .1, ] £11)',-t08 2. ;1!.)1_',-;16;[, Dl!l-i 04 ;i, 70l!',.i OR 2,06I!;- .l.62,0_.t 04 .1.,96l!]-t 08 ], 9 6 I_,;-164, Olfl.r 04 2, 1111,.ii Ott .I., 691_-.165, Oli;.i-04 ], 11l!',.tOil 1, Dc)Ii;- ] 6
Ru [ei:erlceI 599
Ac:curacy t 25_
NoLe_ I None
C!l!ub, yuliev F'.It:L.l.li£1 Pal. aliil_,L_,i__ [oi C'.l;clt_,u <cJfgc;J'L]Ollkl
lf]lll;[l. I _-: .l , !)I_',I O_J (_!V/_Ttllltl_ l#',llh:l_ '-: !l, (.)1,;t 04 t:,V/Elllltl /i
A 0 A l A 2 A 3 A4 A b A 6
-12,4228 -,()]J962g -, 166019 ,C)2B7214 -,()07!i24 b6 ,000221]20] ,00(1526627
'£lle .I7].L i:epreBe, llt.rJ the abiJvc: C::l()lJ£1 FI_c-'I. I.(_il W.tt:h i!lll Illlf.t c:l(-_vI al:.l oi_ oi O, ;I _,The AIl_i×t llll.illl dev:t _ll ].t-iri .1l-t 0,2._t, d:li. 2, ()l!;.i 04 (?V/dTililtl,
See-., al._peil01.t.x [(Jr (;hc..,lJyiallev (IL d_-_t.ai I <q,
O
r
t--I.,+ -_ t--I- :'.:'H+' Prol,
1O- 16 ........... ] ..... J.___J._.._L_.Z_J__L.LL.... I___I..___L____L-J--I_L
lC7 ld lo_• / ')[_rlerg y (eV/El ri7LI.
C,l:o_l-t S_t_t loci l'oi/ t.h_ l_'riilllat]on c)f! I_'aaL I1 At:(-_lllliI i
by Pa_ilt.:_,_l_lC-_' oi II;! ° 'l'hrotic.lh II_
I1_!' ,I I1,I .-;. IIi, toO,
(_.VIainu) (c_m/_:_) (c',m_)
20L_,-t(.)3 G 211_.t 07 4,9HI!',_,I 64 0 l_-i.0 ._ 8 19 I!I.t 07 1,09 L_:- .l.67 0 E -t.03 1 16 l_'t 0 t._ II, .I.2 lil- 161 0[_,-104 ]. 39L!l-l.Of3 I1,221!1-16I 5N'F()4 [ 701_-t()B El, C)!i1!I-;[62 0 lr,+ C)4 I 96 I,.I.t.O,q 1,44 E- .1640E-t.O4 2 'ltTIlll.t.Oa 4,7()1!l-1670Et-O4 3 6{11'.I-IOB. 2o211!',-161 0 _'-t.O5 4 3 9 l_.t O13 1,2 ;1I!',- ;I 8
It__,£ e rB, nge El I, 2OBt 2.1()t 214, 2;IB, 2190 21;I
ect - . 20%_ _ Ir ac?y I
NoteA 't'h_: clatfl refer to till:) I-)13111Cii' i;h_J c2I.'('jrclt:l NE._C2t.J.(.'II1EI llL"IL" 117i .t- Hp -.." (ii i
+ H)pcoj, and 1.12_ + !I_ -b (H -i. II)proj,,
c2!lob,t,._llev l_'l.t;L./ilq I:'ai.aillo.te;t_._ .fol; C?l;'o_-_a So_,!t;toll!-s
Eilit i] =: 20l_,.t.()3 (:.:V/alilil_ F :_ ;l OE+O!i _V/aliiU' '111_-11._ '
AO Al, A2 A3 A4 A!_ A6
-70,6702 ,-, 6326.1.2 -,60652;1 -, O.t.lJ 5143 -, Oil 217.10 , OI 6f_l] 79 ,010479"1
'rile ft I; l:npl:-oar_rll; _l t;.ho abovo croaf-t aecLJ.ori wiLh ari rillf.;I (I_:_v.tat:,tol_ oi! O, 3%,The I_lax.t.inuill df:vtaLtorl :l._l O, 6% aL 1 °OE-i-04 oV/alllii,
So.o appel_d:l.x for C;_heby_lhev Pl.i; (:l_:_La:l..l,<_,
O
(: I,-,_:s'_:;'....... .-:,e<[.ioll v c':,oEnerq V................ ,_../
l 0" is T w r--v--q--r-FT-r 1 r----r'---r---r'_--r'T"
_ ,,.....f-"-"-"-"--_....f
j'
I/ '
' X
E(.)
c©
'-_-_ Recommended_) Data
bOo9oo8U Chebyshev Fit
'10-I_ l_ __L__, , ,_.U_Lt , _ _ , !_.LL]_lo_ lo_ .io_
Enerc_ty (eV/aBU)
0
' 'I,-32
Part:J.a.L Ct:oriel Secl:iOlle_ [or DiB'aoc.[at.[oll Oof! t_'a_3t: I-I2. lOllS :1.11 Pansacje Througll . H;!
1.12° t- 1.1;. -> (I.I _ -t. I.I.) -t. H2
Bnergy Veloc].ty Cross _eot:ton
(eV/ainu ) (_m/_) (c_.l2)
], OB'I-O] 4 39[,l-t-06 6 ]4E-]72 OB+OI 6 21E-t.06 6 58E-.L'/4 0B+01 8 79B+06 6 96E-1770E+O1 ] ]68+07 7 641!]_1'710E.t.02 1 39E407 8 161!',-17.L 5L_.t102 i 70E-_C)? 9 191!:-]7
'20E-t.02 1 96t':H07 1 01E-164 OF,+02 2 78E+07 .1. 248-]67 O1_-I'O2 3 681_I-I-07 1 47B-161 0_+03 4 3913-1.07 i 601S-161 5P,.I.03 5,38E-I.07 1. 651{-_1.620P_.I-03 6,2]E.I-O'I 1.67_-].640E+03 8,791!;'1.O7 1,6BE-1670E.F03 ].,16B+08 1,67E-1610E-t.04 ] 39E.t.08 .l,65B-16
1 5E-r04 1 70E+08 1,55E-162, OE+04 ] 96E-I08 1,478-16'4.0E-I.04 2 78B+08 1.13E-:167,0E404 3 681!;+08 8.34E-171. OP,-I-05 4 3913,+08 6.73E-171.58+05 5 38E+08 5.]2B-172. OB+05 6 21E+08 4.22E-174.0E405 8 78E-I08 2,58E-]'I7. OE+05 1. 16F,-t.09 1.74E-].7
].O_]+06 1 39B-I09 1.34E-17 O
References! 271, 527, 528, 529, 560, 589, 59]
_Accuraczl _ < 5x].O4 eV/allltl, 40%
E > 5x]O 4 eV/ainu, 20%
_Notesl (1 ) At the lower impact energ.tes, the results of the variousInvesEigators depend ell t:he initial vibrational-st:ate dlst:ribtltions of
the 1-12* ion. (2) In the eV range, H2 _ projectiles were used with D 2 target
and D2 + proJectlles with H2 target (see Ref. 589).
,C,hebyshev Fit tinq Parameters for Cross Sections
Brain "-" 1 . OE.I-O]. eV/aluu, Ellla × = 1 ,0E+06 eV/,_mhl
AO AI A2 A3 A4 A5 A6
-74.5723 .-.555602 -.906658 -.238001 .]]0022 .0251065 .00343160
The fit: l:epresent:s the above cross sect:t.on wil_h arl rills dev:l.ation of 2.6%.The Illax:[llltlm der] at:ion :l.s 5,8% al: 4,0l_'t 03 eV/ainu,
See appendt× for Cllel)yshev f_tt deta.i.lu,
0
i
C_t-33
0t-t_+ + H; -> (H+ + H) -t-i-I2
Cross Section vs. Energy0-15, 1 i i i Illii i i i i T'1-111I ''t"'I I"FrTTF r- ..... t' i i FTT'TT[_---i---T-T-1
i
10-1_i ' ld ld ld lO_ lOs lO0
Energy (eV/amu)
G-34
Cro_s Sections for the Formatiorl of Fast Protol]s from H2+ ill He O
H2* + He -> Total H _
oH+(He)
Energy Cross Section(eVl_1_u) (cm 2)
1.0E+03 3.69E-171.5E+03 5.75E-172.0E+03 7.43E-174.0E+03 1.17E-167.0E+03 1.53E-161.0E+04 1.72E-161.5E+04 1.86E-162.0E+04 1.94E-163.0E+04 2.01E-163.5E+04 2.01E-164.0E+04 2.0OE-167.0E+04 1.84E-161.0E+05 1.57E-161.5E+05 1.22E-162.0E+05 9.81E-174.0E+05 5.21E-176.0E+05 3.35E-176.5E+05 3.O6E-17
References: 86, 527, 528, 531, 562, 570
Accuracy: 20% O
Notes: (i) More recent cross-section data from Ref. 562 (between 2xlO 3 to
8xl0 _ eV/aIIu) exceed the earlier data by approximately 40% at 8xlO 3 eV/_llu
to approximately 360% at 2xlO 3 eV/_uu. (2) OH+(He) refers to the sum: o(H .
+ H)Proj . + 2o(H . + H.)Proj.
C hebyshev Fittinq Parau_leters for Cross bections
eH+ (He) Enlin = I.OE+03 eV/_llU, Enlax = 6.5E+05 eV/oallU
AO A l A2 A3 A4 A5 A6
aH+(He ) -74.0323 -.0812968 -.900960 -.0399950 -.0205556 .0309465 .00869410
Tl]e fit represents the oH. cross section witll an rills deviation of 1.0%.The maximum deviation is 1.4% at 2.0E+05 eV/_uu.
See appendix for Chebyshev fit details.
(_-35
H_ + He -> H+
Cross Section vs. E,nergy10'15 ':
...... i I '1 f I I'll!' I I 1 I I I li i I I i I I r-T-T
X - c_ (He)t1"
Eo /_f ,\fZ.0
'-D 10 -1_ Recommendedqp Databr)
oooo0L. Chebyshev Fitu
,10-1_ l i ii iliil i i j i iiiil I 1 i i ilii
103 ld ld 106Energy (eVj_nrnu)
,, lla
0-36
0Cross Sections for Dlssocl at Ion of Fa.'_t }l-_ lans in Passacle 'Phrnll(l]1 Hp
l-]z_ 4. He-> (l-I _ ,I- H) + lie
Il.,ow Energy High Energy
Energy Cross Section Energy Cross Section('eV/m.u ) (cre_) evlamu ) (ota2,)
9.7E+00 6 55E-17 2.0E+03, 2 ].iZ-.16I.IE+O] 6 55E-17 4.0E+03 1 93E-161.2E+Ol 6 55E-17 7.0E+03 I 69E-161.3E+01 6 56E-17 I.OE+04 1 46E-]61.3E+OI 6 56E-17 1.5E404 i 22E-]61.5E+01 6 56E-17 2.0E+04 1 07E-16
1.5E+Ol 6 56E-17 4.0E+04 7 35E-17i. 6E+OI 6.56E-17 7. oE+04 5.39E-171.7E+O] 6.61E-17 I' OE+05 4.46E-17i. 8E_01 6.57E- 17 I. 5E+05 3.35E-17
1.9E+OI 6.55E-17 2.OE+05 2.68E-172. OE+OI 6.59E-17 4. OE+05 i. 51E-17
2.1E+01 6.59E-17 70E+05 8.82E-182.2E+OI 6.58E-I 7 1. OE+06 6.37E-182.3E+OI 6.57E-] 72.4E+01 6.55E-17
Referent;es : 527, 528, 560, 562
Accuracy: g > 5x]O 4 eV/_ml, 20%
2xlO "_ < E < 8xlO 3 eV/_ml, 15% (see Ref. 562)
E < 102 eV/6mm, Unknown
Notes: (I) At lower impact energies the resu]ts of the various investigatorsdepend on the initial vibrational state distribution of the H2 _ ion. (2) The
data at i0 to 25 eV/amlu were taken with D2 _ instead of H2 . as the projectile.
(3) No attempt has been made to interpolate between tile low and high energydata.
Chebyshev Fittinq Par6uneters for Cross Sections
Low Energy Eml n = 9.7E+00 eV/ainu, Ema x = 2.4E+01 eV/ainu= 2.0E+03 eV/_nu = ] 0E+06 eV/emluHigh Energy Elnin , Elua× .
AO AI A2 A3 A4 A5 A6
Low Energy -74.5250 .00171327 -, 0009_9677 -,00133213 - .OOO620_55 -.000378036 -.000458557
High Energy -75.0072 -1.76360 -.334933 .000919287 -.0200220 .0135139 .0139802
The fit represents the Low Energy cross section with an rills deviation of 0.2%.The maximum deviation is O.4% at 1.9E+O] eV/ainu.
The fJt represents the High Energy cross sect]oll with an rms deviatioll of 0.8%.The ma×imum deviation is 1.3% at 2.0Bf05 eV/_m_u.
See appendi× for Chebyshev fit deta:i]s.
.i
G-37
QH2+ + He-> (H. + H) + He
Cross Section vs. Ener9y-15
/U h I I I''111111 I I 1 1 I TTTI '1 I I II1111 I i "1'111111 I I I I'1"11'11 1 i I 111!
__
A=Low E
x-...., x = High E
10-16_ \\\
©'+_ Recommended® ---Data
UO
U?
0Chebyshev Fit
u 10-_
10 "-]I__ l I Illllll I I IIIIIII I I Illllll i I Illllll I I IIIIIII ,I,I IIII
lc)° lo' lo_ lo_ _o_ ld i#Energy (eV/ar-nu)
0-38
OCross Sect; ions for Formation of Fast tt._ [or
Fast H2 Projectiles F'assing ThIou_h H2
FI2 + H2 -> I-1_ ( Fast ,Total )
Dow E }llgh _
Energy Cross Section Energy Cross Section( eV / ainu ) ( cm 2 ) ( eV / _,_u ) (cm 2 )
2.5E+03 2.04E-]7 1 5E+05 6 13E-174.0E+03 2.62E-17 2 OEr05 4 61E-]77.0E403 3.61E-17 2 5E4.05 3 70E-171.0E+04 4.52E-17 3 OEr05 3 13[!;-171.5E+04 5.74E-17 40E+05 2 56E-172.0E+04 6.71E-17 5 0E4.05 2 25E-172.4E+04 6.89E-17 60E+05 2 12E-i73. OE+04 6.25E-:[74.0E+04 4.34E-175.0E+04 2.80E-17
References: 31, 535
Accuracy : Unknown
Notes: (I) The low energy data are from Ref. 31, while the high energy data aretaken from Ref. 535. (2) This data involves the sum of the cross sections for
the products: o(H + + H)Proj. + 2o(H + + 114)Pro]. + o(11{ -I H-)Frol .. (3) No attempthas been l*lade to join the high and low energy data sets.
Chebyshev Fittinq Parsuueters for Cross Sections
---- ! --LOW E Eml n 2.5E+03 eV/amul Ema x 5.0E+04 eV/ainu
High E Enlil] =, i. 5E+05 eV/_lltl, Enlax :: 6 .0E405 eV/_llu
AO A1 A2 A3 A4 A5 A6
Low E -75.7161 ,371301 -.373363 -,209805 -.0677263 -.00389719 .0259767High E -75.8616 -.542987 .0642733 .0116753 -.00148111 .000221649 .00636358
The fit represents the bow E c_oss section with an rms deviation of 0.7%.The maximum deviation is 1.2% at 1.5E+04 eV/ainu.
The fit represents the High E cross section with an rms deviation of 0.0%.The maximum deviation is 0.0% at 4.0E+05 eV/ainu.
See appendix for Chebyshev fit detai].s.
O
0-39
QH2 +H_ -> H+ (Fost,-Fotol)
Cross Section vs, Energy-16
10 ..... I -1 'l t '1-r-t'TT I l l I'l I I '1 ,' , -_ i ii i i".,
-- j
- , _=Low E
_ _ = High E
b4
_ _,
c-O
'-_ _ Recommended
0 °O3U'I
8
U /' i, ...... Chebyshev Fit
10-17 l 1 i i i Jill i t 1 l 1 i lll _ 1,_,, l i 11111
10_ ,10', 10s 106Energy (eV/omu)
0-40
Cross Sectiorls |!oi; the For1111:It]:[Ol]oi Fast H [r(i111 i
Fast Fl2 Projectiles Passing Th_:otl[:lh II2
t12, + 1-I2 -> H (Fast,Total)
Bl]ergy Velocity Cross Sectiou(eV/allltl) (c111/s) ([_lli_)
2.5E4.03 6 95E+07 2,62l_-163.01_4'03 7 6]B'I-07 2 89B-164.0E4-03 'B 79E4-0'7 3 OBE-165,0E+03 9 82_;+0'I 3 08E-166.0E+03 l 08E408 2 95[,I-167.0E403 i ]6E4.08 2 85_:-168.0E+03 ' I 24E+08 2 93E-I].69.0E4.03 I 32E+08 3 .13E-161.0E404 i 39E+08 3,32E-161.3E+04 i 5BE+OB 3.46E-16.I. 5E+04 1 70E-108 3.43E-162.0E+04 1 96E.I08 3.16E-]63. OE+04 2 41E+08 2.49E-]6
4, OE+04 2 78E408 r 2.00E-165. OB+04 3 l IE4.08 1. 651,]-16
Referencesz 31, 536
Accuracy:. 40%
Note_._._!"This data involves the sum pf the cross sections for the products l
o(H_ + H)Proj ' + 2o(H 4 H)proj . Variations in ion source conditions produce
changes up to 10% in the measured values (see Ref. 536). O
Chebyshev Fittinq Par_]leters for Cross Sections
Ell_in = 2.5E403 eV/Em_u, Elllax = 5.0E404 eV/_llU
AO AI A2 A3 A4 A5 A6
-71,7329 -.200109 -,223241 -.C773361 -.0140887 ,0563185 -,00955263
The fit represents the above cross section with an rms deviation of 2.5%.The maximum deviation is 4.4% at 'I.OE+03 eV/ainu.
See appendi× for Ch_byshev fit: details.
0
a- 4t
@ ,t--I_,+ I-I.,-> t--I (Fast,-[btal),u _..
<-rv,_-_o.........rio _- E.nergy....... _-,.:,.....,_-_. Iq Vc,o
10-I:-, , r ....m---r-_-r-q--r-q T_, , --r--r-m-r-r-
£'4
o,.._./
w_
0 ' ,_'.,..,.. '"_
0 0 ".Y<---_ ./ _," Recommended¢_ - , ':.... _'-c_/ "_ _-- Da ta
V-)_..omCn /
U Chebyshev Fit
10 _1_ | 1 1 1 l I,IIt 1 I-- 1 I 1 1 I,,.L
103 1©4 .lOsEnergy (eV/om u)
O-42
Total D(_It;I.tlc_t;:loll ('l.Oa/.:t Sc_cJt;.[OltB [of [_',_llJt I1_, l-'l:'t:ljoc_t:.l..l.o J.ll I1_i
11_ + [12 -'" 'l.k:lt:a.I L'JeI-JI:I:tLc'JL](_Ii (.if l:'at.lt !1;!, F'ro')oc._L::Lle
d
l!',nel:cjy Vc-iloc:l ty (.7[ o_l[s Sc::t,'t: l.oi_( eV/_lltl ) (OililY# ) (till z )
103 Ei 03 50 ] E.I 0 7 ;l 591_I- 161 : 513.t.03 h 3 li l!l-I0 7 .I 641_- .162,0 E +03 6 21 I_-I,0 "7 ;1 "/6 E- :16
t4,0E-t'03 8 "/9E,t-O'/ 2 ;[6E-16"I,00E-103 1 ]6E-t-OIJ 2 64E-.16I, 01:]'104 .I 391!H0B . 3 091!;-]61,5F.,-t.04 ]. 'IOE-t O{I ] 4 bE-162,01!IF04 I 961_;-t.0B 3 52E-164, OE-t-04 2 "lSE-t 013 ] ] "LUi-] 6
,!+5,OE 04 3 lIE-fOB 2 92F, .16
,Rg,ferellce I 536
No te_i (1) ThiEt C.lI7OEll-J BecL.t.oII 113 tilE, fitllll or croEIfl ElectiorlB for allreactions t:hat destroy t:he [a[_l; tl 2 IllO].octile .t.ll pa_3fJacje l;hrotlcjh 1-12, J., e,thoBe producing fault 112_ , ( H-I,H) t ( II+II 'i ) , ariel ( lli-l-H i ) prodilmt;a, ( 2 ) IJarc.levariat ;[OllEI J.ii ].oil pJOtlt-Ce oi)or aL t.li{.I c-.'oiKl.l.t.l Ollf_i wci,i;e [OtlllCl t;o pi.oduc_etlallgnf3 til) to 10l iii l:ho llie.a_JUl-ecl crOBFJ fJecl:] Oll ( [4on Re.f, 536 ),
_Cheby8hev Fit-.Liilq Parameters £or C',rosa Sect:t.oilu I
Enltl I = ] 3['I-t03 eV/alllti I' :--- 50E.t.O4 (JV/anlu' # - lilt_IX '
AO AI. A2 A] A4 Ab A6
-71.8671 ,380700 -, 137630 -. 0886297 -,00459765 .013462B .00]97 19B
The fit: repreaent;t? the above ci:o,qa a,oct:l.(:m witll ai1 rnla clev]atton of: 0.6%,The lllaXlllltllll deviat toll ta 1,2% at 70 OEiiO3 eV/ailiu,
See appendix for Chebyahev flt details,
0
|
i
0-'43
® i
tt2 + t-I_--> Totcll Destruction of Fast H_Projectiles!
..... c C':_ ...... _.j.(l,.,s.:,.... ..>c<:tiOl-_vs. Enel-cy- 15
0 _....,-----r....r-7--r--r',--I r------r....,---r--r-r--r-r-
r'l
E
rE. 4_0 "rr"_. ":---G.._<.
' - .-_ ""--, R ec o nnm e n d ed
"t-" o
(.P ,1'_ ',
' @ - ,,' ""_ --_ Datat i') v i
li
d<> /Dr) s_Cl # +L.. ,I
." ........ Otiebyshev Fit(._P iJ
,.,,i "i" >
,ii
_f j ,
lO- ,6 .L.__ 1__ I I -.L_LL_L..L I .1.... -J---J.__.L_LJ.._L
icl ld' ldi 'r .Energy (eV/,.Ji-nu)
' Cl.-44
Tot:al D_.,_t:rLIot:.lOll (_]()[If:l _:_c't;JUlll.t to1 IIi_ I"l:OJe'c_t:j.ll:_ 1o111_1,I11 I1,_
11.!* .t I1_ -.,> 'l'ol:aj. I)t:_F.1LI.'tIc_L:IoI_ o.[ I1_
[_ll_-_v/gy V_,]oc_.lLy C:_uourl Bec_t:I.ol_(_Vla.lu) (c_ml.) (c_,l_)
.I 6 I_.I.03 b, 5 6I!',-I.0 -I 3 39I!:- J62, OB.I.03 6., 2111!',-I.0I 3 VBWr-164 0 P.I,I03 8 7 gL!:.l0 7 5 07 B- .L67 01_,I.103 I .16B-108 O IC)l_-] G] OL_.I.04 ] 391_HOB 6 651_-].6I 51_+04 I 'IOI!_.I.0B "I 061!I-162 C)F,.I.04 1 96_I.I013 6 8:11.'I-:I.63 0_',:I.04 2 zlll!',l'08 5 93_',-163 5L_,.I.04 2 60_-I.0B 5 581!I-16
2o_
(]) Th:Is oror_J _c_e.t,l.oll i_J _II_:_ _:_Ul_l ol c:ro_._ aec_.t..Lol_ l_of _._].I_ot1_ that: claret:roy the 113 lllO].o.L-'t.l]._[ .loll .LII pae_sage, throtlqll 112, (2,)l.,flr_j_ v_r] _tt.| OlIB I11 ._o11 e_otlrc!e oporal:.lrlg C_OllClJt:.LOl1[:_ wor e. fotlrlcl t:o prc]cluooc;hancjo[_ tlp to 10_t_ .l.n t:ho lllOa-_tll:r_d c_l'og[l _.It3c.t:.I(;lll_J ( ,_JOe ROf, !)36 ) ,
,CheLi_ys-l]ev.... !:'.l.tt,:.ll!,Cl !:'ar,0!netc:,re_ for" (-'rose_ [_ec_'tJ.ol_
'-- .I, 61']'I03 _V/_.lllltl _ I!_III_|X = 3, !_I!','I04 f:_V/_lllltl O_10.tll
AO A.L A2 A-I A4 Ab AG
-70,370.1. ,28460! -,18430b -,0425610 -, ()092:1848 ,00698594 ,00725332
The f i t r,e:pro_ollt:_J the _.lbovo c_l:o_l[1 soot:.l o11 w.l.th all rlllEi cleviat.loll of 0,3 _,The llla×illlHlll clevlal:JOll. .ll,J 0,5_, _qt: .l, 01(',.i.04 oV/ftlllu,
See app_.3vlcl.t.x .for Ctllel_y[fllev f:lt: rlc,l:a:l..l _q,
{I-4b
e, .t,Fr.olectlle sPl3+ + I-I_ -> Total Destruction of bl:_ .
i
(.:iI,::,st:.:;....:::,e_....(toil vs, El-l(l__-.IO I_ 'l--'--r'-"--T---r--T--l--r--t-I i ............ F--r'--'T-'-I--T'-T--I--
///
/
/l
/_ ,
(D //
0'-_; Recornn-_ended
, - ---- DatoL/309U'I0L
L) Ctnebyshev Fit
lC)-_6 J L__L.J__L_LLLI__ L ,I__L_Z__Z__L_LJ.1o_ lcr lc)_
Enercjy (eV/cim u)
O-4O
l'r(]')(_r;L:l I(:_ . ]()tII::I Ill II;,fl_ot_ll L')el:-Itrtlt_L:[t)ll f.",l:l:)i:il.l 8u_(::l:l.()ll_ [or II_ .
II2_ .I. II;i -> 'Ik-)tal l:)e_:It:ruct.loll o£ II,_,
l_I)erg.y V_-_.loc:,li.y Cti:oi_ 8_,c_t,Ion(_._VI aimi) ((;,il n ) (_ill_)
I 5Lq'l'03 5, ] 8E-I07 El .| 21i_,- 162 01.,-I.03 6 211_.r0I 8 IBE-]6
, .: ,_40E.t03 _.t '19E.rO'l 8 3(}I_,-]67 OB-l-03 i :t6_ .i ()[) 8 I!:)I!_-16
, , 1 01_}.l,04 :l 39F,.r08 Et .1.8E-16I 5E-t,04 1 "lOLll-t.OO 8 46E-1620E-l.04 '.I 96E.I.08 7 75E-:16
,40E-l.04 2 78Eros 4 69E-165, OE-r04 3 :l:ll_.t.08 3 13:LI_]-:1.6
ee_rellces I 536 _ 5B9
A,cl3tl_r_l(3y i 20%
Notel_l ( 1 ) Tl'rJ.rJ creels seet.|.c)i] .l.s l:hf:.,. [-n.ml of oi:o_:Js _eot:l_ol]i] for a].lrea0t!./'ollB that deal:roy Lhe 112+ Ii)OJecuJLl£ Ion :LI] passage throuc]h I.l2, (2)l, arqe vnriatiOltEi ill .[on _ouroP_ operat.[llcj rUOl]clitiollS wore fou]ld to produceohangee tlp to 10_ ill the measure c;rot4s 8eOl_]OllS ( aee_ Re[, 536 ),
C!!ebY_81!ev FiLtinq .. Pqi-allletera for Cross Sec:t:[Ol!S_
0Elll].l I = 1.31_t03 etV/atllll_ ElllelX = 5, OE-t-O4 eV/NIItl
A0 AI A2 A3 A4 A5 A6
-69,7995 - J2,8808] -, 2'.[6489 -, ]0234"I -,0344599 , t)].55290 ,0223268
The fit represents the above c'ros_J sect.Ion w:Lth all rills deviation of 0,9%,The max.|nl.nl deviation is ],3% at ], OtU-t.04 eV/allltl.
See appendix for Cheby[._hev £tt: deta:l..ls,
a-47
0,+ +
H2 + H_ -> Total Destruction of H_ Projectiles
Cross Section vs. Energy,0-15I T--''-*; I w I '"'l' 'l I '_ i 'l i .............I" t '1" i: i i
CI
ELP _-
C0
'._ Recommended
Q °@ - _Data
@
0_- Chebyshev FitU
10 "16 1 I 1 1 1 1 .J I 1 I I I 1 I, I I
ld lo' o_Energy (eV/amu)
G-48q
Cross Sections for Production of Fast H+ From H3 _ Projectiles iT] H2
H3 _ + H2 -> H + (Total,Projectile)
Energy Velocity Cross Section
(eV/mnu ) (cl11/s) (c1112)
4.0E+OI 8.84E+06 6.00E-187.0E+OI 1.16E+07 6.91E-181.0E+02 1.39E+07 7.61E-182.0E+02 1.96E+O7 8.89E-18
4.0E+02 2.78E+07 ].19E-177.0E+02 3.68E+07 1.78E-]7I.OE+03 4.39E+07 2.49E-17].5E+03 5.38E+O7 3.99E-172.0E+03 6.21E+07 5.41E-174.0E+03 8.79E+07 9.8OE-177.0E+03 1.16E+08 1.42E-16I.OE+04 1.39E408 1.77E-162.0E+04 1.96E+08 2.14E-164.0E+04 2.78E+O8 2.33E-167.0E+04 3.68E+08 2.39E-16I.OE+05 4.39E+08 2.28E-162.0E+05 6.21E+08 1.74E-164.0E+05 8.78E+08 1.08E-166.0E+05 1.08E+09 7.]5E-17
Refe;ences: 86, 214, 535, 574
Accuracy: 30%
0Note: Large variations in measured dissociation cross sections have been
as-'E_bed tc the ii]fluence of H3 _ iolls formed in ion sources with varyingdegrees of vibrational excitation.
Chebvshev Fittinq Par_ueters for Cross Sections
Emi n = 4.0E+01 eV/_ml, Ema x = 6.0E+05 eV/mnu
AO AI A2 A3 A4 A5 A6
-75.3369 1.74367 -.759749 -.559135 .0918355 .0438106 -.0940811
The fit represents the above cross section with a,] rms deviation of 3.4%.The maximum deviation is 5.3% at 7.0E+02 eV/6mlU.
See appendix for Chebyshev fit details.
O
q
0-49
• 'H3+,+ H2 -> H+ (Total, Projectile)
,,
, .
Cross Section vs. Energy10-15- I t' '1 I IIII I 1, I I ! IIII I I I I II1!1 I I I I IIIII I I' I I llrl_l
10-" _-E -
c-© -
'°-t_
O o _ Recommended '_Databr)Or)O0
£U ]0..17 . -..... Chebyshev Fit
- .-- , ,
10-1E__ 1 J * lilitl I I t_,t,itJtl J J I tlJlll ._L_.j l J**J,I I i I IJ,J
lO' lO2 I 103 104 I@ 106Energy (eV/omu)
O ,
G-50
Crosl Sections for Production of Fast 112. From Hl _ Project:lies i_] 112 O
+
H3 + H2 -> I.t2_ (Total,Projectile)
Energy Cross Section
(evl_l_u) (cm2)
I.IE+02 1.34E-]72.0E+02 1.99E-174.0E+02 2.93E-177.0E+02 4.17E-171.0E+03 5.O9E-171.5E+03 6.53E-17
2.0E+03 7.96E-174.0E.03 1.18E-167.0E+03 1.29E-16
I.OE+04 1.29E-162.0E+04 1.18E-164.0E+04 9.62E-177.0E+04 7.75E-17I.OE+05 6.62E-172.0E+05 4.69E-174.0E+05 2.86E-17
6.0E+05 2,O3E-17
References: 86, 214, 535, 574
Accuracy: 30%
Note: Large variations in measured dissociation cross sections have been I
_bed to tile influence of HB * ions formed ill ion sources with varyingdegrees of vibrational excitation.
Chebyshev Fittinq Par_ueters for Cross Sections
Enlin = 1.1E+02 eV/_llU, Ema x = 6.0E+05 eV/amu
AO A1 A2 A3 A4 A5 A6
-75.4231 .295854 -.985779 -.0762360 .0980699 -.0248092 -.0512818
The fit represents the cross section with an rms deviation of 2.4%.
The maximum deviation is 4.1% at 4.0E+05 eV/_uu.
See appendix for Chebyshev fit details.
O
4
G-51
0H3++ H2 -> H2+(Total, Projectile),,
Cross Section vs. Energy10-15 - ,..........
I I I I 1 _11| I I I I f III I I ,I 1 I 11'11 I I I I 1 III1
--.
E0
0
O "_ 10-1_ - Recommended(1) - /L/') ,DataOr)Or)
8U ..... Chebgshev Fit
O-17.____L__L_.LL_L_LLLI i i i llltll l t I Illlil I i i I|ill_
102 103 104 105 100Energy (eV/am@
G-52
Cross Sections for Production of Fast H from H] 4 Project i ]es :irl H_
H34 4. H2 -> '14 (Total, Projectile)
Energy Velocity Cross Section
(eV/ainu) (cre/s) (cre 2 )
1.5E+03 5.42E+07 3 . 20E-']62. OE+03 6.21E_0"7 4.26E-.164. OB+03 8.79E_O7 6.94E-].6 .7. OE+03 ]. 16E+08 8.90E-16l. OE+04 ]. 39E408 9.69E-16I. 3E+04 ]. 58E4 08 9.96E-162.0E404 I. 96E+08 9.02E- 164. CE+04 2.78E+08 .5.77E-167. CE+04 3.68E+08 3.56E-16i. CE+05 4.39E_08 2.62E-162 0E4.05 6.21E+08 1.45E-164. OE+05 8.78E408 7 •79E-176.0E4'05 1.08E+09 5.48E-]7
References_ 214, 535
Accuracy: 30%
Note: Large variations in measured dissociation cross sections have been
asc--_bed to the influence of H3 + ions fornled ill ioll sources with varyingdegrees of vibrational excitation.
Chebyshev Fittinq Parmueters tor Cross Sections
Eml n = 1.5E+03 eV/aallu, Enlax : 6.0E+05 eV/ainu
AO A] A2 A3 A4 A5 A6
-71.5391 -1.05347 -.826342 .203507 .0536]40 -.0425785 -.0]853]5
r
The fit represents the above cross section with an rms deviation of 1.8%.The maximum deviation is 2.9% at 4.0E405 eV/6mlu.
See appendix for Chebyshev fit details.
G-53
0+
H3 4- H2 -> H (Total, Projectile)
Cross Section vs. F_nergyi0-'5_
, I i I I _ b.j_,-.-_',,,.-._<i i i _ I i J II 1 _ , I w itr"
/f --,_- \k\
-- _ ,,
- /t
/d _
- \\\
/'-x
£'4 _
E0
c"©
o 10- - Recommended
Q ° _ hh_ _Data
6O0L
U _ _ Chebyshev Fit
_
lo'" J _ J I 1al L_J__LJ_ZJ_UJ__L _ i i _ _ J_
lo_ lo" lO_ lO_Energy (eV/o m u)
0-54
Cross Secttions for Production of Fast H2 [rom 113" Projee, tttes iN t12 @
H3* 4. H2 -> H2 (Total_ProjectiJ.e)
Energy Velocity C r O _ S I Sect_ ], O_l
( ev/m,u ) (cm/_ ) (cm 2)
3 •OE+OI 7.6 ]E-I.06 5.03E-] 7
4.0E+01 8,79E-I.06 5.18E-].77 •0E4-01 i. 16E+07 5.74E-]7
1.0E+02 1.39E+07 6,29E-]7i. 5E+02 ], 7OE+07 7.07E-17
2.0B+02 ]..96E+07 7.82E-174.0E+02 2.78E+07 ]. fOE-]6
7.0E+02 3.68E lO7 1,48E-161.0E+03 4.39E407 1.81E-.161 5E+03 5.38E+07 2.25F.-]62.0E+03 6.21E+07 2.63E-164.0E+03 8.79E+07 3.64E-1670E+03 1.16E+08 4.26E-168.0E+03 1.24E+08 4.31E-]6
1 • OE+04 I. 39E+08 4.30E-161.5E+04 I 70E+08 3.83E-162. OE+04 1 96E-108 3.22E-]64.0E+04 2 78E+08 1.50E-167.0E+04 3 68E-I08 6.49E-17I.OE+05 4 39E+08 3.65E-]71.5E+05 5 38E+08 1.98E-]72.0E+05 6 21E+O8 1.34E-174.0E+O5 8 78E+08 6.90E-186. OE-_O,5 1 08E'_09 6.09E-181
IDReferences: 214, 535, 585
Accuracy' 30%
Note: Large variations in measured dissociation cross sections, have been
_bed to tl_e influence of H3 . ions formed il] ioll sources with varyingdegrees of vibrational excitation.
Chebyshev Fittinq Par_uneters for Cross Sections
Enlin = 3. OE+OI eV/aullU, Eillax = 6.0E+05 eV/rural
AO A,]. A2 A3 A4 A5 A6
-'74.8168 -.899995 -1.57067 -.379862 .384429 .264557 .0263143
The fit represents the above cross section with an r,us deviation of 4.1%.The maximum deviation is 6.5% at I.OE+05 eV/ainu.
.See appendix for. Chebyshev f.it detai].s
, O-B5
tt3+ + H2 -> H2 ('Total,Projectile)
Cross Sectionvs, Energy0-15 " I JJ illllj 'l---"-T--j-I IIII I ," 'l ..... I I lit'li I "1 ' I 'T-FFTTTJ i l"J I ITI_"
/ \/ \
f"l -
E -& -
o - _'D Recom mended
II ° - \® Data(./9
0
_ ...... Chebystnev FitU 10_17-
10-18 i i llJllll _ J llllJll 1 I LJllJll l 1 l_J_lllll 1 I III11
lo' lo_ lO_ _o" 1o_ lo_Energy (eV/am@
C.I- 56
CroSS Sect iolls .l_or th_ Forltlat Lon ot: Fast I1' [_'rOl. O
tlff-] DJ.ssocJ at.loll c_[ I!_' Prc;_J_c_t;J..l.c_L_ ].rl Ilo:,
1-13_ t. lie -> 1.1_ {ToLa.1. }
Ellergy Velocity Cross Sect',lOll(eVlm.u ) (cml/s ) (c_m_)
i, OI{I-l-03 4.39B-I'07 2.19E- 17i, 51_+03 5,38_+07 '3,2C)_-_L72, OF,+O3 6,21E+07 4,18E*,;I74, OB-l-03 8,79[_-I'07 7,20_,-] I7, O[.,_-O'O3 ]. ].6 _','I'08 .I. 02_I.- .I 6]., 0l_4.04 ], 391!:'I()B ], 20E- 16i, 5E'I04 .L,70[_-I08 1.36111- I61, 'IE+ O4 1,8 .I_;+ 08 1,39 F,-16
Re ferencel 86
Accuracyt 20%
Nol est None
C!lebyslleV FJ.ttivlcl 9a_mllete]'_l for Cross Sect!.lon__._s
Einln = l.OI_103 eVlamu, I_lllax = i, IL_]I04 eV/ainu iL
AO A.I A2 A3 A4 A5 A6
-74,5849 ,941781 -,146192 -,0143319 ,000599232 -,DO304737 ,0023147"2
The fit represents tile above cross section w.Ltll an rl_s deviat.ion oi O,1%,Tile lllaXilllUlll cleviatclOn .l.s 0,2% at ],OI_-F04 eV/_nlllt.l,
See appencllx for Chebyshev fit, deta:l.ls,
O
0+
H3 + k-le- > H+ (,ToLcll)
..--x
P't
E(D
,9o I0-I Recommended® - _ Dat.a(./) .. .///CO - //
,,f"
UL _ ,//I/ ....-- Chebyshev Fit/
-//L
10-17 I l _, J_l .1 I iI ..... I . i _l_k.. l I J I
•io_ .io_ lo_Energy (eV/ar-nu)
II
: (.!.-b[I
O(')roBB _(1c_t; i (,HIEI f'{)l" t:llO I'_(.)rIIW:IL I(1|1'1 (J f I_'r_rit: I1,,* I_'tOltl
LhO l_.l._:_mjc;J:lat:loll c_[ I.l:l_ I_rojc_(:_L.l.l.c:_Fi 111 IIo
II:i*I Ilo -> II;I'
|¢1_0l;C.ly Voluc_tLy C;'rc_rJ 8_Ic:_t:LC}li(_v/_ml.) (ota/.) (cml_)
ii 01_.I.03 4 ;Jgl!:.t07 I 671_,-i1'/1 5L_'1.03 5 381!H()7 2 bOl!l-.J'l2 0 i_',+0:3 6 21 i,_.001 ;I 2bl_- ;l "l4 01!:.t.03 8 79171+07 5 481,I-.17'l OB.I.03 ;l .I 61!].FC}B "1 5'1ll_-]'11 OB+04 .I 391_1.tC)f.l 9 O01_-;17:L 5F3+04 .1 lOlJ;+OI3 ] 061!1-]61 lB-t04 I B:l l_'-t;C}f] ;I .10171-16
Re£ei:e i-ic_ 86
_col4racyL 20_
Ohebyr-Jllev [;'J.tit.,/llq I'arailletc-.,rtl [oi Crou_J 8ecLic;I]U
Biii:l.ri = .1,01!:-t.0] eV/_ulltl_ l!liiltlx == J, 7l!:.t04 oV/_uliti /
AC) A;L A2 A3 A4 Ab A6
- 7 5, .1..12"/ ,93920;| -, ;13202fj ,00680760 ,00049"1736 -,, 00339960 --, 000620;I. 24
Tlle fJ.t repre_-erit:F_ Lhc _lbove rJro_t_] [toct:joll wJLh arl rlllB tier:[aL.loll of {.),0t,'['he lllaXtillUill dev:Lat.l.orl ] _ O, 01 at: .1,01_-t04 oV/_ulIu,
See aplPondtx for Ohebyr_hev [.ii: doLa.lli_,
(1,-,B9
H__' + He - ....',', t-I;t+
....... ,._ . ,_, I_net,gy( i_'_°': .I:.,i-I:'C_.IC_IIV,J,
I()-Is r ........ r----q .... l---v--r-r--r-1 .......... i...... 1---r---1----r-q--r-r-
ELP
EZ0
,..) 10- - _.i j" Recornmended® , " -..... Data(f) ..-
....J/
Cf) !"Of) i"
i/'
(_) ,,-,' ..... Chebyshev Fit/,'
//
/
//
/
//
,///
/
lC)r; n J.......L__L_LZ_Z_L_ L i .L__L_Z_LU±lo:' ld' lo_
Energy (eV/4:lm LI)
(]-60
Total, Ct:o[-I[-._ Suct..l.e_tln [ur t:h6 l_l}_lm:_c.[at:LOl| ot7 I.I_:,H' .111 1.1_! O
lleH ° .F II;_ -> ToLa.l Hell o D]s[:ir_(_..lat::Ic_ll l'rc:_c:hlcl:tl
El'lev:c..ly Ve I.oc I L:y Crc_,a Sect-ioil( eV/_mm ) ( cm/u ) (c:,l _)
1, OE+04 .L, 391_.1.0[_ G, 85E-16.l, 5_.104 I, /01!:+08 6, 131!:-] 62, OB+04 ].+96B.I08 5,59E-.I 64, OE:I_04 2,'/BE-FOB 3,65E-_67, OBF04 3,68E4 OL'I 2,14E-16I ', 0 E405 4, "19II',+C)8 I. 41 E- ] 6I, 5171+05 5,3BE-IOB I,05E-162,0 E.I-05 6,2 1I_,I-t,08 9,0 '1E- :1"1
Re,[ e r eI]Ce.__.___._!l 610
6_ccuraey_ 20_
._otesl ( .l ) This react.toll :lllvolves Lhe total dJssociat:lOjl cross s_c_t.l.onobtain'ed frolll tile atllll of tile partla.1, crepis sec;ti.ollS for the tormat.toll offast projectile frac_uelltS, i,e, (He+H), (He*+H), (He+H') and. (He"+H _). (2)See Re.f, 6] 0 .for l_art:[a.1 cros_J secttOllS .tn the . 1-2 x 105 eV/6tllltl energyrat]ge,
_ChebYshev, Fitt.l.nq Parameters [or Cross Sections
E,I:[I1 = l,OE+04 eV./allltl, Billsx = 2.OB+Ob eV/alHtt W
AO AI A2 A3 A4 A5 A6
-71,6345 -1.10463 -,J28721 ,0876009 °0373958 .007]9887 -.0189657
The fit. represents t:he above cross section w:t.t:h ali rms deviation of 0.9%,The lllax:LlllHIH deviat:ioll :l.8 I. 5% at: ]. OE-t.05 eV/a,lu,
See append.lx for Chebysh_v [.tt: der:ai.leD.
O
0-61
QHell* 4- H_ -> Total Hell + DissociaLion
Cr-,--,_:._..__.._,._:,G_:,ction_vs, Energy...-,t5
I( f
..) 1 1_ I I - I'' I l-r-T i i --I-"-_--I_'F"T--'_
-%
\
li
0
c ,,,©
C) "lC)- - Recomrnended
V')
C) --L
(_) _ Chebyshev Fit
]0-17 I .... _ _ l ....L_LZ_LI L__J J .LZ_--LLL
1o_ lo_ lcrEnergy (eV//om u)
G-62
0Total Cross Sections for the Dissociation of Hell. in He
HeH + + He -> Total HeH + Dissociation Products
Energy Velocity Cross Section _(eV/a_lu) (cm/s) (cm2
I.OE+04 1.39E+08 2.09E-161.5E+04 1.70E+08 2.98E-162.0E+04 1.96E+08 3.14E-163.OE+04 2.41E+08 3.00E-164.0E+04 2.78E+08 2.73E,165.0E+04 3.11E+08 2.44E-166.0E+04 3.40E+08 2.15E-167.OE+04 3.68E+08 1.93E-168.0E+04 3.93E+08 1.73E-169.OE+04 4.17E+08 1.58E-16I.OE+05 4.39E+08 1.44E-161.5E+05 5.38E+08 1.03E-162.0E+05 6.21E+08 8.54E-17
Reference: 610
Accuracy: 20%
+
Notes: (i_ This reaction involves the tota] dissociation cross section
obtained from the sum of tile partial cross sections for tile formation offast projectile fra_llents, i.e. (He+H), (He++H), (He+H + ) and (He++H.). (2)
See Ref. 610 for partial cross sections in tile i-2 x 105 eV/m_lu energyrange.
Chebyshev Fittinq Parmueters for Cross Sections
Eml n = I.OE+04 eV/muu, Ema x = 2.0E+05 eV/mllu
AO AI A2 A3 A4 A5 A6
-72.4377 -.561126 -.322720 .0959965 -.00323223 .017197 -.00704447
The fit represents the above cross section with an rms deviation of 0.3%.The maximum deviation is 0.6% at 6.0E+04 eV/_nu.
r
See appendix for Chebrshev fit details
G-63
OHell + + He -> Total Hell + Dissociation
Cr-ossSection vs. Energy, -15IrAIU l i i i i i i i I i i i i i l '"l' ,
ff_
\\
4_" 'x,,.\E \\\
'.__/ \\,
c- \ \
© \'_ -16 \
10 - \'... _ Recommended(,.)
O <u - ---Data[/_ _ h5
(J9
8 -U _ Chebyshev Fit
10 17, ,, 1 J l J , _ J , I z ,J J, i J J _ _
104 1Q5 10_Energy (eV/a mu)
lP,
OH. Cross Sections for Interchange Reactions
Pager
H+ + D2 -> D+ + HD ............. H-2-> HD + + D ............. H-2
HD + + D2 -> HD2 + + D ............ H-4+ + H ............ H-4-> D 3
HD +(U=0) + He -> Hell+ + D .......... H-6
HD+(u=I) + He -> Hell+ + D .......... H-6HD+(u=2) + He -> Hell+ + D .......... H-6
HD +(_=3) + He -> Hell+ + D .......... H-6HD+(_,=4) + He -> Hell+ + D .......... H-6
H2+ + He -> Hell4 + H ............ H-8
H2+ + H2 - > H3+ + H ............. H- i0
D2+ + D2 -> D3 + + D ............. H-12
+"2->HD2++H .......... -14O +(u=l) + H 2 -> HD2 + + H .......... }{-14D2+(u=2) + H 2 -> HD2 + + H .......... H-14
D2+(_=3) + H 2 -> HD2 + + H .......... H-14
H +(_=0) + D2 -> HD2 + + D .......... H-162+(u=i) + D2 -> HD2 + + D .......... H-16H2+(u=2) + D2 -> HD2 + + D .......... H-16
H2+(.=3) + D 2 -> HD2 + + D .......... H-16H2 (_=4) 4- D 2 -> HD2 + + D .......... H-16
H-2
A
Cross Reactions for Interohange Reactions Between Prot:on_ and D2 /
H+ + D2 -> D_ + Hl)•-> HD* + D
D_ + ltD HD _ + D
Energy Cross Section Energy cross Section(eV / aalu ) (cm 2 ) ( eV / _uu ) (cm 2 )
4.5E-OI i. 18E-15 2.2E400 4 .67E-187.0E-OI 7.38E-16 4.0E+O0 2.22E-17I.OE4-O0 4.69E-16 4.5E+00 2.26E-17I.SE+O0 2.59E-16 7.0E+O0 1.29E-172.0E+O0 1.59E-16 I.OE+OI 4.03E-184.0E+O0 4.15E-17 1.5E.OI 1.28E-]87.0E+O0 1.47E-17 2.0E+01 6.95E-191.0E+O] I.IOE-17 4.0E+OI 2.72E-191.5E+01 9.80E-18 7.0E.OI 1.87E-192.0E+OI 8.78E-18 1.OB+02 1.67E-194.0E+OI 5.18E-187.0E+OI 2.90E-18I.OE+02 2.01E-18
References: 602, 603, 604, 605, 606, 620
Accuracy : Unknown
Notes: (i) For proton energies about 5 eV the product ion of D* may proceedalso via H+ + D2 -> D + 4 D + H. (2 ) For total reaction cross sections see:
Maier (Ref. 602); Ochs and Teloy (Ref. 604); Schlier et al. (Ref. 605); and
Holliday et al. (Ref. 603). (3) For relative yields of D . and HD _ see: Krenosand Wo_Sgang (Ref. 620). (4) Rate coefficient for thernlal energy is : k =3.7xi0 -lo cnlS/S fronl Fehsenfeld et al. (Ref. 606).
Chebyshev Fittinq Par_lleters tor Cross Sections
D. 4 HD Elldn = 4.5E-01 eV/6ullu, Ems x = I.OE+02 eV/aUllU
HD* + D Emi n = 2.2E+00 eV/_llu, Ema x = 1.0E+02 eV/ainu
AO A1 A2 A3 A4 A5 A6
D + + HD -75.6468 -3.22911 .4121.13 .0393398 -.26]749 _00129512 .120885
HD _ + D -82.0488 -2.46136 -.299817 .833081 -.341103 -.0343948 .0959803
The fit represents the D{ 4 HD cross sect loll with an rms deviation of 4.9%.
Tile maximum deviation is 9.3% at 7.0E+00 eV/_uuu.
The fit represents the HD + + D cross section with an rnls deviatiot] of 3.!5%.
The maximum deviation is 7.0% at 1.0E+0.1 eV/6m_u.
See appendix for C,hebyshev fit: cleta:i.l£_.
tt-3
OH+ + D2 -> D+ + HDH+ + D_-> HD+ + D
Cross Section vs° Energy10-1'__, , ,,,,,,,,,,,,, , , , ,,,,,, , , , ,,,,,_
A=D . + HD
10-1_ ,',- ""%,. X=HD . + D\
, tN
E 10-,G(--- ..
O'-_ - Recommended
Q _ _ --Data
Or) -17 _ ___ '
oCn 10 -: /,' \-"_
L_ "_. , >_ ' _"'%.'__,,_ ...... Chebyshev Fit
IO-,8 _._._lf3 -19 1 I l._j. liill i 1 Ii lllil i I i i|ill/ _.,"
10-' 100 10' 102Energy (eV/Gm u)
H-4
OCross Sections for Interchange Reactions Between HD + alld D2
HD + + ,D2 -> HD2 "_ 4. D
-> D3 _ + H
HD2 . + D D34 + H
Energy Cross section Energy Cross Section(evI_llu) (c.I2) (evl_llu) (cre')
6.0E-03 1 17E-14 6.0E-03 6.52E-15
7. OE-03 i. IOE- 14 7. OE-03 5.99E-15I. OE-02 9.45E-15 i. 0E-02 5.03E-151.5E-02 7.92E-15 i. 5E-02 4.15E-15
2. OE-02 6.93E-15 2. OE-02 3.58E-154. OE-02 5.08E.-15 4. OB-02 2.48E-157.0E-02 4. IIE-15 7.0E-02 1 •80E-I 5i. OE-O] 3.58E- 15 i. OE-OI i. 47E-15i. 5E-OI 3.07E-15 1.5E-Of I. ]4E-152. OE-OI 2.70E-15 2. OE-OI 9.55E-16
4. OE-OI I. 85E-15 4. OE-OI 5.78E-167. OE-O] i. IIE-15 7 •OB-Ol 3.54E-16i. OE+O0 7.05E-16 i. OE+O0 2.30E-16i. 5E+O0 3.49E-16 I. 5E+O0 I. 20E-162.0E+O0 i. 82E-16 2. OE+O0 6.60E-174. OE+O0 1.47E-17 4. OE+O0 6.33E-184.3E+O0 9.62E-18 4.3E+O0 4.59E-18
References: 607, 608
Accuracy: Unknown O
NQtes: None
Chebyshev Fittinq Parm_leters for Cross Sections
HD2 . + D Emi n = 6.0E-03 eV/ainu, Ema x = 4.3E+00 eV/oallu
D3 + + H Emi n = 6.0E-03 eV/mllu, Enlax = 4.3E+00 eV/anlu
AO A1 A2 A3 A4 A5 A6
HD2. + D -68.6683 -2.92522 -1.06891 -.570210 -.198731 -.0387800 -.0]84986
D3 . + H -70.3595 -3.11828 -.916067 -.449998 -.194126 -.0628098 -.00822327
The fit represents the HD2 _ + D cross section with an rnls deviation of 1.3%.
The maximum deviation is 2.9% at 4.3E+00 eV/amu.
The fit represents the D3 + + H cross section with an rnls deviation of 0.5%.The maximum deviation is 0.9% at 4.0E_O0 eV/_nu.
See appendix for Chebyshev fit details.
' H-5
ti+
HDD++D2-> HD_ 4-DH + D2 -> D3 + H
Cross Section vs. Energy--' I .... I I I I III I '1 I I I'J II1[ ,I I' 1 I I I1t1' I I 1 J I111.
A = HD_+ + D
10-1_ ,,_., . , , .,,
.
- X='D3 +H
-E _s_ 10- -
f2_ -0 -'
'_ - Recommended
0 -_ -
u_u_ 10'_0L. - ,
U : ..... Chebyshev Fit
10-17_.
10-le 1 ! 1 111111 1 1 1 l.lllll 1 1 1 111111 1, 1 111111,
10-3 10-,_ 10-i 100 101Energy (eV/am u)
1-1-6
Cross Sect.[Oll8 [or I llt6_ro h_llge Re61ct J.oll[4 [)6,tWOell HD+ 6111i] lie
II1.)t (.) "t He -> Hell' .t. D
tj., 0 u ,, 1 U - 2 U - ] U _ 4
Energy o Energy o Energy 0 EIIBT.gy 0 Ellergy c)
(eV/ainU) (cre _ ) (eV/ainu) {eta:') (eV/ainu) (c,m z ) ( eV'/tlllltl ) ' (cn, _ ) (eV/ainu) (cJm2 )
1 8E-01 7,70P.-18 1,9E-01 2.53E-17 2,0E-OI 6,15E-I'I 2,0E-01 1,25E-16 1,8E.,01 2,,,'15E-t6
20E-01 7,71E-18 2, OE-01 2,44E-01 3,0E-OI 3,82E-I'I 2,5E-01 1,03E-16 2,0E-OI 2,0_Z-16
30Z-01 7,.16E-18 3,0E-01 1,84E-17 4.0E-01 2,48E-17 3,0E-01 O,08E-I"I 3,0E-OI 1,26E-16
40Z-Ol 6,79E-18 4,0E-01 1,46E-17 5,0E.01 1,71E-t7 4,0E-01 4 51E-l'; 4,0E-Ol 8,05E-17
5 0E-OI 6.27E-18 5,0E-O! 1,22E-17 6,0E-01 1,27E-17 5,0E-01 2 54E-17 5,0E-01 5,29E-17
60E-01 5,79E-18 6,0E-01 1,04E-17 7,0E-OI 1.04E-17 6,0E-Of I 78E-i7 6,0E-OI 3,54E-17
70E-QI 5.37E-18 7,0E-01 9,22E-18 8,0E-OI 8,98E-10 '/,0E.,01 I 42E-17 7,0E-OI -",,44E-17
80E-OI 5,00E-18 8,0E-01 8,26E-18 9,0E-OI 8,08E-18 8,0E-01 I 23E-17 8,0E-Oi i,69E-17
90E-OI 4.68E-18 9,0E-OI 7,52E-18 I,OE_O0 7,45E-18 9,0E-OI I |3E-[7 g,OE-OI 1,22E-17
i OE+O0 4,37E-18 I.OE_O0 6,94E-18 ¿,5Ec.O0 6,51E_18 1,0E_O0 I 06E-17 I,OE400 8,94E-)(!
1 513_OO 3.31E-18 1,5E_00 5,29E-18 1,5E+O() I OIE-17 I,SE!OO 2o36E-10
1 7E_OO 3,08E-18
Referel]ce8 _ 609, 611
Accuracy. L Unknown
Notesl (1) Cross sections are presented mB a func, tton oi tllJ.tia] vtbrat:tolla[quantum nun_)er u. (2) The HD' ion beam was prepared In a given vJ.brat;.lollal st:ate
by selective photoionization of HD (Turner et _1. Ref. 611), (3) '['he thermal-energy (~0.1 eV) rate coefficient k for the HD + He reaction leading to all
products in Smith et al, (Ref, 609) _sl k = (],25 + 0.1)xi0 "I0 cm3/_1,
_Cheb.yshev Fittin.,q Par_ulleters for Cross Sect:lOllS
u = 0 B = 1 8E-01 eV/_lltl, = I 7E+00 eV/alllUu = I E lllin ' _]lllaX ' iu = 2 Bmln = 1.9E-01 eV/ainu, Eillax = 1.5E-_00 eV/ainuu = 3 Emln = 2.OE-01 eV/ainu, Emax = 1.5E+00 eV/allltlu = 4 Brain = 2.OB-OI eV/ainu, P'max = ].5E+O0 eV/ainu
mJn = 1.8E-01 eV/ainu, Smax = 1.5E+00 eV/_ml
AO Al A2 A3 A4 A5 A6
_] : 0 -79,5223 -,474196 -,106022 .00910711 .00412170 ,00308534 ,00343162
u = 1 -78,0058 -,002720 ,000bd1956 ,0202372 ,00181675 .000208519 .00196596
u = 2 -77,1958 -.I,20851 /141092 ,I01616 -.O0786021 -,0159891 ,0143204
U = 3 -76.1495 -1,42278 .227207 ,182149 -.0607895 -.0178064 ,O326454
U = 4 -75,8801 -2.27104 -,369722 -.00864579 .0064111"I ,O0107548 -.F)0589532
The fit represents tile u = 0 cross sect ion with arl rms deviation of 0,1%.
The maximum deviation is 0.]% at 4.0E-0I eV/ainu.
The fit represents the v = ] cross section with all rills deviation of 0.2%.
The maximum deviat:ion is 0.4% at 6,0E-0[ eV/_m_,
The fit represellt8 the u = 2 cross section wltll an rlns deviation (}f 0,2%,
The 81aximum deviatlon i8 0.5% at. 6.0E-01 eV/ainu,
The fit represents tile v = 3 cross sect.ton with an rnm deviation of 0.8%,
The maxi81tlnl deviation is 1.4% at 5.0E-OI eV/ainu.
Tile fit represel]ts the , = 4 cross sect:Icl} w]th an rms dev.iation oi 0.2%,
The maximum deviation is 0.6% at 8.0E-01 eV/ainu,
See appendix for Chebyshev fit. details,
H- "1
@HD+tz,,)+ He .,-> Hell . + D, HeD+ + H
'\\X\ ×=1,'=2
10-'e _" v - u : 1_-u:O
x'X," e:u:4.
5'-_ Recommended
b'_ -- Data
' Chebyshev FitU 1710- -
[! _...........
""'---._....,_
Y10- la I __-m___L_L_Z_m_L_L] L____L__4....J J _ L_L
10-' 100 ldEnergy (eV/omu)
11-8i
Cross Beatioll/_ for Illt:erchallg_ Re_et-.tons L_et:woell l.l;__ and lle
1.124 + He -> Hell" + Hi
Ellergy Velocity Crost4 Sect.Loll( eV/allltl ) ( oi,Is ) ( oiil _')
5 6E-01 1 04Ei.O6 5,13E-1660E-01 ] 08E+06 4.81E-.]670E-01 ] 16E+06 4,17E-16[! OB-01 ;l 24E,.t06 3.67E-1690E-01 1 32E-I.O6 3,24E-16I OEi.O0 ;[ 39E4'06 .2.86E-161 5E+00 1 70E+06 1,66E-.162 0E+00 1 96E.I.06 1.04F,-I#"30E+O0 2 41E+06 4,91E-174 0E4'OO 2 78F,-l06 3,0"1E-'].750E+O0 3 llE-t06 2.23E-176 0E+00 3 40E+06 1.77E-1770E+00 3 68E-l.06 1.49E-I/80E-i.O0 3 93E+06 1.29E-1790E+O0 4 17E+O6 1.16E-1"Ii OB+01 4 39E+O6 1.05E-1.7
609, 611, 612, 613, 614, 6.151 616, 617, 6181 619
Unknowll
(1) For relative total cross sect.ions see l Neyllaber and Magnuson
618), t2) For absolute cross sections as a ftlllction of vibrational _1_states of H2 see i Chupka and Russell (Ref. 616 ); Cllupka et al. (Ref. W617); Turner et al. (Ref. 611)2 and Govers apd Cluyol] (Ref, 619). (3) Forabsolute rate constants for produc;tiorl of Hell as a fUllCtlon of the eilergy
seel Von Koch and Friechllall (Ref. 6]5); and Sluith et al. (Ref. 609). (4)Rate ooefficlent k, at thermal energy for Hell+ production lsz k = Ii.4 +_,15]xlO "10 cm-_/mol s. (5) For data on D2 _ + He -> HeD _ seeI Smith et al.
(Ref. 609)° (6) Rate coefficlel]t k at therl,al ellergy for HeD + p roductJol]is] k = Ii.15 __ O.llxlO -IO ClW_/lllol,s.
Cl]e,,,bTstlev Fittinq Parameters for Cross sections
Enlln = 5.6E-0] eV/ailltl, P_.lillax = 1.0E+O]. eV/aiml
AO A1 A2 A3 A4 A5 A6
-74.2766 -2.0581] -.0177676 .136014 .00555409 -,0251696 -.000631817
Tile fit represents tile above cross section with an rnls dev,latlorl of 0.6%.Tile lllaxlilluill deviation is 1.4% at 3.0EiO0 eV/aluu.
See appendix for Chebyshev fit: cletat]s.
11-9
H_+ + He -:>Hell+ + Pl
_t,_,.J.:, vs Enetcjyi0T15 r------T----_----rTT_-'P_T---::, ,....r--r-TT-r-
I"1 E
(.),.._j'
©'._ 16
0 g lO- -_ Recommended, L,'_ - _ Data(.N -.U')0g-.
LO _ - .... Chebyshev Fit
O" 17.... I ___I__.___,I__Z___L_Z_I I I i J J J J I I l
"lC)-' 100 10'Energy (eV/a m LI)
11-10
OroBs Boc2L:L(.')IIB [.BL" Illt:e,l:{_llalITje Rea[Jt Jells [:]r;.,tweol| 1-12' EIIlC..I ii R O
II;_ ° .O II_ -> 113° .l. II
Uhlergy V_loc,'Ity C.'ro_ Seutloll(evlamu) (_:mlB) (o,i_)
i OF,-02 .| 391_-I'05 1,16[?I-142 OE-02 J 961_'I-05 1,03E-.I.4 ,4 01_-02 2 781_'I'05 B,631_.-157 OE-02 3 68B-F05 7,20t",.-151 OE-OI 4 391_,.I.05 6,23E-152 01_-01 6 2]_H'05 4,62_-154 O_J-01 8 79['.I+05 3.271-I:-157 01_--01 ] '.[6E-t-06 2,43_3-i5
I 0E"I'O0 I 39 t",-I06 I,I]7I_-.l5J 5E-I.O0 ] 70E+06 _,25l_.-152 OE-I.O0 ] 96E-I06 8,511!1-:164 0_3-I'00 2 7[IF.-I06 2,09F,-167 OE.I.O0 3 681!',-I'06 2,22l_]-17
._eferel]_Os I 607, 612, 613, 62:!, 622, 623, 0[_4, 625, 626, 627, 628, 629,631[, 632, 633, 636, 637
boou[acyl "oi 45%
Notesl (I') For relative total Dross sections Be,el Clew and FutreJ.1 (Ref,_")_TT- and Vance and BaJ.J.ey (Ref. 628), (2) . For absolute) rate oollst:allts as
a ftlnotlon of the stler_y see I Clew and FLittel] (Ref, 625) ; Bowers et: a],(Ref. 626 )) and Reuben alld Friechllan (Ref. 62'I). (3 ) For ellergydlst:ribLltlons of I13_ seel Lees and Ro.l (Ref, 638)I _llld Oellt:ry st: ai.. (Ref, B621). (4) For cross sectJollS aB a fHnct.|ol] of v wool Chupka el a.l, (Rot,629)) and Koyano allCl Tanaka (Ref, 633).. (5) For. k as a ful]atloll o£ u Beet
Theard and Htlrlterss _(Ref, 6.1=.3)['2 (6) Rate cJoE/fflc:t.ent: k at t:herlllal el lorcjyfor production of 1-13 tsl k- .0 -I-.jS]}l]O -_ Cl]13/s, frol}_ Refs, 613, 621,
623, 625, 626, 627, 63:1, 637,
¢l]e. byaltev Fittinq .... Par..atlleters for Cross Secttol)s
= ,' = 7 0I_-t-00 eV/ainuEml n 1.0E-02 eV/altlu, [_'ltlax '
AO A1 A2 A3 A4 Ab A6
-67.8902 -2.58783 -1.02353 -.461932 -,229219 -.0763343 --.01'70793
The fJt represents the above cross sect::[oll with atl rm[.J deviation of. 1,2%,The IlIlaX.illlUIII deviat:iofl is 2, '7% at 2. OE.tOO eV/_lllltl.
See appendix Jfer Chebyahev fit: clet-ails _,
O
I1.'-11
+ +H, H_+-I- H:_ > bl
Cross bection vs. Energy-13
10 ----r '-, ,'_',,,_'r--- , ' i i' , t,,J, .... I' ' ,...._ , ,-r'rT:,_
,.
"_ 10-15 Recommended¢_ - _Data
Lr)
O')
" Chebyshev Fit
10-'__
I
10-17 _ i , i 1 1 iiii I ..... 1 I 1 1 liiil _,.L- i i i iili_
10-= 10-' 100 101Energy (eV/am u)
,ll,-:i2
Cross Sections for Interchange rea_tlons Between D_ + and D z O
D_ -I.D2 -> D3'_ + D
Energy Velocity Cross Section(ev/ainu) (e.m/s) (cm2)
i, 6P,-01 5,56E+05 2,60B-152,0_:-01 6,21B+05 2.43B-153, OP,-01 7,61R.105 2. OOB-154, OB-OI 8.79B+O5 i, 69_,'-155.0P,-01 9,82E+05 1.45B-156. OE-OI 1.08E+06 I, 29B-15
7. OE-OI 1_16E'I06 I. 16B-158.0B-0,1 1.24E_06 1.06E-159.0_-0i 1.32_+06 _ 9.77B-161.0B+00 i. 39B+06 9.07E-16
I, 5B I'00 i, 70_+06 6.90E-162. OE+00 i. 96_+06 5,55_-163. OB+00 2,41B+O6 4.01E-16 '4. OE+Q0 2.78E+06 3.15_-164,2E+O0 2,85E+06 3,04E-16
R_eferenoes _ 623, 625, 626, 627, 631, 647
Unknown
(I) For relative cross sections seel Clew and F_Itrell (Ref. 625), (2)solute rate ool]stants as a fl.lnction of energy see! Drewitz (Ref. 631);
Harrison et al. (Rsf. 623); Reuben al_d l,"riech_an (Ref. 627); Clew and Futrell(Ref. 625); and Bowers st al. (Ref. 626). (3) For kir]etia energy distributionsof D3'+ products see! Doversplke and challlpiol] (Ref. 647), (4) Rate ooefficlent
for production of D3+ isl k = 1.55xi0 "9 Oli13/111ois froll% Refs. 623, 625, 626, 627,631. The states of reactants are ul]kll0Wll.
Chebyshev Fittinq Parameters for Cross Sections
Bmi n = i. 6B-01 eV/m_u, Ema x = 4.2_]+00 eV/a]_u
AO A1 A2 A3 A4 A5 A6
-69.1270 -1.09264 -.0827553 .0133959 -.0140139 .00530178 .00343451
The fit represents tile above cross section wlth ali rl)Is deviation of O. 2%.The luaxillluilldeviation is .4% at i. OE.lOO eV/_JIRI.
See appendl× for Chebyshev fit details.
H-13
0+ +
D2 + D_->D:_ + D
Cross Section vs. Energy0-14 I r t I 't 1 I i I I i /' i t' t''l I''
E "xo \
0 o 10_1s'-_ Recommended(.3@ - -- -, DataL/') - \
090
...... Chebyshev FitU
10-16 , i .... L. i _ J J.i II I ,l , , i i ,
lo-' _o° _o'Energy (eV/a m u)
' I
L
i,
H-14 L
Cross Sections for Interchange Reactions Between D2 _ and H 2
D2_(u) + H 2 -> HD2* + H, _
u= 0 u= i u= 2 u = 3
EIlergy o Energy o Eriergy o ' EIlergy o
(eV/aJllu) (Clll') (eV/aJllU ) (cre') (eV/ed,u ) (cre_ ) (eV /eu,_u) (cre2 )
5 8E-02 1.88E-15 5 7E-02 2,03E-15 5.8E-02 2.01E-15 5.8E-02 1.93E-156 OE-02 1.84E-15 6 0B-02 I 92E-15 6.0E-O2 1.96E-15 6 OE-02 1.9OE-15
7 OE-02 1,52E-15 7 OE-02 I 61E-15 7,0E-O2 1,76E_-15 7 0E-02 1.78E-15
8 OE-02 1.20E-15 8 OE-02 i 29E-15 8.0E-O2 1.57E-15 8 OE-02 1,62E-15
9 OE--02 9.67E-16 9 OE-02 i fOE-15 9.0E-02 1.42E-15 9 0E-02 1.49E-15
i 0E-01 8.3!E-16 I OE-01 9 66E-16 I.OE-OI 1.28E-15 I OE-01 1.36E-151 5E-01 5,70E-16 i 5E-01 6 93E-16 l. SE-Ol 8.29E-16 1 5E-01 8.8'15-16
2 0E-01 4.29E-16 20E-01 5 25E-.16 2,0E-OI 5.66E-16 2 0E-01 5.70E-16
30E-01 2.47E-16 2 5E-01 3 78E-16 2.5E-01 3.79E-16 2.5E-01 3.75E-16
3 5E-01 1,81E-16 30Ei01 2 79E-16 3.0E-O1 _ 2,77E-16 3.0E-OI 2.46E-16
40E-OI 1.52E-16 3 5E-OI 2 00E-16 3.5E-01 2.01E-16 3.5E-01 1.65E-16
4 6E-01 1.15E-16 40E-OI 1.44E-16 4.0E-OI 1.47E-16 4,OE-OI 1,12E-16
4 5E-OI 1.04E-16 4.5E-OI I.O.IE-16 4.5E-01 7.55E-17
4 6E-OI 9.61E-17 4.6E-OI 9.58E-17 4.6E-01 6.93E-17
Referel_ces : 625, 626, 627, 634, 638, 647, 652
Accuracy' 25%
Notes' (i) For relative cross sections see: C]ow aI_d FLILrell (Ref. 625). (2) For
rate constants, energy depel_dence see: Bowers et al. (Ref. 626),; and Clow andFutrell (Ref. 625). (3) For kinetic energy distributions of HD 2 proclucts seez
bees and Rol (Ref. 638); Doverspike and Chemlpion (Ref. 647), and Krenos et al.
(Re_. 652). (4) Rate coeflciellt for reaction D2 _ 4- H2 -> prodtlcts is: k = (3.0
+ O.6)xlO "9 ClII_/HIOIS frolll Clow and tqltrell (Ref. 625). (5) [)ata are presented as
a function of u, as reported in Ande1"son et al. (Re_. 634).
Chebyshev FittiHq Parameters for Cross Sections
u = O EmiE n = 5.8E-02 eV/ainu, Ema x = 4.6E-01 eV/ainu
u = 1 Emin 5./E-02 eV/ainu, Ema x = 4.6E-01 eV/ainuu = 2 5.8E-02 eV/edm_ = 4 6E-OI eV/ainu_ = 3 Emln ' Ema× '
rain 5.8E-02 eV/a]uu_ Ema x = .4,6E-01 eV/_urtu
AO Al A2 A3 A4 A5 A6
_J = 0 -70.4879 -].34605 -.0400746 -.0884724 .00327276 .04]0225 -.0238082
u = i-70.3174 -1.4137] -.174436 -.131909 -.00594907 .0250115 -.0190350
u = 2 -70.1696 -1.46820 -.256068 -.0411502 -.010"2313 -.00889023 -.0110482
u = 3 -70.3104 -1.61386 -.377596 -.0473991 -.00736333 .000736/57 -.00411866
The fit represents the u = 0 cross section with an rms deviation of 1.3%.
Tile maximum deviation is 3.3% at 3.5E-01 eV/Em,u.
The fit represents tile u = 1 cross _ectJon with au rms deviation of 0.7%.
The ma ximul, deviation is 1.3% at 6.0E-02 eV/6uHu.
The fit represents the u = 2 cross sectioll with all ,-ius deviation of 0.7%.
Tl_e maximum deviation] is 1.4% at 2.5E-01 eV/ainu.
The fit represents the u = 3 cross section with all rms deviation of 0.3%.
Tile maximum deviation is 0.4% at 8.0E-02 eV/Eu_u.
See appendi× for Chebyshev fit details.
0
,H-15
D_+OJ)-FH2 > HD2+ + H
Cross Section vs.Energyii I I I I
}{-16
, ,
Cross Sections for Interchange Reactions Between H 2_ and D 2 e{-t2+(.) .t- D 2 -> HD2 _ 4 H
t_ = 0 U =' 1 li = ,,,') ' _; = 3 I; = 4
Energy o Energy O Energy o Eliel:gy o Energy ,_)
(eV/alntl) {C/n a ) ' {eV/ainu) (cre2),• (eV/hl,u) (cinz) (eV/alntl) clll2) (oV/alilu) (cln2
1.7E-01 2 92E-15 1.7E-01 2 53E.-15 1,7E-01 2,46E-15 1.8E-01 2.45E-15 1,8E-OI 2.47E-15
2.0E-OI 2 91E-15 2.0E-01 2 43E-15 2.0E-01 2,41E-15 2.0E-OI 2 39E-15 2.0E-OI 2.40E-15
3.0E-OI 2 64E-15 3.0E-OI 2 15E-15 3.0E-OI 2.12E-15 ].OE-OI 2 13E-15 3.0E-01 2.14E-15
4.0E-OI 2 26E-15 4.0E-OI 1 91E-15 4.0E-OI 1.91E-]5 4.OE-OI I 91E-15 4.0E-OI 1.95E-15
5.OE-OI 1 92E-15 5.OE-O1 1 72E-15 5.OE-O] 1.7tE-15 5,OE-O] I 71E-15 5.0E-OI 1,8OE-15
6,0E-OI 1 62E-15 5.0E-OI I 68E-15 6.0E-OI 1.54E-15 6.OE-O1 i 58E-15 60E-OI 1.67E-15
7.0E-OI 1 36E-15 6.0E-OI 1 49E-15 7.OE-OI 1,42E-15 '7.0E-OI 1 46E-15 "7 ()E-OI 1.56E-15
8.0E-OI 1 14E-15 7.0E-OI 1 32E-15 8.0E-O] 1.3OE-15 8.0E-OI I 37E-15 80E-01 1.47E-15
9.0E-OI 9.72E-16 8.0E-OI 1 19E-15 9.OE-61 1.21E-15 9.0E-01 i 29E-15 90E-OI 1,39E-15
].OE+O0 8.51E-16 9.0E-OI ],08E-15 ].OE_00 ].liE-15 |.OEiO0 i 2]E-I'] ] OE_O0 1.32E-15
I,SE+O0 5.4P, F,-l'6 1.OE_O0 9 81E-16 1'SEt00 8'.39E-16 1.5ETOO 9.64E-16 I. 5E400 1.06E-152.0E+OO 4.24E-16 1.5E_00 6 61E-16 2.0E_OO 6.65E-16 2.0E*00' 7174E-16 20E+OO 8.6OE-1,6
3.0E.O0 3.02E-16 2.0E+O0 5 13E-16 3.0E_00 4.65E-16 ].OE_OO _.2tE-16 ] OE_O0 5.53E-16
4,0E.O0 2,39E-16 ],0EIO0 3 71E-16 4,OEr00 _,58E-16 4.OE+OO 3.73E-]6 40EIO0 3.55E-16
4.5E_OO 2.19E-16 4.OEiO0 3 07E-].6 5.OE+OO ';].9OF,-16 5.0E_O0 2 85E-16 4 .5E_O0 2.84E-16
5.OEiO0 2.74E-16 5.4EI00 2.7OE-16 5_2E_OO 2.8OE-]6
References: 62!$, 626, 621, 634, 6]8, 652
Acct!rgcy: 25%
NOteS: ( ] ) For energy dependeilce of rate const:ai]ts see : Bowers et all . (Ref.
626); Clow and Ftltrell (Ref. 625); and Reuben and Friedluan (Ref, 627). (2) For
kinetic energy distributions of HD2 + products see: Lees and Ro] (Ref, 638) ; and
Krenos et al. (Ref. 652). (3) For relative cross sections see: Clow and Futrell
(Ref. 625) . (4) Rate coefficiellt for re_ictioll 112+ _ D 2 -> P rodtlcts is: k =- ( 3.2
ii 0.6)xlO -9 clu3/nlol.s from Clow and Futrell Re[. 625). (5) Data are preserlted
as a function of u, as reported ill Andei:son et a.[ (Ref. 634).
Chebyshev Fittiilq Par alnete_ s for' Cross Sections--
u = 0 E : 1 7E-OI eV/alllti, : 4 5E+OO ciV/allltlu = 1 Elllin " Emax '
. 2 Brain = ].7E-Ol eV/ailu, Ema x = 5.0E+O0 eV/_ilu
u = 3 Elilin : 1.7E-OI eV/au]iu, El]lax = 5.4E+00 eV/alllu= ' , 1 BE-Oi eV/mlm = 5 2E+O0 eV/aulltl
IJ .-= 4 E lllln ' ' ["]111ax 'lui.n 1,8E-O1 eV/mim, Ema x = 4.5E+00 eV/_llu
AO AI A2 A3 A4 A5 A6
t; = 0 -69.2456 -1.40946 -.128223 .]39770 -.0170479 -.0330555 .00606671
it = ] -69.2502 -1.1.9199 -,]16093 ,0911706 ,0198857 -,0118162 -.O0051045]
U = 2 -69.1336 -i.1'2492 -,176104 .0165999 .00076044'1 .002'P3290 -.000454869
II = 3 -69.0426 -I.O6802 -,213967 -.O368351 -.6)0493123 .01.61013 .e'O775590
i) = 4 -68,8659 -.99;{859 -.258499 -.0853432 -.O286]04 -,0037;"291 .00520865
The fit represents tl]e . : 0 cross section with au rli|s der]at:ion of 1.3%.
The maximum deviation ]._ 2.0% at: ].OE4-00 eV/amtl.
The fit represents the u =, l cross sectioll wit:li arl rllis devJ.ation of 0.6%.
The maximunl deviation :i.s 0.8% at 7.0E-0] r.V/ailiu.
The fi,t represents the ,_ = 2 cross sect:ioll wJtll arl rllis deviat;ion of 0.]%.
Tile I1Ktxillltnil deviat.ioil ]s O. 7% at: ]. OE-0] eV/aillli,
The fit represents tLhe ,J = 3 cross sect]on wit, Di ai] i:llls (lev].atJorl of 0.5%.
The maxinlunl dev]ati.on ts ].3% at: 5.0E-t00 _,V/aluu, WThe fit represents the u = 4 cross sect.ion w]t:h ari rills deviati0n of 0.2%.The maxin_um deviation ].s 0.3% at ].OE.(J(J eV/'aml_,
See appendix for Cllebyshev lit detai Is,
H-17
O+ ++Htq2 (v) + D2-> HD2
Cross Section vs, Fnergy•_,--,-1.4-IU I I l I I till I i i I I I I I
10-1(_ i ,i, J J i J 1 li l l 1 j_l 1 I l
i10-I 100 10'Energy (eV/am@
!/sl
/
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682. J. T. Park and F. D. Schowengerdt, Phys. Rev. 18.._.55, ]52 (1969).
683. D. Krause and E. A. Soltysik, Phys. Rew. 175, 142 (1968).
684. E. W. Thomas, ed. p. 134 ill Excitation in Heavy Particle Collisiolls,Wiley-lnterscience, New York, 1972.
685. D. Hasse]kaaHp, R. Hippler, A. Scharmann, and K. H. Schartner, Z. Phys.
248, 254 (1911).
686 J. van den Bos, O. J. Winter, and F. J.. de Heer, Physica 40, 357 (1968).
687. A. Scharmann and K.-H. Schartner, Z. Phys. 228, 254 (1969).
688. E. W. Thomas and G. D. Bent, Phys. Rev. 164, 143 (1967).
689. J. O. Dodd and R. H. Hughes, Phys. Rev. 135, A618 (1964).
690. A. Denis, M. Dufay, and M. Oaillard, C. R. Acad. Sci. Paris Ser. B
264, 440 (1967).
691. J. Hill, J. Geddes, al_d H. B Gilbody, J. Phys. B 13, 951 (]980).
692. V. Dose and W. Herr, J. Phys. B "7, [,454 (1974).
693. E. P. Andreev, V. A. Ankudlnov, and S. V. Bobashev, Opt. Spectrosc. ]6,103 (1964).
694. R. D. Nathan and R. C. Is]er, Pl_ys. Rev. /,ett. 26, ].091 (1971). Q
R- 2 7
695. D. Dowek, D. Dhulcq, V. SIcll.s, and M. Barat, Pllyn. Rev. A 26, 746(] 98,2).
696. F. O. cle Flee[ and J. var] clen Bom, Phys:ic.a 31, 365 (]965).
697. O. Rahmat, G. Vasstlev, and d. Baudon, d Phys. (Paris) 4:_, 319 (1980).
698. D. Hasselkamp, R. ll_ppIer, A. Scharnlann, arld K.-H. Schartner, Z. Phys.25'7, 43 (1972).
699. V. Po]., W. Kauppila, and J. T. Park, Phys. Rev. A 8, 2990 (1973).
700. R. A. Young, R. F. Stebblrlgs, al'icld. W, McOowan, Pllys. Rev. ]7!, 85(]96aJ.
701. J.D.A. McKee, J. R. Sheridall, J. Oeddes, and H. B. Gilbc)dy, O. Phys. BiO, 1679 (1977).
702. V. A. Allktldillov, S. V. Bokanllev, ancl g. P. All(l_-eov, Soy. Phys. -JETP 25,235 (1967).
703. W. (_. F. Blair, R. W. McCtll ]ougll, F. R, Silllpson, and II. B. Oil body, J.Phys. B 6, 1265 (]973).
704. D. Bordenave-MontesquieU, A. Boutonnet, C. Bergnes, and R. Daclnac, J.Phys. B 16, ].93"I (1983).
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706. M. B. Shah and H. B. Gi]body, J. Phys. B 7, b122 (]974).
707. S. El. Dworetsky, R. Nov]ck, and N. Tot.k, p. 294 in VI Intern_itlonalCol'Iferel]ce.......on the Physics of Electronic and Atomic Collisions, MIT'," duly28-Auqust 2, 1969, Tl{e MI_ _ Press, C6mlbrlclge', Massach[ise6ts, ]969.
708. S. H. Dworetsky, R. Nov ick, W. W. Smith, and N. Tolk, Phys. Rev. I,ett.
18, 939 (1967).
709. J. T. Park, J. E. Aldag, J. M. George, a|ld J. 5. Peachet-, Phys. Rev. A
14, 608 ( 19'76 )
....... _ .L,_:)3710. J T. Park, J E Aldag, and J M O{,orge, Phys Rev. bett 34, or- (1975).
731. D. R. Bates and O. Griffin(], Pror:. Pllys. Soc. L,onch:)n 66, 64 (.I.953).
7:12. R. A. Young, R. F. Stebbings, and J. W. McOowan, Phys. Rev. 171, 85- (1968).
713. D. R. SchOOllOVer aiICl J. T. Park, Phys. Rev. A 3, 228 (1971).
714. A. I. Dashchenko, I. p. Zapesoclll]y], A. I. rf[lte, V. S. Bukst ]ch, F. F.
Danch, and V. A. Kel 'man, Soy. Phys.-JETP 40, 249 (1975).
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716. J. B. Aldag, J. I,. Peacher, P. J. Martln, V. SutclJffe, J. (]ec_rge, B.Redd, J. T. Kvale, D. M. Blallkerlship, and J. T. park, Phys. Rev. A 23,
_- 1062 (1981).
71"I. D. R. Scllocmover and J. T. Park, p. 839 in Vll International Col,ferenceon the Physic[_ of Electronic alld At.olllic Col.tisioI'is, A]llsterdalll, duly 26-30, 1971, North-Holland Pub]'.Jsh]nj] Co., Alusterd_uu, 1971.
718. M. K buura, T. Iggawa, and '['. lwai, p. 554 in Xi I|_ter|lational Confe ence. orl the Pllysics of Electronic aild Atolllic Co.l.f/sions, Kyoto, August ' 2--_9-
September 4, 1979, ]'979.
APPENDIX 1
O Calculation of Cross Sections and Rate Coefficientsfrom Chebyshev Fitting Parameters
i-i
' , APPENDIX 1
Calculation Of Cross sections and ,Rate coeffioients
from_ Chebyshev Fitti,n,g, ,Parameters
For _ase of numerical data retrieval, the method of least-
squares fitting to the reconunended cross sections and rate
coefficients ,using the Chebyshev orthogonal polynomials has
been used throughout this compilation. In general_ it
produced high accuracy fits to the recommended data.
A measure of the accuracy of the Chebyshev fit representationto the recommended cross sections has been calculated and
appears at the bottom of each cross section page as a relative
rms error with a maximum deviation. In a handful of cases,
the recommended cross sections had associated Chebyshev fits
With an error of greater than 1.00% rms error. These fits
have not been included and only the recommended cross section
data is presented.
The recommended cross-section and rate coefficient data have
been fitted to the following analytical expression:
D £n[a(E) ] = AJ2 + 7. AIT l(X) ,i=l
where k is the smallest number of coefficients that provides
an accurate fit (usually k=6), and
X = [ (£nE - £nEmin) - (£nE,_× - £nE) ] / (£nE_x - £nEmln) ,
and where TI(X ) are the Chebyshev orthogonal polynomials.Fitting to the natural logarithms of the cross section and
energy values increases the Chebyshev fit accuracy by reducing
the ranges of values for the cross section and energy byseveral orders of magnitude.
EThe values of fitting parameters Ai, E_in, and _× are glven foreach reaction after each cross--sectlon or rate-coefficient
table. In each case, the minimum number of parameters A i arelisted which are required to produce a satisfactory fit to the
data. The cross section o is given in units of cm 2, with
collision energies E in units of eV/amu. The rate c:oefficient
is in units of cm3/s, with Maxwellian temperatures T in
units of eV. (We follow the convention used frequently in
plasma physics of expressing temperature in eV energy units,
recognizing that kT is understood, where k is Boltzmann'sconstant.) The analytic representation of the cross section
O or rate coefficient should be used only in the region betweenEmln alld E_ax. The expressions for' the Chebyshev polynomialsare reproauced below for convenience.
1-2
TI(x)= XT2(X ) = 2 X2 1
%(x) = 4 x3- 3 xT4(X)= s x4 - 8 X2+ 1Ts(X ) = 16 X5 - 20 X3 + 5 X
T6(X ) = 32 X6 - 48 X4 + 18 X2 - 1
T 7_x) = 64 X7 i12 X 5 + 56 X3 7 XTs(X ) = 128 X s - 256 X6 + 160 X4 - 32 X2 + 1
All the rate-coefficient and cross-section data in this volume
may be reproduced by using either of the model Chebyshevfitting programs listed at the end of this Appendix For each
reaction and pair of reactants there are given Chebyshev
fitting parameters to be used as input to the CHEBFOR Fortranor CHEB Basic code.
Irl the iplots of recommended data the Chebyshev or alternative
fits have been added as dashed lines to give a visual
inspection of the accuracy of the fit. Also, the pagescontaining cross section tables include rms deviations of the
fit to the recommended data over the energy range from Emln to
m,_x,
The sample programs listed below Utilize recursion relations
to rapidly generate the Chebyshev polynomials and require
input o f the parameters _moln O, E x' and the Chebyshev
coefficients A0_ Al, A2, ... enable calculation of a rate
coefficient or cross section at a given energy. The programs
direct the user to input these parameters at the proper time
during program execution. To simplify data input, thetabulations of coefficients contain the minimum number of
significant digits required to produce an accurate
representation of the polynomial fit.
The ALADDIN database system may also be used to generate the
cross-section data directly from the fitting coefficients.
See Appendix 2 for details.
Sample FORTRAN Program
Program CHEBFORC This Fortran program is derived from a program in 'Elementary Numerical Analysis: AnC Algorithmic Approach' , S. D. Conte and C. de Boor, McGraw-Hilt, Inc., P.254, 1972.
DIMENSION D(IO)
REAL*4 ANS, ANS21000 TYPE 14'
'14 FORMAT(' IS THIS A FIT TO RATE COEFFICIENTS? ; ENTER "Y" FOR YES, "N" FOR NO')ACCEPT 199, ANS
199 FORMAT(Al)1010 TYPE 1515 FORMAT(' ENTER IHE NUMBEROF COEFFICIENTS')
ACCEPT 200, NTERMS
200 FORMAT(12) 0
b
i
1-3
Sample FORTRAN Program (Cont'd.)
IF(ANS .EQ. 'N') GO 'ro 16TYPE 1
1 FORMAT(' **** ENTER Emin (eV) *****')ACCEPT *, EMINTYPE 9
9 FORMAT(' **** ENTER Emax (eV) *****l)ACCEPT *, EMAXGO TO 25
19 FORMAT(' **** ENTER Emtn (eV/amu) ****')16 TYPE 19
ACCEPT *, EMINTYPE 29
29 FORMAT(' **** ENTER Emax (eV/amu) ****')ACCEPT *, EMAX
25 EMINL=ALOG(EMIN)EMAXL=ALOG(EMAX)TYPE 2, NTERMS
2 FORMAT(I ENTER ', [2,' COEFFICIENTS ')ACCEPT *, (D(J), J=I,NTERMS)
100 IF (ANS .EQ. tN°)GO TO 24TYPE 3, EMIN, EMAX
3 FORMAT(' INPUT TEMPERATURE(eV) BETWEEN ',lPElO.l,' AND ',1PElO.1,' FOR THE RATE& COEFFICIENT CALCULATION ')
GOTO 2624 TYPE 23, EMIN, EMAX23 FORMAT(' INPUT ENERGY (eV/amu)BETWEEN i,IPEIO.I,' AND ',lPElO.l,' FORTHE CROSS SECTION
& CALCULATION _)C TAKE ENERGY FOR CALCULATION AND USE THREE TERM RECURRENCERELATION26 K=NTERMS
CHEB=D(K)ACCEPT * XIF(X .LT. 0.) GO TO 101X=ALOG(X)K=K-1
. XNORM=(X'EMINL'(EMAXL'X))/(EHAXL'EMINL)Tt@DX=2.*XNORMPREV2=O.
10 PREV=CHEB[F(K .EQ. 1) GO TO 20CHEB=D(K)+TWO×*PREV'PREV_
= PREV2=PREVK=K-IGO TO 10
20 CHEB=.5*D(1)+XNORM*PREV-PREV2IF(ANS .EQ. 'Y') TYPE 69, EXP(CHEB)
69 FORMAT(_ RATE COEFFICIENT (CM3/S) = ',1PE12.4)IF(ANS .EQ. =N=) TYPE 45, EXP(CHEB)
45 FORMAT(' CROSS SECTION (CM2) = ',IPE12.4)TYPE 48
48 FORMAT(' DO YOU WANT ANOTHER CALCULATION FOR THIS FIT?, ENTER "Y" FOR YES; "N" FOR NO')
ACCEPT 199, ANS2[F(ANS2 .EQ, 'Y') GO TO 100TYPE 49
49 ' FORMAT(' DO YOU WANT A DIFFERENT FIT CALCULATION?, ENTER "Y" FOR YES; "N" FOR NO')
ACCEPT 199, ANS2= IF(ANS2 .EQ. 'Y') GO TO 1000: 101 END
1-4
SamPle BASIC. Pro ct_am
5 REM CHEB.BAS10 REH CHEB PROGRAMIS A BASIC PROGRAMDERIVED FROI4A FORTRAN20 REM PROGRAMIN "ELEMENTARY NUMERICAL ANALYSIS: AN ALGORITHMIC30 REM APPROACH**, S. D. CON(E AND C. de BOOR, 30 REMMcGRAW-HILL, INC., P40 REM 254, 1972.50 DIM D(IO)60 INPUT "IS THE k RATE FIT?; ENTER 'Y' FOR YES, 'N* FOR NO ",ANS$70 IF ANS$="Y*' THEN INPUT "ENTER Em|n (eV) ",EMIN80 IF ANSS="Y" THEN INPUT *'ENTER EmaX (eV) ",EMAX90 IF ANS$='*N" THEN INPUT "ENTER Emin (eV/ainu) ",EMIN100 IF ANS$="N" THEN INPUT '=ENTEREmax (eV/ainu) ",EMAX110 INPUT "HOW MANYCOEFFICIENTS FOR THIS FIT?*';NTERMS120 ENINL=LOG(EMIN)130 ENAXL=LOG(EMAX)140 °RI,NT USING"ENTER # COEFFICIENTS'*;NTERMS150 FOR J=l TO NTERMS ,160 INPUT D(J):NEXT J170 IF ANS$="Y" THEN PRINT USING ='INPUT ENERGY (eV/amu) BETWEEN###o# AND #.#^^^^ FOR THE RATECOEFFICIENT CALCULATION=';EMIN;EMAX180 IF ANS$="N" THEN PRINT USING *'INPUT ENERGY (eV/amu) BETWEEN###,# AND #.#^^^^ FOR THE CROSSSECTIONICALCULATION=*;EMIN;EMAX190 REM GET ENERGY FOR CALCULATION AND USE THREE TERM RECURRENCE200 REM RELATION210 INPUT X220 K=NTERMS250 CHEB=D,(K)240 IF X<O THEN END250 X=LOG(X)260 K=K-I
270 IF K=O THEN END
290280 XNORM=(X-EMINL-(EMAXL-X))/(EMAXL-EM]NL)Tk_)X=2eXNORM 0300 PREV2=O310 PREV=CHEB320 IF K=I GOTO 370330 CHEB=D(K)+TWOX*PREV-PREV2340 PREV2=PREV350 K=K'I
360 GOT0310370 CHEB=.5*D(1)+XNORM*PREV-PREV2380 IF ANS$="Y" THEN PRINT USING"#'#.## ^^^^ = RATE COEFFICIENT (CM3/S)";EXP{CHEB)390 IF ANS$="N" THEN PRINT USING"##.## ^^^^ = CROSS SECTION (CM2)";EXP(CHEB)400 GOTO 170410 END
0
APPENDIX 2
O ALADDIN Database System and Data Files
2-1
O' APPENDIX 2 '""'
A_ADD!_, DatAb, aSe s¥stem an,_ Dat_, Files
ALADDIN 1,2 is an atomic physics database system which hasbeen developed by R. A. Hulse of Princeton Plasma PhysicsLaboratory in conjunction with the Atomic and Molecular DataUnit of the International i\tomic Energy Agency (IAEA) to
provide a broadly-based standard medium for the exchange andmanagement of atomic data. ALADDIN has been adopted by theIAEA as the standard international atomic physics dataexchange format for magnetic confinement fusion applications.
ALADDIN consists _ of a data format definition together
with supporting software for both interactive searches andaccess to the data byplasma modelling and other computercodes. The ALADDIN software has been written in strictFORTRAN-77 to ensure compatibility with the widest possiblerange of scientific computers. The data are stored in
• straightforward ASCII text files either in tabular x,y orparametrized format. Provision has been made _within ALADDINto incorporate the subroutines which are needed to extract theatomic data from each ALADDIN data entry. The Chebyshev
polynomial fits which are presented for the data in thisvolume are one example of such a parametrization.
OAll recommended cross-section data fromthe compilations
in the Atomic Data for Fusion series are available in ALADDIN
format (including those from this volume). Table 2.1 containsa sample ALADDIN data entry from each chapter of this volume.Each entry contains a page-number label to expedite locatingspecificdata within the file. Complete ALADDIN data filesfor this series and a copy of the ALADDIN Database program areavailable on PC-DOS-formatted diskettes from:
Controlled Fusion Atomic Data Center
Oak Ridge National LaboratoryP. O. Box 2008MS-6372
Oak Ridge, .TN 37831-6372, U.S.A.
A copy of the ALADDIN Manual 2 which contains instructionsfor its use and a dictionary of abbreviations and symbolicnotations for collision processes is also available from theabove address. The ALADDIN code and reference material arealso available directly from the IAEA (see address below).
The ALADDIN data files and FORTRAN program may also betransmitted readily by electronic mail, and are available bycontacting:
2-2
With input from a number of international data centers, O
the Atomic and Molecular Data Unit of the IAEA is assembling
a larger ALADDIN data base of atomic and molecular processes
relevant to fusion applications, and is providing officiallyrecomz_ended data in ALADDIN format. Further information may
be obtained by contacting:
Atomic and Molecular Data Unit
Nuclear Data Section
International Atomic Energy AgencyP. O. Box i00
A-1400 Vienna, Austria
or by electronic mail at_
i. R. A. Hulse, "The ALADDIN Atomic Physics DatabaseII
System, pp. 63-72 in Atomic Processes in Plasmas, AIP
Conference Proceedings 206, ed. Y. K. Kim and R. C.
Elton, AIP, New York, 1990.
2. ALADDIN Manual, A System for Storage, Exchange and
Management of Atomic and Molecular Data for Fusion, IAEA-
NDS-AM-17, Atomic and Molecular Data Unit, Nuclear Data
Section, International Atomic Energy Agency, Vienna, June1989.
II
""3
TABLE 2 •1
S_mple ALADDIN Data File
$ CX H [+i] H ['+0] H [+0] H [+i]& XS EVAL ACC=B ORNL-CFADC DOC-ORNL-6086 A-22 6/90 #CHEB
-72.6656 -5.49142 -3.42948 _1.98377 ..0.878009
-0.198932 0.0837431 0.121252 0.0827182 0.12 630000
$ CXSS He [+2] H [+0] (G) He [+I] (28) H [+I]& XS _ EVAL ACC=C ORNL-CFADC DOC=ORNL-6086 B-89 6/90 #CHEB
-89.4268 -0.438776 _t -8.73454 0.130314 -0.01012100.0343355 0.227699 _ -0.188121 -0 130396 23. 2500000.
$ Exc H [+0] (G) H [+0] (O) H [+0] (2s) H [+0]& ES EVAL ACC=? ORNL-CFADC DOC=ORNL-6086 C-2 8/89 #CHEB
-79.1098 -0.784062 -0.651723 0.0462865 0.114234
-0.00487654 -0.0114391 0.0 0.0 2000. _ 90000.
$ ION H [+I] H [+0] H [+i] H [+I] e& ES EVAL ACC=B ORNL-CFADC DOC-Omre-6086 D-6 5/90 #CHEB
-75.505348206 -0.409784913 -0.996553540 0.355360299 -0.049000371-0.034998417 0.043782476 0.0 0.0 9400. 1500000.
O $ STRIP H [+0] H [+0] H [+i] H [+0] e& XS EVAL ACC=B ORNL-CFADC DOC=ORNL-6086 E-2 5/90 #CHEB
-77.1793823242 -0.4514082074 -1.5175991058 0.5439749956 -0.0355154276
0.0025895350 -0.0750899166 0.0 0.0 1200. 3500000.
$ ELDET H [-I] H [+0] H [+0] H [+0] e& XS EVAL ACC-C ORNL-CFADC DOC=ORNL-6086 F-2 5/90 #CHEB
.! -72.0698776245 -2.4792380333 -0.9363254905 0.0886530057 0.01753922550.0545278080 -0.0645320490 0.0 0.0 ii0. 4000000.
$ DISION2 H [+0] HI2} [+0] H [+0] H [+i] H [+I] 2e& XS EVAL ACC=? ORNL-CFADC DOC=ORNL-6086 G-2 6/90 #CHEB
-82.5844192505 1.5008718967 -0.5141620040 -0.0138262566 0.0274858437
-0.0085383281 -0.0116637163 0.0 0.0 5000. 50000.
$ PX H [+i] D{2) [+0] D [+i] HD [+0]& XS EVAL ACC-? ORNL-CFADC DOC=ORNL-6086 H-2 9/89 #CHEB
-75.6467819214 -3.2291088104 0.4121128917 0.039,3397696 -0.2617489398
0.0012951158 0.1208853275 0.0 0.0 0.45 i00.
i
APPENDIX 3
Atomic PhysicsHandy Conversion Units and Formulas
3-1
O APPENDIX 3
Atomic Physics
Handy Conversion Units and Formulas
Conversion units
i electron volt = 1 ev = 8065.76 cm "I = 23.069 kcal/mol =
1.6022 x 10 "12 ergs = 1.6022 x 10 "19 joules
1 atomic unit = 1 a.u. = 2 Rydbergs = 27.21 eV = 1 Hartree
1 atomic mass unit = 1 a.m.u. = 1.6605 x 10 .24 gm
Atomic velocity = velocity of 13.6 eV electron = 2.18 x 108
cm/sec = velocity of 24.97 keV proton
Atomic radius = radius of first Bohr orbit of H° = 5.29 x
10 .9 cm
1 angstrom = 1 A = 1 × 10 .8 cm
O Electron mass, m e = 9.110 x 10 .28 gmElectron charge, e = 4.8032 x 10 "1° statcoulomb, or 1.6011 ×10 "19 coulombs
Proton mass= 1.673 × 10 .24 gm
' 0 c .Atomic unit of time atomic radlus/atoml velocity = 2 42 x
I0 Iz sec
Boltzmann constant, k = 1.381 x 10 "16 erg/°K,
1 mm Hg = 133.3 pascals = 1 torr; 1 mBar = I00 pascals
Atomic cross section = _ x (atomic radius) 2 = _ao 2 = 8.797 ×10 -17 cm 2
1 mol 6.022169 x 1023 molecules = Avogadro's number
Loschmidt's number = number of molecules at 1 mm Hg at 0°C =
2.687 x 1016 cm "3
3-2
OFormulas
Velocity (non-relativistic) (cm/sec) = 1.38 × ]06 (E/m) I/2,
where E = energy of the particle in eV, of mass m in a.m.u.
Energy levels in hydrogen-like atoms,
-13.6 Z2
En(eV ) = n2-;
where Z is the atomic number and n is the total quantumnumber.
Wavelength of a photon,
(A) = 1.2398 X 104E
where E is the photon energy in eV.
Wavelength of a non-relativistic electron,
-- l
where T is the temperature of the electrons in eV.
Relative velocity (cm/s) = V r = (V.2 + V,2 - 2ViV2cos8 )I/2
where V =: velocity of particle 1 in cm/sec, V 2 = velocityof part%icle 2, and 8 = angle of approach.
Energy (center of mass) (eV) =
........ cos@MI+M2MI Ms MIM2
where MI, EI are the mass and energy of particle 1 and M_, E2are the mass and energy of particle 2, respectively, an_ 0
is the angle of approach.
3-3
• l.... Plasma p,hysics _
Handy ,Formu!a__s
*Gaussian units are used in the formulas below except for
the following: Temperatures, _ of 61ectrons, and T i ofions in eV. Mass of ions, m i expressed in units of
proton mass, m b by _a= ml/mP; B in gauss; k is Boltzmann'sconstant; ne a_d n i re number densities of electrons andions, respectlvely, in cm'3; Z is the charge state of anion; _ is wavelength in A; c is the speed of light in vacuum(3 x 1010 cm/sec) ; and frequency is _ (rad/sec) =2_' f (cycles/sec)
For Electrons:
Plasma frequency, Ope (rad/sec) = 5.64 x 104 ne1/2
Gyrofrequency_ _ce (rad/sec) = 1B76 x 107 BGyroradius, re (cre) = 2.38 TeI/2 "Electron thermal velocity, vie (cm/sec) = 4.19 x 107 Tei/2
17.34
Electron deBroglie length, _ (A) =--Te--_-T
OFor Ions:
Plasma frequency, _-i (rad/sec) = 1.32 x i03 Z _-I/2 nil/Z3 -I B
Oyrofreq_lency, _ci (rad/sec) = 9.58 x 10 z1_ B"IGyroradius, r I (cm) = 1.02 x 102 _I/2 Z-I/2TiIon thermal velocity, Vti (cm/sec) _= 9.79 x I0 s _-I12 TII12
Drift velocity of particles in a constant electric field, E(volts/cm), perpendicular to a constant magnetic field, B(gauss), independent of mass m, or charge Z, of the particleis given by:
v E (cm/sec) = 1 x 108 _-B
Phase velocity, vt (cm/sec I = u/k, where _ is in rad/sec andk is the wavenumber in cm-.
Group velocity, vg (cm/sec) = dQ/dk
Alfven velocity, vA (cm/sec) = 2.18 x 1011 _I/2 ni-I/2B
Debye length, _D (cm) = 7.43 x 10 2 Te I/2 ne"I/2
• *
3-4
Maxwellian veloclty distribution for- a constant temperature @
plasma, for one-.dimens:ion: i
F (V) (c.m"]) = n' (m/2_kt) I/2 exp(-mv2/2kt)' II_.tX
o ' i |
whe_:'e t- is in K, m is the pal"tlcle s mass in gm n is the
number density (cre3), k is Boltzmann's consta;lt '(1.38 x .].0-16
erg/°K), and v is the particle's velocity (cm/sec) for one-dimension.
Saha thermal equilibrium:
ni/n n _ 2.4 x 1015 (t_l_/nl) exp(-Ui/kt ) ,
where n is the .numbel" density of neutrals in cm 3, U i i.._, theionizat'lon energy of the gas in ergs, and t is the
temperature of the ga_ in °K.
Top Related