Post on 21-Dec-2015
Iain StewartMIT
Iain StewartMIT
Nonleptonic Decays and the Soft Collinear Effective Theory
Nonleptonic Decays and the Soft Collinear Effective Theory
Super B Factory Workshop, Hawaii, 2004
• Introduction: What is the Soft-Collinear EFT?
•1) Lessons from
•2) Factorization for
•Outlook and Open Issues
•Clean:
•Color Suppressed:
•Baryons:
•CP violation:
•Clean:
•Color Suppressed:
•Baryons:
•CP violation:
•Clean:
•Color Suppressed:
•Baryons:
•CP violation:
•Clean:
•Color Suppressed:
•Baryons:
•CP violation:
• Introduction: What is the Soft-Collinear EFT?
•1) Lessons from
•2) Factorization for
•Outlook and Open Issues
•Clean:
•Color Suppressed:
•Baryons:
•CP violation:
•Clean:
•Color Suppressed:
•Baryons:
•CP violation:
•Clean:
•Color Suppressed:
•Baryons:
•CP violation:
•Clean:
•Color Suppressed:
•Baryons:
•CP violation:
OutlineOutline
ie.ie.
Factorization Theorem
Factorization TheoremHard vs. Jet:
Hard vs. Jet:
Polarization:
Polarization: Charming penguins, Power
corrections Charming penguins, Power
corrections
in SCETin SCET
Two body nonleptonic decays. Simple?
Two body nonleptonic decays. Simple?
B
B
π
π
Note: Nonleptonic B-decays are not Gold Plated
Observables for Lattice QCD
Note: Nonleptonic B-decays are not Gold Plated
Observables for Lattice QCD
Electroweak HamiltonianElectroweak Hamiltonian
b u
d
u
W
b u
u
d
u
u
b
W
d
g
db
uu
db
uu
u,c
QuickTime™ and aGIF decompressorare needed to see this picture.QuickTime™ and aGIF decompressorare needed to see this picture.
QuickTime™ and aGIF decompressorare needed to see this picture.
= CKM factors= CKM factors
1.Use SU(2) or SU(3) to relate amplitudes so data can be used to reduce uncertainties.
• Flavor symmetries of QCD,
2.Factorization from QCD to reduce the amplitudes to simple universal nonperturbative parameters.
• Expand in
1.Use SU(2) or SU(3) to relate amplitudes so data can be used to reduce uncertainties.
• Flavor symmetries of QCD,
2.Factorization from QCD to reduce the amplitudes to simple universal nonperturbative parameters.
• Expand in
Measuring CP violation in “unclean” decays requires
Measuring CP violation in “unclean” decays requires
These two possibilities are not exclusive.These two possibilities are not exclusive.
The important thing to keep in mind is “what are the uncertainties”.
The important thing to keep in mind is “what are the uncertainties”.
• Beneke, Buchalla, Neubert, Sachrajda proposed a QCD factorization theorem for , QCDF .
• Amplitude is reduced to simpler matrix elements
• At LO in strong phases are perturbative,
, and therefore small.
• Beneke, Buchalla, Neubert, Sachrajda proposed a QCD factorization theorem for , QCDF .
• Amplitude is reduced to simpler matrix elements
• At LO in strong phases are perturbative,
, and therefore small.
Factorization in QCDFactorization in QCD
,, ,,
form factorform factor hard spectatorhard spectator
Keum, Li, Sanda:pQCD FactorizationKeum, Li, Sanda:
pQCD Factorization
PP = 21 + 13 decays
PV = 40 + 23 decays
VV = 21 + 13 decays
PP = 21 + 13 decays
PV = 40 + 23 decays
VV = 21 + 13 decays
Chiang et al.Chiang et al.SU(3) analysis SU(3) analysis
QCDF analysisQCDF analysisBeneke & NeubertBeneke & Neubert
eg.eg.
• Separate physics at different momentum scales
• Power expansion
• Make symmetries explicit
• Model independent, systematically improvable
• Separate physics at different momentum scales
• Power expansion
• Make symmetries explicit
• Model independent, systematically improvable
Effective Field TheoryEffective Field Theory
• An effective field theory for energetic hadrons,
• An effective field theory for energetic hadrons,
Soft - Collinear Effective Theory
Soft - Collinear Effective Theory
Bauer, Pirjol, StewartFleming, Luke
Bauer, Pirjol, StewartFleming, Luke
Soft Collinear Effective TheorySoft Collinear Effective Theory
eg.eg.
Introduce fields for infrared degrees of freedom (in operators)Introduce fields for infrared degrees of freedom (in operators)
Degrees of freedom in SCETDegrees of freedom in SCET
Energetic jetsEnergetic jets
Energetic hadronsEnergetic hadrons
FactorizationFactorization
Bauer, Pirjol, I.S. Bauer, Pirjol, I.S.
Universal functions:Universal functions: Calculate T, Calculate T,
Universal hadronic parameters
Universal hadronic parameters
SCET Expansion SCET Expansion
Observed 2001Observed 2001Large - not very predictiveLarge - not very predictiveNaive Factorization - too smallNaive Factorization - too small
(Cleo, Belle, Babar)(Cleo, Belle, Babar)Data
20-30% level20-30% level
Color Suppressed DecaysColor Suppressed Decays
Mantry, Pirjol, I.S. ‘03
Mantry, Pirjol, I.S. ‘03
Factorization with SCET Factorization with SCET
QCDQCD
new soft functionnew soft function
- like generalized parton distributions
- like generalized parton distributions
QCDQCD
Theory: Theory:
Phenomenology:
Phenomenology:
is complex, new mechanism for rescatteringis complex, new mechanism for rescattering
with HQET forwith HQET for getget
not a convergent expansionnot a convergent expansion
Tests and PredictionsTests and Predictions
Tests and PredictionsTests and Predictions
All predictions so far are independent of the form of All predictions so far are independent of the form of
and and
ie. same Br and same strong phases
ie. same Br and same strong phases
More PredictionsMore Predictions
• nonperturbative strong phases are natural
• Nonperturbative J vs. Perturbative J
• With the entire amplitude power suppressed the polarization issue in B to VV is non-trivial
• nonperturbative strong phases are natural
• Nonperturbative J vs. Perturbative J
• With the entire amplitude power suppressed the polarization issue in B to VV is non-trivial
Lessons
Lessons
SCET ResultSCET Result
Chay, KimChay, Kim
Bauer, Pirjol, Rothstein, I.S. (to appear)
Bauer, Pirjol, Rothstein, I.S. (to appear)
operators, exponentiation of soft & collinear gluonsoperators, exponentiation of soft & collinear gluons
hard spectator & form factor terms hard spectator & form factor terms same operatorssame operators
long distance charming penguinslong distance charming penguins
analysis for PP, PV, VVanalysis for PP, PV, VV
unique functionunique function which is also in which is also in
Operators
OperatorsQCDQCD
Integrate out Integrate out fluctuationsfluctuations
......
......
Long Distance Long Distance
dangerous region near threshold
dangerous region near threshold ,,
NRQCD NRQCD
power suppressionpower suppression
couple to b, spectatorcouple to b, spectator
Polarization
Polarization
......
......
......
ie. SCET agrees with A. Kagan for polarization fraction:
ie. SCET agrees with A. Kagan for polarization fraction:
NoNo
power suppressedpower suppressed
unless it is spoiled by charming penguins!
unless it is spoiled by charming penguins!
Same Jet function as Same Jet function as
New Nonperturbative Result in New Nonperturbative Result in ::
fit fit , calculate T’s, calculate T’s
Hard CoefficientsHard Coefficients
Note: have not used isospin hereNote: have not
used isospin here
can use SCET, but there is a lot of work
left to do
can use SCET, but there is a lot of work
left to do
Open Issues inOpen Issues inFactorization formula with charming
penguins?Factorization formula with charming
penguins?Role of other degrees of freedom: messenger modes, Glaubers
Role of other degrees of freedom: messenger modes, Glaubers
ie. ie.
Power Corrections:Power Corrections:
expect nonperturbative phasesexpect nonperturbative phases
“chirally” enhanced terms, annihilation“chirally” enhanced terms, annihilation
Becher, Hill, NeubertBecher, Hill, Neubert
Factorization theorems usually do not try to untangle Factorization theorems usually do not try to untangle
fromfrom left in nonperturbative functions
left in nonperturbative functions
• Non-analytic terms vanish
• With all NLO operators, ie all the leading SU(3) violation:
• Non-analytic terms vanish
• With all NLO operators, ie all the leading SU(3) violation:
Using chiral perturbation theory we find:
Using chiral perturbation theory we find:
“Gell-Mann Okubo”
“Gell-Mann Okubo”
all in all in
OutlookOutlook
SCETSCET
We have only seen the tip of the
iceberg
We have only seen the tip of the
iceberg