Post on 26-Apr-2020
S1
Electronic Supplementary Information
Topologically diverse shape-persistent bis-(Zn-salphen) catalysts efficient cyclic carbonate formation under mild conditions
Shixiong He Fuli Wang Wah-Leung Tong Shek-Man Yiu and Michael C W Chan
Department of Biology and Chemistry City University of Hong Kong Tat Chee Avenue
Kowloon Hong Kong China Email mcwchancityueduhk
Electronic Supplementary Material (ESI) for ChemCommThis journal is copy The Royal Society of Chemistry 2015
S2
Experimental Section
General Considerations and Instrumentation Propylene oxide epoxybutane and 12-
epoxyhexane (Sigma-Aldrich) were distilled from CaH2 and 2-butanone (MEK methyl ethyl
ketone) was distilled from K2CO3 and all were stored over 4 Aring molecular sieves Carbon dioxide
(research grade 99999) was purchased from HK Scientific Gas Engineering Co Ltd and
used as received Mesitylene was dried over 4 Aring molecular sieves Tetrabutylammonium iodide
(Acros) was recrystallized using dry acetone and diethyl ether (110) and dried in a vacuum
oven at 90 oC for 48 h All reactions that describe the use of dry solvents were performed under a
nitrogen atmosphere and the solvents were appropriately dried and distilled prior to use for the
remaining reactions solvents (analytical grade) were used without further purification 1H and 13C NMR spectra were recorded at 298 K on Bruker Avance III 300 400 and 600 MHz NMR
spectrometers (ppm referenced to residual solvent peaks) ESI mass spectra were measured on a
Perkin-Elmer SCIEX API 365 mass spectrometer Elemental analyses were performed on a
Vario EL elemental analyzer (Elementar Analysensysteme GmbH) The synthesis of L112 L223
L545 L82 L92 and complex 12 were described previously
General Procedure for CO2 Reactions CO2 reactions were performed using a Teflon liner
in a 100-mL Parr stainless steel high-pressure reactor equipped with a paddle-like stirrer The
epoxide (in MEK [5 mL] or neat [epoxypropane and -hexane 3 mL epoxybutane 5 mL])
catalyst nBu4NI cocatalyst and mesitylene (internal standard) were introduced into the reactor
which was then subjected to three cycles of pressurization and depressurization with CO2 (at half
of reacting pressure) before final stabilization at the chosen reacting pressure The reactor was
sealed heated to the required temperature and stirred at 500 rpm for the prescribed time The
reactor was then cooled to 10 degC using ice water and the remaining pressure was slowly vented
An aliquot (60 microL) of the reaction mixture combined with CDCl3 (440 microL) was taken for 1H
NMR analysis (90deg flip angle 30 seconds relaxation delay) The conversion which was
reproducible within plusmn2 in at least 3 independent runs for selected experiments was calculated
from the 1H NMR integration of the cyclic carbonate product against the mesitylene internal
standard
S3
Synthetic Methods
R2
O
CHOOH
Zn(OAc)2 NEt3MeOH
H2N N
HO R2
tBuR2 = H (L8)R2 = tBu (L9)
B
O
B
OH
OH
OH
OH
(L1)
R2
O
ON N
OZn
ON N
OZn
tBu
tBu
Pd(PPh3)4 K2CO3
Br OH
CHO
2 dil HCl (aq)
R11
DMEH2O
R1
CHOOH
R1
R1 = H (L2) tBu (L3)
R1
R1
R1 = H R2 = tBu (1)R1 = tBu R2 = H (5)R1 = R2 = tBu (6)
I CHO
OH
1O
OHCHO
OHCHO
O
NN
OO Zn
tBu
tBuN
NO
O Zn
tButBu
(2)
Zn(OAc)2 NEt3MeOH
H2N N
HO tButBu(L9)
(L4)
tBu
tBu
O
ON N
OZn
ON N
OZn
tBu
tBu
(3)
ZnCl2 NaOMeEtOHCH2Cl2
H2N N
HO tButBu(L10)
Pd(PPh3)4 K2CO3
2 dil HCl (aq)DMEH2O
R1 = H
Zn(OAc)2 NEt3MeOH
H2N N
HO R2
tBuO
B(OH)2
B(OH)2Pd(PPh3)4
K2CO3
Br OH
CHO
2 dil HCl (aq)
O
OHCHO
R1
OH
CHO
R1
R11
R1 = H tBuR2 = tBuMeOH(wash)
O
R2
ON
NOZn
tBu
R1
R2
ON
NO
Zn
tBuR1
H2O(wash)
R1 = tBuR2 = H
[7 AcOH]
DMEH2O
R1 = H R2 = tBu (4)R1 = tBu R2 = H (7)R1 = R2 = tBu (8)
(L5)
R1 = H (L6) tBu (L7)
R2 = H (L8)R2 = tBu (L9)
Scheme S1 Synthesis of complexes 1ndash8
S4
Compound L3 L1 (082 g 20 mmol) 2-hydroxy-3-tert-
butyl-5-bromobenzaldehyde (122 g 476 mmol) and Pd(PPh3)4
(005 g 004 mmol) were suspended in a deoxygenated solution of
K2CO3 (122 g 880 mmol) in DMEDI water (31 40 mL) The
reaction mixture which became a clear orange solution upon
heating was then stirred under reflux for 3 h during which the
color of the solution became dark brown The mixture was cooled to 0 degC after which 1 M
aqueous HCl (20 mL) was added and the mixture was stirred at room temperature for 1 h Water
(100 mL) and chloroform (200 mL) were added to the resulting orange suspension After stirring
at room temperature for 1 h the organic layer was separated and washed with water The
resultant orange solution was dried over MgSO4 filtered and concentrated to dryness The crude
product was further purified by column chromatography (SiO2 hexaneCH2Cl2 11) to give the
desired product as a yellow solid Yield 092 g 68 1H NMR (300 MHz DMSO-d6) δ 1171 (s
2H OH) 947 (s 2H CHO) 760ndash743 (m 6H) 719 (d J = 22 Hz 2H) 173 (s 6H CH3)
134 (s 18H tBu) 120 (s 18H tBu) Compound L4 The procedure for the synthesis of L3 was
adopted using L1 (070 g 17 mmol) and 2-hydroxy-4-
iodobenzaldehyde (10 g 40 mmol) The crude product was
purified by column chromatography (SiO2 hexaneCH2Cl2 12) to
give the desired product as a pale yellow solid Yield 051 g 53 1H NMR (300 MHz DMSO-d6) δ 1014 (s 2H CHO) 756 (d J =
23 Hz 2H) 732 (d J = 80 Hz 2H) 716 (d J = 23 Hz 2H) 684
(d J = 12 Hz 2H) 676 (d J = 80 Hz 2H) 170 (s 6H CH3) 132 (s 18H tBu)
Compound L6 The procedure for the synthesis of L3
was adopted using L5 (200 g 782 mmol) and 2-hydroxy-5-
bromobenzaldehyde (346 g 172 mmol) The crude product
was purified by column chromatography (SiO2 CH2Cl2) to
give the desired product as a pale yellow solid Yield 24 g
75 1H NMR (300 MHz DMSO-d6) δ 1102 (s 2H OH)
S5
1036 (s 2H CHO) 830 (s 2H) 824ndash807 (m 4H) 773 (d J = 76 Hz 2H) 749 (dd J = 78
and 75 Hz 2H) 720 (d J = 86 Hz 2H)
Compound L7 The procedure for the synthesis of L3 was
adopted using L5 (080 g 31 mmol) The crude product was
purified by flash chromatography (SiO2 CH2Cl2hexane 11) to
give the desired product as a yellow powder Yield 12 g 74 1H NMR (400 MHz DMSO-d6) δ 1189 (s 2H OH) 1005 (s 2H
CHO) 823ndash819 (m 4H) 793 (d J = 22 Hz 2H) 773 (dd J =
76 and 12 Hz 2H) 755 (t J = 76 Hz 2H) 133 (s 18H tBu)
Compound L10 To a vigorously stirred solution of 12-
cyclohexanediamine (080 g 70 mmol) in dry CH2Cl2 (15 mL) at 0 oC
was added dropwise a solution of 35-di-tert-butylbenzaldehyde (109 g
467 mmol) in dry CH2Cl2 (10 mL) at 0 oC over 30 min The mixture
was then stirred at 0 oC for 3 h The resulting yellow solution was
evaporated under reduced pressure at 5 degC to give a pale yellow oil which was purified by
column chromatography (SiO2 ethyl acetate) to give the desired product as a pale yellow solid
Yield 052 g 34 1H NMR (400 MHz CDCl3) δ 1371 (s 1H OH) 843 (s 1H) 739 (d J =
24 Hz 1H) 710 (d J = 24 Hz 1H) 412 (q J = 71 Hz 2H) 293ndash274 (m 2H) 199ndash189 (m
2H) 183ndash171 (m 4H) 170ndash157 (m 2H) 145 (s 9H tBu) 130 (s 9H tBu)
Complex 2 Compound L4 (33 mg 0059 mmol
in powder form) and triethylamine (1 mL) were added
to a stirred solution of L9 (42 mg 013 mmol) and
Zn(OAc)2middot2H2O (28 mg 013 mmol) in MeOH (20 mL)
at room temperature The reaction mixture was stirred
at room temperature for 20 h to give a yellow
precipitate which was collected and washed copiously
with MeOH to afford 2 as a bright yellow solid Yield 64 mg 78 Anal Calcd for
C79H86N4O5Zn2(H2O)5 (139245) C 6814 H 695 N 402 Found C 6851 H 670 N 404
S6
1H NMR (300 MHz DMSO-d6) δ 897 (s 2H H11) 873 (s 2H H6) 784 (d J = 79 Hz 2H
H10) 753 (d J = 22 Hz 2H H1) 736 (d J = 85 Hz 2H H7) 732ndash719 (m 8H H5 H9 H12
H13) 718 (d J = 22 Hz 2H H2) 691 (dd J = 78 and 75 Hz 2H H8) 660 (d J = 13 Hz 2H
H3) 647 (dd J = 124 and 22 Hz 2H H4) 171 (s 6H H16) 145 (s 18H H14) 134 (s 18H
H17) 127 (s 18H H15) 13C NMR (101 MHz DMSO-d6) δ 1717 1703 1633 1615 1456
1451 1439 1407 1398 1392 1355 1334 1304 1296 1289 1284 1269 1265 1248
1232 1220 1183 1182 1163 1158 1155 352 348 343 336 315 314 297 ESI-MS
(+ve mode) mz 1304 [M + H]+
Complex 3 Compound L2 (025 g 045
mmol in powder form) was added to a stirred
solution of sodium methoxide (015 g 27
mmol) and zinc chloride (013 g 098 mmol)
in degassed EtOHCH2Cl2 (12 20 mL) at 0 degC
The mixture was stirred for 5 min after which
L10 (029 g 089 mmol) in EtOHCH2Cl2 (12
10 mL) was added The reaction mixture was stirred at room temperature for 12 h to give a pale
yellow suspension The filtrate was collected and all volatiles were removed under reduced
pressure to give a yellow solid which was purified by column chromatography (Et3N-saturated
SiO2 hexaneCH2Cl2 11) to afford 3 as a pale yellow solid Yield 013 g 21 Anal Calcd for
C79H98N4O5Zn2C6H14 (140064) C 7289 H 806 N 400 Found C 7269 H 782 N 377 1H NMR (300 MHz CD2Cl2) δ 765 (s 2H H13) 750 (d J = 22 Hz 2H H15) 749 (s 2H H6)
745 (dd J = 87 and 23 Hz 2H H4) 742 (d J = 23 Hz 2H H1) 731 (d J = 23 Hz 2H H3)
720 (d J = 23 Hz 2H H2) 694 (d J = 88 Hz 2H H5) 653 (d J = 23 Hz 2H H14) 379ndash
359 (m 4H H7 H12) 187ndash163 (m 8H H8 H11) 173 (s 6H H18) 150ndash128 (m 8H H10 H9)
147 (s 18H H17) 137 (s 18H H19) 132 (s 18H H16) 128ndash124 (m C6H14) 088 (t C6H14) 13C NMR (101 MHz CD2Cl2) δ 1737 1728 1702 1687 1459 1455 1417 1385 1382
1359 1314 1300 1298 1283 1267 1249 1237 1219 1178 1174 698 686 383 383
358 351 348 343 333 317 316 301 256 253 ESI-MS (+ve mode) mz 1316 [M + H]+
S7
Complex 4 The procedure for the synthesis
of 2 was adopted using L6 (50 mg 012 mmol) A
yellow precipitate was formed which was
collected and washed copiously with MeOH and
pentane to afford 4 as a yellow solid Yield 011 g
78 Anal Calcd for C68H64N4O5Zn2(H2O)3
(120213) C 6794 H 587 N 466 Found C
6787 H 596 N 445 1H NMR (400 MHz
DMSO-d6) δ 911 (s 2H H7) 893 (s 2H H12)
818 (d J = 22 Hz 2H H4) 809 (dd J = 24 and 26 Hz 2H H5) 805 (d J = 68 Hz 2H H1)
787 (d J = 86 Hz 2H H8) 784 (d J = 84 Hz 2H H11) 775 (d J = 75 Hz 2H H3) 750 (t J
= 76 Hz 2H H2) 737 (t J = 76 Hz 2H H9) 734 (d J = 25 Hz 2H H14) 730ndash722 (m 4H
H10 H13) 686 (d J = 89 Hz 2H H6) 149 (s 18H H16) 128 (s 18H H15) 13C NMR (101
MHz DMSO-d6) δ 1722 1707 1638 1623 1524 1410 1403 1391 1363 1345 1337
1299 1288 1278 1272 1254 1252 1246 1241 1240 1204 1199 1189 1184 1167
1163 354 338 316 299 ESI-MS (+ve mode) mz 1150 [M + H]+
Complex 5 Compound L3 (88 mg 013
mmol in powder form) and trimethylamine (1
mL) were added to a stirred solution of L8 (70
mg 026 mmol) and Zn(OAc)2middot2H2O (63 mg
029 mmol) in MeOH (20 mL) at room
temperature The reaction mixture was stirred
at 75 degC for 20 h to give a yellow precipitate
which was collected and washed copiously with cold MeOH to afford 5 as a bright yellow solid
Yield 80 mg 64 Anal Calcd for C79H86N4O5Zn2(CH3OH)2 (136646) C 7120 H 693 N
410 Found C 7130 H 674 N 413 1H NMR (400 MHz DMSO-d6) δ 838 (s 2H H10) 818
(s 2H H5) 752ndash735 (m 8H H4 H3 H6 H9) 739 (s 2H H1) 721 (s 2H H2) 707 (d J = 67
Hz 2H H13) 697 (dd J = 76 and 72 Hz 2H H7) 684 (d J = 72 Hz 2H H11) 676 (dd J =
80 and 72 Hz 2H H8) 638 (t J = 76 Hz 2H H12) 407 (br q J = 52 Hz CH3OH) 318 (d J
= 52 Hz CH3OH) 172 (s 6H H16) 137 (s 18H H17) 125 (s 18H H14) 123 (s 18H H15)
1
2
3
415
56
7 8
910
11
13
12
16
17
14
O
ON N
OZn
ON N
OZn
tBu
tBu
tBu
tBu
S8
13C NMR (101 MHz C6D6DMSO-d6 91) δ 1729 1722 1614 1612 1458 1448 1423
1420 1398 1396 1346 1329 1309 1300 1299 1261 1258 1257 1221 1199 1194
1192 1154 1151 1120 354 353 348 342 314 297 296 ESI-MS (+ve mode) mz
1304 [M + H]+
Complex 6 The procedure for the
synthesis of 5 was adopted using L3 (50 mg
0074 mmol) and L9 (48 mg 015 mmol) A
orange precipitate was formed which was
collected washed copiously with cold MeOH
and recrystallized from CH2Cl2hexane (19)
to afford 6 as a bright yellow solid Yield 46 mg 41 Anal Calcd for C87H102N4O5Zn2(H2O)5
(150466) C 6945 H 750 N 372 Found C 6977 H 736 N 389 1H NMR (400 MHz
DMSO-d6) δ 880 (s 2H H10) 852 (s 2H H5) 768 (d J = 80 Hz 2H H9) 763 (d J = 83 Hz
2H H6) 750 (d J = 23 Hz 2H H3) 745ndash739 (m 4H H1 H4) 720 (d J = 25 Hz 2H H12)
717 (d J = 23 Hz 2H H2) 719ndash712 (m 2H H7) 705 (d J = 26 Hz 2H H11) 707ndash699 (m
2H H8) 173 (s 6H H16) 136 (s 18H H17) 131 (s 18H H14) 124 (s 18H H13) 121 (s 18H
H15) 13C NMR (101 MHz DMSO-d6) δ 1721 1708 1626 1625 1452 1448 1412 1411
1399 1346 1332 1323 1298 1292 1285 1268 1267 1260 1260 1250 1218 1213
1196 1186 1165 1159 356 353 348 346 339 336 319 319 300 298 ESI-MS (+ve
mode) mz 1416 [M + H]+
Complex 7 and 7middotAcOH Compound L7 (60 mg
012 mmol in powder form) and Et3N (3 mL) were
added to a stirred solution of L8 (62 mg 023 mmol)
and Zn(OAc)2middot2H2O (56 mg 025 mmol) in MeOH
(20 mL) at room temperature The reaction mixture
was stirred at room temperature for 20 h to give a grey
solution All volatiles were removed under reduced
pressure and recrystallization from CH2Cl2hexane
(19) afforded a yellow crystalline solid which was characterized as 7middotAcOH Yield 98 mg
68 Anal Calcd for C68H64N4O5Zn2CH3CO2H (120813) C 6959 H 464 N 567 Found
S9
C 6999 H 464 N 599 1H NMR (400 MHz DMSO-d6) δ 871 (s 2H H11) 870 (s 2H H6)
832 (d J = 22 Hz 2H H4) 804 (dd J = 76 and 11 Hz 2H H1) 781ndash772 (m 4H H3 H5)
750 (t J = 76 Hz 2H H2) 743 (d J = 76 Hz 2H H10) 737 (d J = 81 Hz 2H H12) 732 (d
J = 79 Hz 2H H7) 727 (d J = 75 Hz 2H H14) 701 (t J = 77 Hz 2H H8) 662 (dd J = 79
and 75 Hz 2H H9) 650 (t J = 75 Hz 2H H13) 185 (s 3H H17) 161 (s 18H H16) 156 (s
18H H15) 13C NMR (151 MHz DMSO-d6) δ 1720 1719 1717 1616 1605 1522 1424
1414 1390 1377 1350 1345 1300 1299 1267 1264 1256 1244 1243 1236 1194
1188 1184 1181 1149 1146 1119 353 350 295 294 210
The yellow crystalline solid (7middotAcOH) was
dissolved in CH2Cl2 (15 mL) and washed with DI
water (20 mL times 3) The organic layer was collected
all volatiles were removed under reduced pressure
and recrystallization from acetonepentane (15)
afforded 7 as an orange solid Yield 62 mg 47
(based on L7) Anal Calcd for C68H64N4O5Zn2
(114808) C 7114 H 562 N 488 Found C 7116
H 579 N 473 1H NMR (400 MHz DMSO-d6) δ
870 (s 2H H11) 869 (s 2H H6) 832 (s 2H H4)
804 (dd J = 77 and 10 Hz 2H H1) 781ndash772 (m 4H H3 H5) 750 (t J = 76 Hz 2H H2)
743 (d J = 81 Hz 2H H10) 737 (d J = 68 Hz 2H H12) 732 (d J = 80 Hz 2H H7) 727 (d
J = 73 Hz 2H H14) 701 (dd J = 77 and 74 Hz 2H H8) 662 (t J = 75 Hz 2H H9) 650 (t J
= 75 Hz 2H H13) 161 (s 18H H16) 155 (s 18H H15) 13C NMR (101 MHz DMSO-d6) δ
1720 1717 1618 1606 1522 1425 1414 1390 1376 1352 1347 1301 1300 1268
1265 1256 1245 1243 1238 1195 1188 1185 1183 1150 1146 1120 354 352
296 295 ESI-MS (+ve mode) mz 1150 [M + H]+
S10
Complex 8 The procedure for the synthesis
of 4 was adopted using L7 (78 mg 015 mmol) A
brown precipitate was formed which was
collected and washed copiously with MeOH and
pentane to afford 8 as a brownish yellow solid
Yield 85 mg 43 Anal Calcd for
C76H80N4O5Zn2(H2O)4 (133235) C 6851 H
666 N 421 Found C 6840 H 688 N 429 1H NMR (400 MHz DMSO-d6) δ 883 (s 2H
H13) 882 (s 2H H20) 813 (d J = 22 Hz 2H H8) 805 (d J = 76 Hz 2H H2) 776 (d J = 23
Hz 2H H12) 771 (d J = 70 Hz 2H H4) 763 (d J = 78 Hz 2H H18) 754ndash745 (m 4H H315)
734 (d J = 25 Hz 2H H25) 724 (d J = 26 Hz 2H H23) 711 (dd J = 76 and 78 Hz 2H
H16) 689 (dd J = 78 and 80 Hz 2H H17) 152 (s 18H H32) 151 (s 18H H30) 132 (s 18H
H28) 13C NMR (151 MHz DMSO-d6 peak assignments based on combination of DEPT-135
and 2-D 1H-1H 13C-1H (HSQC and HMBC) and NOE correlation NMR experiments) δ 1719
(C10) 1702 (C21) 1621 (C20) 1612 (C13) 1523 (C6) 1422 (C11) 1407 (C26) 1392 (C19)
1382 (C14) 1346 (C8) 1331 (C24) 1301 (C12) 1294 (C23) 1281 (C25) 1266 (C17) 1265
(C16) 1258 (C5) 1250 (C4) 1243 (C1) 1236 (C3) 1190 (C9) 1188 (C7) 1181 (C2) 1180
(C22) 1152 (C18) 1151 (C15) 352 (C2931) 335 (C27) 313 (C28) 296 (C30) 294 (C32) ESI-
MS (+ve mode) mz 1264 [M + H]+
S11
Figure S1 1H NMR (400 MHz CDCl3 298 K inset expanded) spectrum of reaction mixture corresponding to Run 10 in Table 3 [reaction conditions 12-epoxybutane (575 mmol 5 mL) catalyst 8 (00025 mol) nBu4NI co-cat (0125 mol) mesitylene (internal standard 1 mol) 10 bar CO2 initial pressure 95 degC 2 h]
Hf
Hc
Hd Hdrsquo
Hcrsquo ampnBu4NI
Ha
Hb1
Hb2
Harsquo
Hbrsquo1
Hbrsquo2
CDCl3
He
S12
Figure S2 1H NMR (400 MHz CDCl3 298 K inset expanded) spectrum of reaction mixture corresponding to Run 12 in Table 3 [reaction conditions 12-epoxyhexane (249 mmol 3 mL) catalyst 8 (00025 mol) nBu4NI co-cat (0125 mol) mesitylene (internal standard 1 mol) 10 bar CO2 initial pressure 95 degC 2 h]
nBu4NI Hf
Hd Hdrsquo
Ha
Hb1
Hb2 Harsquo
Hbrsquo1
Hbrsquo2
CDCl3
He
Hc Hcrsquo
S13
ESI References
1 R Okamura T Wada K Aikawa T Nagata and K Tanaka Inorg Chem 2004 43 7210
2 W-L Tong S-M Yiu and M C W Chan Inorg Chem 2013 52 7114
3 M Hirotsu N Ohno T Nakajima C Kushibe K Ueno and I Kinoshita Dalton Trans 2010 39 139
4 E B Schwartz C B Knobler and D J Cram J Am Chem Soc 1992 114 10775
5 Z Guo S-M Yiu and M C W Chan Chem Eur J 2013 19 8937
S2
Experimental Section
General Considerations and Instrumentation Propylene oxide epoxybutane and 12-
epoxyhexane (Sigma-Aldrich) were distilled from CaH2 and 2-butanone (MEK methyl ethyl
ketone) was distilled from K2CO3 and all were stored over 4 Aring molecular sieves Carbon dioxide
(research grade 99999) was purchased from HK Scientific Gas Engineering Co Ltd and
used as received Mesitylene was dried over 4 Aring molecular sieves Tetrabutylammonium iodide
(Acros) was recrystallized using dry acetone and diethyl ether (110) and dried in a vacuum
oven at 90 oC for 48 h All reactions that describe the use of dry solvents were performed under a
nitrogen atmosphere and the solvents were appropriately dried and distilled prior to use for the
remaining reactions solvents (analytical grade) were used without further purification 1H and 13C NMR spectra were recorded at 298 K on Bruker Avance III 300 400 and 600 MHz NMR
spectrometers (ppm referenced to residual solvent peaks) ESI mass spectra were measured on a
Perkin-Elmer SCIEX API 365 mass spectrometer Elemental analyses were performed on a
Vario EL elemental analyzer (Elementar Analysensysteme GmbH) The synthesis of L112 L223
L545 L82 L92 and complex 12 were described previously
General Procedure for CO2 Reactions CO2 reactions were performed using a Teflon liner
in a 100-mL Parr stainless steel high-pressure reactor equipped with a paddle-like stirrer The
epoxide (in MEK [5 mL] or neat [epoxypropane and -hexane 3 mL epoxybutane 5 mL])
catalyst nBu4NI cocatalyst and mesitylene (internal standard) were introduced into the reactor
which was then subjected to three cycles of pressurization and depressurization with CO2 (at half
of reacting pressure) before final stabilization at the chosen reacting pressure The reactor was
sealed heated to the required temperature and stirred at 500 rpm for the prescribed time The
reactor was then cooled to 10 degC using ice water and the remaining pressure was slowly vented
An aliquot (60 microL) of the reaction mixture combined with CDCl3 (440 microL) was taken for 1H
NMR analysis (90deg flip angle 30 seconds relaxation delay) The conversion which was
reproducible within plusmn2 in at least 3 independent runs for selected experiments was calculated
from the 1H NMR integration of the cyclic carbonate product against the mesitylene internal
standard
S3
Synthetic Methods
R2
O
CHOOH
Zn(OAc)2 NEt3MeOH
H2N N
HO R2
tBuR2 = H (L8)R2 = tBu (L9)
B
O
B
OH
OH
OH
OH
(L1)
R2
O
ON N
OZn
ON N
OZn
tBu
tBu
Pd(PPh3)4 K2CO3
Br OH
CHO
2 dil HCl (aq)
R11
DMEH2O
R1
CHOOH
R1
R1 = H (L2) tBu (L3)
R1
R1
R1 = H R2 = tBu (1)R1 = tBu R2 = H (5)R1 = R2 = tBu (6)
I CHO
OH
1O
OHCHO
OHCHO
O
NN
OO Zn
tBu
tBuN
NO
O Zn
tButBu
(2)
Zn(OAc)2 NEt3MeOH
H2N N
HO tButBu(L9)
(L4)
tBu
tBu
O
ON N
OZn
ON N
OZn
tBu
tBu
(3)
ZnCl2 NaOMeEtOHCH2Cl2
H2N N
HO tButBu(L10)
Pd(PPh3)4 K2CO3
2 dil HCl (aq)DMEH2O
R1 = H
Zn(OAc)2 NEt3MeOH
H2N N
HO R2
tBuO
B(OH)2
B(OH)2Pd(PPh3)4
K2CO3
Br OH
CHO
2 dil HCl (aq)
O
OHCHO
R1
OH
CHO
R1
R11
R1 = H tBuR2 = tBuMeOH(wash)
O
R2
ON
NOZn
tBu
R1
R2
ON
NO
Zn
tBuR1
H2O(wash)
R1 = tBuR2 = H
[7 AcOH]
DMEH2O
R1 = H R2 = tBu (4)R1 = tBu R2 = H (7)R1 = R2 = tBu (8)
(L5)
R1 = H (L6) tBu (L7)
R2 = H (L8)R2 = tBu (L9)
Scheme S1 Synthesis of complexes 1ndash8
S4
Compound L3 L1 (082 g 20 mmol) 2-hydroxy-3-tert-
butyl-5-bromobenzaldehyde (122 g 476 mmol) and Pd(PPh3)4
(005 g 004 mmol) were suspended in a deoxygenated solution of
K2CO3 (122 g 880 mmol) in DMEDI water (31 40 mL) The
reaction mixture which became a clear orange solution upon
heating was then stirred under reflux for 3 h during which the
color of the solution became dark brown The mixture was cooled to 0 degC after which 1 M
aqueous HCl (20 mL) was added and the mixture was stirred at room temperature for 1 h Water
(100 mL) and chloroform (200 mL) were added to the resulting orange suspension After stirring
at room temperature for 1 h the organic layer was separated and washed with water The
resultant orange solution was dried over MgSO4 filtered and concentrated to dryness The crude
product was further purified by column chromatography (SiO2 hexaneCH2Cl2 11) to give the
desired product as a yellow solid Yield 092 g 68 1H NMR (300 MHz DMSO-d6) δ 1171 (s
2H OH) 947 (s 2H CHO) 760ndash743 (m 6H) 719 (d J = 22 Hz 2H) 173 (s 6H CH3)
134 (s 18H tBu) 120 (s 18H tBu) Compound L4 The procedure for the synthesis of L3 was
adopted using L1 (070 g 17 mmol) and 2-hydroxy-4-
iodobenzaldehyde (10 g 40 mmol) The crude product was
purified by column chromatography (SiO2 hexaneCH2Cl2 12) to
give the desired product as a pale yellow solid Yield 051 g 53 1H NMR (300 MHz DMSO-d6) δ 1014 (s 2H CHO) 756 (d J =
23 Hz 2H) 732 (d J = 80 Hz 2H) 716 (d J = 23 Hz 2H) 684
(d J = 12 Hz 2H) 676 (d J = 80 Hz 2H) 170 (s 6H CH3) 132 (s 18H tBu)
Compound L6 The procedure for the synthesis of L3
was adopted using L5 (200 g 782 mmol) and 2-hydroxy-5-
bromobenzaldehyde (346 g 172 mmol) The crude product
was purified by column chromatography (SiO2 CH2Cl2) to
give the desired product as a pale yellow solid Yield 24 g
75 1H NMR (300 MHz DMSO-d6) δ 1102 (s 2H OH)
S5
1036 (s 2H CHO) 830 (s 2H) 824ndash807 (m 4H) 773 (d J = 76 Hz 2H) 749 (dd J = 78
and 75 Hz 2H) 720 (d J = 86 Hz 2H)
Compound L7 The procedure for the synthesis of L3 was
adopted using L5 (080 g 31 mmol) The crude product was
purified by flash chromatography (SiO2 CH2Cl2hexane 11) to
give the desired product as a yellow powder Yield 12 g 74 1H NMR (400 MHz DMSO-d6) δ 1189 (s 2H OH) 1005 (s 2H
CHO) 823ndash819 (m 4H) 793 (d J = 22 Hz 2H) 773 (dd J =
76 and 12 Hz 2H) 755 (t J = 76 Hz 2H) 133 (s 18H tBu)
Compound L10 To a vigorously stirred solution of 12-
cyclohexanediamine (080 g 70 mmol) in dry CH2Cl2 (15 mL) at 0 oC
was added dropwise a solution of 35-di-tert-butylbenzaldehyde (109 g
467 mmol) in dry CH2Cl2 (10 mL) at 0 oC over 30 min The mixture
was then stirred at 0 oC for 3 h The resulting yellow solution was
evaporated under reduced pressure at 5 degC to give a pale yellow oil which was purified by
column chromatography (SiO2 ethyl acetate) to give the desired product as a pale yellow solid
Yield 052 g 34 1H NMR (400 MHz CDCl3) δ 1371 (s 1H OH) 843 (s 1H) 739 (d J =
24 Hz 1H) 710 (d J = 24 Hz 1H) 412 (q J = 71 Hz 2H) 293ndash274 (m 2H) 199ndash189 (m
2H) 183ndash171 (m 4H) 170ndash157 (m 2H) 145 (s 9H tBu) 130 (s 9H tBu)
Complex 2 Compound L4 (33 mg 0059 mmol
in powder form) and triethylamine (1 mL) were added
to a stirred solution of L9 (42 mg 013 mmol) and
Zn(OAc)2middot2H2O (28 mg 013 mmol) in MeOH (20 mL)
at room temperature The reaction mixture was stirred
at room temperature for 20 h to give a yellow
precipitate which was collected and washed copiously
with MeOH to afford 2 as a bright yellow solid Yield 64 mg 78 Anal Calcd for
C79H86N4O5Zn2(H2O)5 (139245) C 6814 H 695 N 402 Found C 6851 H 670 N 404
S6
1H NMR (300 MHz DMSO-d6) δ 897 (s 2H H11) 873 (s 2H H6) 784 (d J = 79 Hz 2H
H10) 753 (d J = 22 Hz 2H H1) 736 (d J = 85 Hz 2H H7) 732ndash719 (m 8H H5 H9 H12
H13) 718 (d J = 22 Hz 2H H2) 691 (dd J = 78 and 75 Hz 2H H8) 660 (d J = 13 Hz 2H
H3) 647 (dd J = 124 and 22 Hz 2H H4) 171 (s 6H H16) 145 (s 18H H14) 134 (s 18H
H17) 127 (s 18H H15) 13C NMR (101 MHz DMSO-d6) δ 1717 1703 1633 1615 1456
1451 1439 1407 1398 1392 1355 1334 1304 1296 1289 1284 1269 1265 1248
1232 1220 1183 1182 1163 1158 1155 352 348 343 336 315 314 297 ESI-MS
(+ve mode) mz 1304 [M + H]+
Complex 3 Compound L2 (025 g 045
mmol in powder form) was added to a stirred
solution of sodium methoxide (015 g 27
mmol) and zinc chloride (013 g 098 mmol)
in degassed EtOHCH2Cl2 (12 20 mL) at 0 degC
The mixture was stirred for 5 min after which
L10 (029 g 089 mmol) in EtOHCH2Cl2 (12
10 mL) was added The reaction mixture was stirred at room temperature for 12 h to give a pale
yellow suspension The filtrate was collected and all volatiles were removed under reduced
pressure to give a yellow solid which was purified by column chromatography (Et3N-saturated
SiO2 hexaneCH2Cl2 11) to afford 3 as a pale yellow solid Yield 013 g 21 Anal Calcd for
C79H98N4O5Zn2C6H14 (140064) C 7289 H 806 N 400 Found C 7269 H 782 N 377 1H NMR (300 MHz CD2Cl2) δ 765 (s 2H H13) 750 (d J = 22 Hz 2H H15) 749 (s 2H H6)
745 (dd J = 87 and 23 Hz 2H H4) 742 (d J = 23 Hz 2H H1) 731 (d J = 23 Hz 2H H3)
720 (d J = 23 Hz 2H H2) 694 (d J = 88 Hz 2H H5) 653 (d J = 23 Hz 2H H14) 379ndash
359 (m 4H H7 H12) 187ndash163 (m 8H H8 H11) 173 (s 6H H18) 150ndash128 (m 8H H10 H9)
147 (s 18H H17) 137 (s 18H H19) 132 (s 18H H16) 128ndash124 (m C6H14) 088 (t C6H14) 13C NMR (101 MHz CD2Cl2) δ 1737 1728 1702 1687 1459 1455 1417 1385 1382
1359 1314 1300 1298 1283 1267 1249 1237 1219 1178 1174 698 686 383 383
358 351 348 343 333 317 316 301 256 253 ESI-MS (+ve mode) mz 1316 [M + H]+
S7
Complex 4 The procedure for the synthesis
of 2 was adopted using L6 (50 mg 012 mmol) A
yellow precipitate was formed which was
collected and washed copiously with MeOH and
pentane to afford 4 as a yellow solid Yield 011 g
78 Anal Calcd for C68H64N4O5Zn2(H2O)3
(120213) C 6794 H 587 N 466 Found C
6787 H 596 N 445 1H NMR (400 MHz
DMSO-d6) δ 911 (s 2H H7) 893 (s 2H H12)
818 (d J = 22 Hz 2H H4) 809 (dd J = 24 and 26 Hz 2H H5) 805 (d J = 68 Hz 2H H1)
787 (d J = 86 Hz 2H H8) 784 (d J = 84 Hz 2H H11) 775 (d J = 75 Hz 2H H3) 750 (t J
= 76 Hz 2H H2) 737 (t J = 76 Hz 2H H9) 734 (d J = 25 Hz 2H H14) 730ndash722 (m 4H
H10 H13) 686 (d J = 89 Hz 2H H6) 149 (s 18H H16) 128 (s 18H H15) 13C NMR (101
MHz DMSO-d6) δ 1722 1707 1638 1623 1524 1410 1403 1391 1363 1345 1337
1299 1288 1278 1272 1254 1252 1246 1241 1240 1204 1199 1189 1184 1167
1163 354 338 316 299 ESI-MS (+ve mode) mz 1150 [M + H]+
Complex 5 Compound L3 (88 mg 013
mmol in powder form) and trimethylamine (1
mL) were added to a stirred solution of L8 (70
mg 026 mmol) and Zn(OAc)2middot2H2O (63 mg
029 mmol) in MeOH (20 mL) at room
temperature The reaction mixture was stirred
at 75 degC for 20 h to give a yellow precipitate
which was collected and washed copiously with cold MeOH to afford 5 as a bright yellow solid
Yield 80 mg 64 Anal Calcd for C79H86N4O5Zn2(CH3OH)2 (136646) C 7120 H 693 N
410 Found C 7130 H 674 N 413 1H NMR (400 MHz DMSO-d6) δ 838 (s 2H H10) 818
(s 2H H5) 752ndash735 (m 8H H4 H3 H6 H9) 739 (s 2H H1) 721 (s 2H H2) 707 (d J = 67
Hz 2H H13) 697 (dd J = 76 and 72 Hz 2H H7) 684 (d J = 72 Hz 2H H11) 676 (dd J =
80 and 72 Hz 2H H8) 638 (t J = 76 Hz 2H H12) 407 (br q J = 52 Hz CH3OH) 318 (d J
= 52 Hz CH3OH) 172 (s 6H H16) 137 (s 18H H17) 125 (s 18H H14) 123 (s 18H H15)
1
2
3
415
56
7 8
910
11
13
12
16
17
14
O
ON N
OZn
ON N
OZn
tBu
tBu
tBu
tBu
S8
13C NMR (101 MHz C6D6DMSO-d6 91) δ 1729 1722 1614 1612 1458 1448 1423
1420 1398 1396 1346 1329 1309 1300 1299 1261 1258 1257 1221 1199 1194
1192 1154 1151 1120 354 353 348 342 314 297 296 ESI-MS (+ve mode) mz
1304 [M + H]+
Complex 6 The procedure for the
synthesis of 5 was adopted using L3 (50 mg
0074 mmol) and L9 (48 mg 015 mmol) A
orange precipitate was formed which was
collected washed copiously with cold MeOH
and recrystallized from CH2Cl2hexane (19)
to afford 6 as a bright yellow solid Yield 46 mg 41 Anal Calcd for C87H102N4O5Zn2(H2O)5
(150466) C 6945 H 750 N 372 Found C 6977 H 736 N 389 1H NMR (400 MHz
DMSO-d6) δ 880 (s 2H H10) 852 (s 2H H5) 768 (d J = 80 Hz 2H H9) 763 (d J = 83 Hz
2H H6) 750 (d J = 23 Hz 2H H3) 745ndash739 (m 4H H1 H4) 720 (d J = 25 Hz 2H H12)
717 (d J = 23 Hz 2H H2) 719ndash712 (m 2H H7) 705 (d J = 26 Hz 2H H11) 707ndash699 (m
2H H8) 173 (s 6H H16) 136 (s 18H H17) 131 (s 18H H14) 124 (s 18H H13) 121 (s 18H
H15) 13C NMR (101 MHz DMSO-d6) δ 1721 1708 1626 1625 1452 1448 1412 1411
1399 1346 1332 1323 1298 1292 1285 1268 1267 1260 1260 1250 1218 1213
1196 1186 1165 1159 356 353 348 346 339 336 319 319 300 298 ESI-MS (+ve
mode) mz 1416 [M + H]+
Complex 7 and 7middotAcOH Compound L7 (60 mg
012 mmol in powder form) and Et3N (3 mL) were
added to a stirred solution of L8 (62 mg 023 mmol)
and Zn(OAc)2middot2H2O (56 mg 025 mmol) in MeOH
(20 mL) at room temperature The reaction mixture
was stirred at room temperature for 20 h to give a grey
solution All volatiles were removed under reduced
pressure and recrystallization from CH2Cl2hexane
(19) afforded a yellow crystalline solid which was characterized as 7middotAcOH Yield 98 mg
68 Anal Calcd for C68H64N4O5Zn2CH3CO2H (120813) C 6959 H 464 N 567 Found
S9
C 6999 H 464 N 599 1H NMR (400 MHz DMSO-d6) δ 871 (s 2H H11) 870 (s 2H H6)
832 (d J = 22 Hz 2H H4) 804 (dd J = 76 and 11 Hz 2H H1) 781ndash772 (m 4H H3 H5)
750 (t J = 76 Hz 2H H2) 743 (d J = 76 Hz 2H H10) 737 (d J = 81 Hz 2H H12) 732 (d
J = 79 Hz 2H H7) 727 (d J = 75 Hz 2H H14) 701 (t J = 77 Hz 2H H8) 662 (dd J = 79
and 75 Hz 2H H9) 650 (t J = 75 Hz 2H H13) 185 (s 3H H17) 161 (s 18H H16) 156 (s
18H H15) 13C NMR (151 MHz DMSO-d6) δ 1720 1719 1717 1616 1605 1522 1424
1414 1390 1377 1350 1345 1300 1299 1267 1264 1256 1244 1243 1236 1194
1188 1184 1181 1149 1146 1119 353 350 295 294 210
The yellow crystalline solid (7middotAcOH) was
dissolved in CH2Cl2 (15 mL) and washed with DI
water (20 mL times 3) The organic layer was collected
all volatiles were removed under reduced pressure
and recrystallization from acetonepentane (15)
afforded 7 as an orange solid Yield 62 mg 47
(based on L7) Anal Calcd for C68H64N4O5Zn2
(114808) C 7114 H 562 N 488 Found C 7116
H 579 N 473 1H NMR (400 MHz DMSO-d6) δ
870 (s 2H H11) 869 (s 2H H6) 832 (s 2H H4)
804 (dd J = 77 and 10 Hz 2H H1) 781ndash772 (m 4H H3 H5) 750 (t J = 76 Hz 2H H2)
743 (d J = 81 Hz 2H H10) 737 (d J = 68 Hz 2H H12) 732 (d J = 80 Hz 2H H7) 727 (d
J = 73 Hz 2H H14) 701 (dd J = 77 and 74 Hz 2H H8) 662 (t J = 75 Hz 2H H9) 650 (t J
= 75 Hz 2H H13) 161 (s 18H H16) 155 (s 18H H15) 13C NMR (101 MHz DMSO-d6) δ
1720 1717 1618 1606 1522 1425 1414 1390 1376 1352 1347 1301 1300 1268
1265 1256 1245 1243 1238 1195 1188 1185 1183 1150 1146 1120 354 352
296 295 ESI-MS (+ve mode) mz 1150 [M + H]+
S10
Complex 8 The procedure for the synthesis
of 4 was adopted using L7 (78 mg 015 mmol) A
brown precipitate was formed which was
collected and washed copiously with MeOH and
pentane to afford 8 as a brownish yellow solid
Yield 85 mg 43 Anal Calcd for
C76H80N4O5Zn2(H2O)4 (133235) C 6851 H
666 N 421 Found C 6840 H 688 N 429 1H NMR (400 MHz DMSO-d6) δ 883 (s 2H
H13) 882 (s 2H H20) 813 (d J = 22 Hz 2H H8) 805 (d J = 76 Hz 2H H2) 776 (d J = 23
Hz 2H H12) 771 (d J = 70 Hz 2H H4) 763 (d J = 78 Hz 2H H18) 754ndash745 (m 4H H315)
734 (d J = 25 Hz 2H H25) 724 (d J = 26 Hz 2H H23) 711 (dd J = 76 and 78 Hz 2H
H16) 689 (dd J = 78 and 80 Hz 2H H17) 152 (s 18H H32) 151 (s 18H H30) 132 (s 18H
H28) 13C NMR (151 MHz DMSO-d6 peak assignments based on combination of DEPT-135
and 2-D 1H-1H 13C-1H (HSQC and HMBC) and NOE correlation NMR experiments) δ 1719
(C10) 1702 (C21) 1621 (C20) 1612 (C13) 1523 (C6) 1422 (C11) 1407 (C26) 1392 (C19)
1382 (C14) 1346 (C8) 1331 (C24) 1301 (C12) 1294 (C23) 1281 (C25) 1266 (C17) 1265
(C16) 1258 (C5) 1250 (C4) 1243 (C1) 1236 (C3) 1190 (C9) 1188 (C7) 1181 (C2) 1180
(C22) 1152 (C18) 1151 (C15) 352 (C2931) 335 (C27) 313 (C28) 296 (C30) 294 (C32) ESI-
MS (+ve mode) mz 1264 [M + H]+
S11
Figure S1 1H NMR (400 MHz CDCl3 298 K inset expanded) spectrum of reaction mixture corresponding to Run 10 in Table 3 [reaction conditions 12-epoxybutane (575 mmol 5 mL) catalyst 8 (00025 mol) nBu4NI co-cat (0125 mol) mesitylene (internal standard 1 mol) 10 bar CO2 initial pressure 95 degC 2 h]
Hf
Hc
Hd Hdrsquo
Hcrsquo ampnBu4NI
Ha
Hb1
Hb2
Harsquo
Hbrsquo1
Hbrsquo2
CDCl3
He
S12
Figure S2 1H NMR (400 MHz CDCl3 298 K inset expanded) spectrum of reaction mixture corresponding to Run 12 in Table 3 [reaction conditions 12-epoxyhexane (249 mmol 3 mL) catalyst 8 (00025 mol) nBu4NI co-cat (0125 mol) mesitylene (internal standard 1 mol) 10 bar CO2 initial pressure 95 degC 2 h]
nBu4NI Hf
Hd Hdrsquo
Ha
Hb1
Hb2 Harsquo
Hbrsquo1
Hbrsquo2
CDCl3
He
Hc Hcrsquo
S13
ESI References
1 R Okamura T Wada K Aikawa T Nagata and K Tanaka Inorg Chem 2004 43 7210
2 W-L Tong S-M Yiu and M C W Chan Inorg Chem 2013 52 7114
3 M Hirotsu N Ohno T Nakajima C Kushibe K Ueno and I Kinoshita Dalton Trans 2010 39 139
4 E B Schwartz C B Knobler and D J Cram J Am Chem Soc 1992 114 10775
5 Z Guo S-M Yiu and M C W Chan Chem Eur J 2013 19 8937
S3
Synthetic Methods
R2
O
CHOOH
Zn(OAc)2 NEt3MeOH
H2N N
HO R2
tBuR2 = H (L8)R2 = tBu (L9)
B
O
B
OH
OH
OH
OH
(L1)
R2
O
ON N
OZn
ON N
OZn
tBu
tBu
Pd(PPh3)4 K2CO3
Br OH
CHO
2 dil HCl (aq)
R11
DMEH2O
R1
CHOOH
R1
R1 = H (L2) tBu (L3)
R1
R1
R1 = H R2 = tBu (1)R1 = tBu R2 = H (5)R1 = R2 = tBu (6)
I CHO
OH
1O
OHCHO
OHCHO
O
NN
OO Zn
tBu
tBuN
NO
O Zn
tButBu
(2)
Zn(OAc)2 NEt3MeOH
H2N N
HO tButBu(L9)
(L4)
tBu
tBu
O
ON N
OZn
ON N
OZn
tBu
tBu
(3)
ZnCl2 NaOMeEtOHCH2Cl2
H2N N
HO tButBu(L10)
Pd(PPh3)4 K2CO3
2 dil HCl (aq)DMEH2O
R1 = H
Zn(OAc)2 NEt3MeOH
H2N N
HO R2
tBuO
B(OH)2
B(OH)2Pd(PPh3)4
K2CO3
Br OH
CHO
2 dil HCl (aq)
O
OHCHO
R1
OH
CHO
R1
R11
R1 = H tBuR2 = tBuMeOH(wash)
O
R2
ON
NOZn
tBu
R1
R2
ON
NO
Zn
tBuR1
H2O(wash)
R1 = tBuR2 = H
[7 AcOH]
DMEH2O
R1 = H R2 = tBu (4)R1 = tBu R2 = H (7)R1 = R2 = tBu (8)
(L5)
R1 = H (L6) tBu (L7)
R2 = H (L8)R2 = tBu (L9)
Scheme S1 Synthesis of complexes 1ndash8
S4
Compound L3 L1 (082 g 20 mmol) 2-hydroxy-3-tert-
butyl-5-bromobenzaldehyde (122 g 476 mmol) and Pd(PPh3)4
(005 g 004 mmol) were suspended in a deoxygenated solution of
K2CO3 (122 g 880 mmol) in DMEDI water (31 40 mL) The
reaction mixture which became a clear orange solution upon
heating was then stirred under reflux for 3 h during which the
color of the solution became dark brown The mixture was cooled to 0 degC after which 1 M
aqueous HCl (20 mL) was added and the mixture was stirred at room temperature for 1 h Water
(100 mL) and chloroform (200 mL) were added to the resulting orange suspension After stirring
at room temperature for 1 h the organic layer was separated and washed with water The
resultant orange solution was dried over MgSO4 filtered and concentrated to dryness The crude
product was further purified by column chromatography (SiO2 hexaneCH2Cl2 11) to give the
desired product as a yellow solid Yield 092 g 68 1H NMR (300 MHz DMSO-d6) δ 1171 (s
2H OH) 947 (s 2H CHO) 760ndash743 (m 6H) 719 (d J = 22 Hz 2H) 173 (s 6H CH3)
134 (s 18H tBu) 120 (s 18H tBu) Compound L4 The procedure for the synthesis of L3 was
adopted using L1 (070 g 17 mmol) and 2-hydroxy-4-
iodobenzaldehyde (10 g 40 mmol) The crude product was
purified by column chromatography (SiO2 hexaneCH2Cl2 12) to
give the desired product as a pale yellow solid Yield 051 g 53 1H NMR (300 MHz DMSO-d6) δ 1014 (s 2H CHO) 756 (d J =
23 Hz 2H) 732 (d J = 80 Hz 2H) 716 (d J = 23 Hz 2H) 684
(d J = 12 Hz 2H) 676 (d J = 80 Hz 2H) 170 (s 6H CH3) 132 (s 18H tBu)
Compound L6 The procedure for the synthesis of L3
was adopted using L5 (200 g 782 mmol) and 2-hydroxy-5-
bromobenzaldehyde (346 g 172 mmol) The crude product
was purified by column chromatography (SiO2 CH2Cl2) to
give the desired product as a pale yellow solid Yield 24 g
75 1H NMR (300 MHz DMSO-d6) δ 1102 (s 2H OH)
S5
1036 (s 2H CHO) 830 (s 2H) 824ndash807 (m 4H) 773 (d J = 76 Hz 2H) 749 (dd J = 78
and 75 Hz 2H) 720 (d J = 86 Hz 2H)
Compound L7 The procedure for the synthesis of L3 was
adopted using L5 (080 g 31 mmol) The crude product was
purified by flash chromatography (SiO2 CH2Cl2hexane 11) to
give the desired product as a yellow powder Yield 12 g 74 1H NMR (400 MHz DMSO-d6) δ 1189 (s 2H OH) 1005 (s 2H
CHO) 823ndash819 (m 4H) 793 (d J = 22 Hz 2H) 773 (dd J =
76 and 12 Hz 2H) 755 (t J = 76 Hz 2H) 133 (s 18H tBu)
Compound L10 To a vigorously stirred solution of 12-
cyclohexanediamine (080 g 70 mmol) in dry CH2Cl2 (15 mL) at 0 oC
was added dropwise a solution of 35-di-tert-butylbenzaldehyde (109 g
467 mmol) in dry CH2Cl2 (10 mL) at 0 oC over 30 min The mixture
was then stirred at 0 oC for 3 h The resulting yellow solution was
evaporated under reduced pressure at 5 degC to give a pale yellow oil which was purified by
column chromatography (SiO2 ethyl acetate) to give the desired product as a pale yellow solid
Yield 052 g 34 1H NMR (400 MHz CDCl3) δ 1371 (s 1H OH) 843 (s 1H) 739 (d J =
24 Hz 1H) 710 (d J = 24 Hz 1H) 412 (q J = 71 Hz 2H) 293ndash274 (m 2H) 199ndash189 (m
2H) 183ndash171 (m 4H) 170ndash157 (m 2H) 145 (s 9H tBu) 130 (s 9H tBu)
Complex 2 Compound L4 (33 mg 0059 mmol
in powder form) and triethylamine (1 mL) were added
to a stirred solution of L9 (42 mg 013 mmol) and
Zn(OAc)2middot2H2O (28 mg 013 mmol) in MeOH (20 mL)
at room temperature The reaction mixture was stirred
at room temperature for 20 h to give a yellow
precipitate which was collected and washed copiously
with MeOH to afford 2 as a bright yellow solid Yield 64 mg 78 Anal Calcd for
C79H86N4O5Zn2(H2O)5 (139245) C 6814 H 695 N 402 Found C 6851 H 670 N 404
S6
1H NMR (300 MHz DMSO-d6) δ 897 (s 2H H11) 873 (s 2H H6) 784 (d J = 79 Hz 2H
H10) 753 (d J = 22 Hz 2H H1) 736 (d J = 85 Hz 2H H7) 732ndash719 (m 8H H5 H9 H12
H13) 718 (d J = 22 Hz 2H H2) 691 (dd J = 78 and 75 Hz 2H H8) 660 (d J = 13 Hz 2H
H3) 647 (dd J = 124 and 22 Hz 2H H4) 171 (s 6H H16) 145 (s 18H H14) 134 (s 18H
H17) 127 (s 18H H15) 13C NMR (101 MHz DMSO-d6) δ 1717 1703 1633 1615 1456
1451 1439 1407 1398 1392 1355 1334 1304 1296 1289 1284 1269 1265 1248
1232 1220 1183 1182 1163 1158 1155 352 348 343 336 315 314 297 ESI-MS
(+ve mode) mz 1304 [M + H]+
Complex 3 Compound L2 (025 g 045
mmol in powder form) was added to a stirred
solution of sodium methoxide (015 g 27
mmol) and zinc chloride (013 g 098 mmol)
in degassed EtOHCH2Cl2 (12 20 mL) at 0 degC
The mixture was stirred for 5 min after which
L10 (029 g 089 mmol) in EtOHCH2Cl2 (12
10 mL) was added The reaction mixture was stirred at room temperature for 12 h to give a pale
yellow suspension The filtrate was collected and all volatiles were removed under reduced
pressure to give a yellow solid which was purified by column chromatography (Et3N-saturated
SiO2 hexaneCH2Cl2 11) to afford 3 as a pale yellow solid Yield 013 g 21 Anal Calcd for
C79H98N4O5Zn2C6H14 (140064) C 7289 H 806 N 400 Found C 7269 H 782 N 377 1H NMR (300 MHz CD2Cl2) δ 765 (s 2H H13) 750 (d J = 22 Hz 2H H15) 749 (s 2H H6)
745 (dd J = 87 and 23 Hz 2H H4) 742 (d J = 23 Hz 2H H1) 731 (d J = 23 Hz 2H H3)
720 (d J = 23 Hz 2H H2) 694 (d J = 88 Hz 2H H5) 653 (d J = 23 Hz 2H H14) 379ndash
359 (m 4H H7 H12) 187ndash163 (m 8H H8 H11) 173 (s 6H H18) 150ndash128 (m 8H H10 H9)
147 (s 18H H17) 137 (s 18H H19) 132 (s 18H H16) 128ndash124 (m C6H14) 088 (t C6H14) 13C NMR (101 MHz CD2Cl2) δ 1737 1728 1702 1687 1459 1455 1417 1385 1382
1359 1314 1300 1298 1283 1267 1249 1237 1219 1178 1174 698 686 383 383
358 351 348 343 333 317 316 301 256 253 ESI-MS (+ve mode) mz 1316 [M + H]+
S7
Complex 4 The procedure for the synthesis
of 2 was adopted using L6 (50 mg 012 mmol) A
yellow precipitate was formed which was
collected and washed copiously with MeOH and
pentane to afford 4 as a yellow solid Yield 011 g
78 Anal Calcd for C68H64N4O5Zn2(H2O)3
(120213) C 6794 H 587 N 466 Found C
6787 H 596 N 445 1H NMR (400 MHz
DMSO-d6) δ 911 (s 2H H7) 893 (s 2H H12)
818 (d J = 22 Hz 2H H4) 809 (dd J = 24 and 26 Hz 2H H5) 805 (d J = 68 Hz 2H H1)
787 (d J = 86 Hz 2H H8) 784 (d J = 84 Hz 2H H11) 775 (d J = 75 Hz 2H H3) 750 (t J
= 76 Hz 2H H2) 737 (t J = 76 Hz 2H H9) 734 (d J = 25 Hz 2H H14) 730ndash722 (m 4H
H10 H13) 686 (d J = 89 Hz 2H H6) 149 (s 18H H16) 128 (s 18H H15) 13C NMR (101
MHz DMSO-d6) δ 1722 1707 1638 1623 1524 1410 1403 1391 1363 1345 1337
1299 1288 1278 1272 1254 1252 1246 1241 1240 1204 1199 1189 1184 1167
1163 354 338 316 299 ESI-MS (+ve mode) mz 1150 [M + H]+
Complex 5 Compound L3 (88 mg 013
mmol in powder form) and trimethylamine (1
mL) were added to a stirred solution of L8 (70
mg 026 mmol) and Zn(OAc)2middot2H2O (63 mg
029 mmol) in MeOH (20 mL) at room
temperature The reaction mixture was stirred
at 75 degC for 20 h to give a yellow precipitate
which was collected and washed copiously with cold MeOH to afford 5 as a bright yellow solid
Yield 80 mg 64 Anal Calcd for C79H86N4O5Zn2(CH3OH)2 (136646) C 7120 H 693 N
410 Found C 7130 H 674 N 413 1H NMR (400 MHz DMSO-d6) δ 838 (s 2H H10) 818
(s 2H H5) 752ndash735 (m 8H H4 H3 H6 H9) 739 (s 2H H1) 721 (s 2H H2) 707 (d J = 67
Hz 2H H13) 697 (dd J = 76 and 72 Hz 2H H7) 684 (d J = 72 Hz 2H H11) 676 (dd J =
80 and 72 Hz 2H H8) 638 (t J = 76 Hz 2H H12) 407 (br q J = 52 Hz CH3OH) 318 (d J
= 52 Hz CH3OH) 172 (s 6H H16) 137 (s 18H H17) 125 (s 18H H14) 123 (s 18H H15)
1
2
3
415
56
7 8
910
11
13
12
16
17
14
O
ON N
OZn
ON N
OZn
tBu
tBu
tBu
tBu
S8
13C NMR (101 MHz C6D6DMSO-d6 91) δ 1729 1722 1614 1612 1458 1448 1423
1420 1398 1396 1346 1329 1309 1300 1299 1261 1258 1257 1221 1199 1194
1192 1154 1151 1120 354 353 348 342 314 297 296 ESI-MS (+ve mode) mz
1304 [M + H]+
Complex 6 The procedure for the
synthesis of 5 was adopted using L3 (50 mg
0074 mmol) and L9 (48 mg 015 mmol) A
orange precipitate was formed which was
collected washed copiously with cold MeOH
and recrystallized from CH2Cl2hexane (19)
to afford 6 as a bright yellow solid Yield 46 mg 41 Anal Calcd for C87H102N4O5Zn2(H2O)5
(150466) C 6945 H 750 N 372 Found C 6977 H 736 N 389 1H NMR (400 MHz
DMSO-d6) δ 880 (s 2H H10) 852 (s 2H H5) 768 (d J = 80 Hz 2H H9) 763 (d J = 83 Hz
2H H6) 750 (d J = 23 Hz 2H H3) 745ndash739 (m 4H H1 H4) 720 (d J = 25 Hz 2H H12)
717 (d J = 23 Hz 2H H2) 719ndash712 (m 2H H7) 705 (d J = 26 Hz 2H H11) 707ndash699 (m
2H H8) 173 (s 6H H16) 136 (s 18H H17) 131 (s 18H H14) 124 (s 18H H13) 121 (s 18H
H15) 13C NMR (101 MHz DMSO-d6) δ 1721 1708 1626 1625 1452 1448 1412 1411
1399 1346 1332 1323 1298 1292 1285 1268 1267 1260 1260 1250 1218 1213
1196 1186 1165 1159 356 353 348 346 339 336 319 319 300 298 ESI-MS (+ve
mode) mz 1416 [M + H]+
Complex 7 and 7middotAcOH Compound L7 (60 mg
012 mmol in powder form) and Et3N (3 mL) were
added to a stirred solution of L8 (62 mg 023 mmol)
and Zn(OAc)2middot2H2O (56 mg 025 mmol) in MeOH
(20 mL) at room temperature The reaction mixture
was stirred at room temperature for 20 h to give a grey
solution All volatiles were removed under reduced
pressure and recrystallization from CH2Cl2hexane
(19) afforded a yellow crystalline solid which was characterized as 7middotAcOH Yield 98 mg
68 Anal Calcd for C68H64N4O5Zn2CH3CO2H (120813) C 6959 H 464 N 567 Found
S9
C 6999 H 464 N 599 1H NMR (400 MHz DMSO-d6) δ 871 (s 2H H11) 870 (s 2H H6)
832 (d J = 22 Hz 2H H4) 804 (dd J = 76 and 11 Hz 2H H1) 781ndash772 (m 4H H3 H5)
750 (t J = 76 Hz 2H H2) 743 (d J = 76 Hz 2H H10) 737 (d J = 81 Hz 2H H12) 732 (d
J = 79 Hz 2H H7) 727 (d J = 75 Hz 2H H14) 701 (t J = 77 Hz 2H H8) 662 (dd J = 79
and 75 Hz 2H H9) 650 (t J = 75 Hz 2H H13) 185 (s 3H H17) 161 (s 18H H16) 156 (s
18H H15) 13C NMR (151 MHz DMSO-d6) δ 1720 1719 1717 1616 1605 1522 1424
1414 1390 1377 1350 1345 1300 1299 1267 1264 1256 1244 1243 1236 1194
1188 1184 1181 1149 1146 1119 353 350 295 294 210
The yellow crystalline solid (7middotAcOH) was
dissolved in CH2Cl2 (15 mL) and washed with DI
water (20 mL times 3) The organic layer was collected
all volatiles were removed under reduced pressure
and recrystallization from acetonepentane (15)
afforded 7 as an orange solid Yield 62 mg 47
(based on L7) Anal Calcd for C68H64N4O5Zn2
(114808) C 7114 H 562 N 488 Found C 7116
H 579 N 473 1H NMR (400 MHz DMSO-d6) δ
870 (s 2H H11) 869 (s 2H H6) 832 (s 2H H4)
804 (dd J = 77 and 10 Hz 2H H1) 781ndash772 (m 4H H3 H5) 750 (t J = 76 Hz 2H H2)
743 (d J = 81 Hz 2H H10) 737 (d J = 68 Hz 2H H12) 732 (d J = 80 Hz 2H H7) 727 (d
J = 73 Hz 2H H14) 701 (dd J = 77 and 74 Hz 2H H8) 662 (t J = 75 Hz 2H H9) 650 (t J
= 75 Hz 2H H13) 161 (s 18H H16) 155 (s 18H H15) 13C NMR (101 MHz DMSO-d6) δ
1720 1717 1618 1606 1522 1425 1414 1390 1376 1352 1347 1301 1300 1268
1265 1256 1245 1243 1238 1195 1188 1185 1183 1150 1146 1120 354 352
296 295 ESI-MS (+ve mode) mz 1150 [M + H]+
S10
Complex 8 The procedure for the synthesis
of 4 was adopted using L7 (78 mg 015 mmol) A
brown precipitate was formed which was
collected and washed copiously with MeOH and
pentane to afford 8 as a brownish yellow solid
Yield 85 mg 43 Anal Calcd for
C76H80N4O5Zn2(H2O)4 (133235) C 6851 H
666 N 421 Found C 6840 H 688 N 429 1H NMR (400 MHz DMSO-d6) δ 883 (s 2H
H13) 882 (s 2H H20) 813 (d J = 22 Hz 2H H8) 805 (d J = 76 Hz 2H H2) 776 (d J = 23
Hz 2H H12) 771 (d J = 70 Hz 2H H4) 763 (d J = 78 Hz 2H H18) 754ndash745 (m 4H H315)
734 (d J = 25 Hz 2H H25) 724 (d J = 26 Hz 2H H23) 711 (dd J = 76 and 78 Hz 2H
H16) 689 (dd J = 78 and 80 Hz 2H H17) 152 (s 18H H32) 151 (s 18H H30) 132 (s 18H
H28) 13C NMR (151 MHz DMSO-d6 peak assignments based on combination of DEPT-135
and 2-D 1H-1H 13C-1H (HSQC and HMBC) and NOE correlation NMR experiments) δ 1719
(C10) 1702 (C21) 1621 (C20) 1612 (C13) 1523 (C6) 1422 (C11) 1407 (C26) 1392 (C19)
1382 (C14) 1346 (C8) 1331 (C24) 1301 (C12) 1294 (C23) 1281 (C25) 1266 (C17) 1265
(C16) 1258 (C5) 1250 (C4) 1243 (C1) 1236 (C3) 1190 (C9) 1188 (C7) 1181 (C2) 1180
(C22) 1152 (C18) 1151 (C15) 352 (C2931) 335 (C27) 313 (C28) 296 (C30) 294 (C32) ESI-
MS (+ve mode) mz 1264 [M + H]+
S11
Figure S1 1H NMR (400 MHz CDCl3 298 K inset expanded) spectrum of reaction mixture corresponding to Run 10 in Table 3 [reaction conditions 12-epoxybutane (575 mmol 5 mL) catalyst 8 (00025 mol) nBu4NI co-cat (0125 mol) mesitylene (internal standard 1 mol) 10 bar CO2 initial pressure 95 degC 2 h]
Hf
Hc
Hd Hdrsquo
Hcrsquo ampnBu4NI
Ha
Hb1
Hb2
Harsquo
Hbrsquo1
Hbrsquo2
CDCl3
He
S12
Figure S2 1H NMR (400 MHz CDCl3 298 K inset expanded) spectrum of reaction mixture corresponding to Run 12 in Table 3 [reaction conditions 12-epoxyhexane (249 mmol 3 mL) catalyst 8 (00025 mol) nBu4NI co-cat (0125 mol) mesitylene (internal standard 1 mol) 10 bar CO2 initial pressure 95 degC 2 h]
nBu4NI Hf
Hd Hdrsquo
Ha
Hb1
Hb2 Harsquo
Hbrsquo1
Hbrsquo2
CDCl3
He
Hc Hcrsquo
S13
ESI References
1 R Okamura T Wada K Aikawa T Nagata and K Tanaka Inorg Chem 2004 43 7210
2 W-L Tong S-M Yiu and M C W Chan Inorg Chem 2013 52 7114
3 M Hirotsu N Ohno T Nakajima C Kushibe K Ueno and I Kinoshita Dalton Trans 2010 39 139
4 E B Schwartz C B Knobler and D J Cram J Am Chem Soc 1992 114 10775
5 Z Guo S-M Yiu and M C W Chan Chem Eur J 2013 19 8937
S4
Compound L3 L1 (082 g 20 mmol) 2-hydroxy-3-tert-
butyl-5-bromobenzaldehyde (122 g 476 mmol) and Pd(PPh3)4
(005 g 004 mmol) were suspended in a deoxygenated solution of
K2CO3 (122 g 880 mmol) in DMEDI water (31 40 mL) The
reaction mixture which became a clear orange solution upon
heating was then stirred under reflux for 3 h during which the
color of the solution became dark brown The mixture was cooled to 0 degC after which 1 M
aqueous HCl (20 mL) was added and the mixture was stirred at room temperature for 1 h Water
(100 mL) and chloroform (200 mL) were added to the resulting orange suspension After stirring
at room temperature for 1 h the organic layer was separated and washed with water The
resultant orange solution was dried over MgSO4 filtered and concentrated to dryness The crude
product was further purified by column chromatography (SiO2 hexaneCH2Cl2 11) to give the
desired product as a yellow solid Yield 092 g 68 1H NMR (300 MHz DMSO-d6) δ 1171 (s
2H OH) 947 (s 2H CHO) 760ndash743 (m 6H) 719 (d J = 22 Hz 2H) 173 (s 6H CH3)
134 (s 18H tBu) 120 (s 18H tBu) Compound L4 The procedure for the synthesis of L3 was
adopted using L1 (070 g 17 mmol) and 2-hydroxy-4-
iodobenzaldehyde (10 g 40 mmol) The crude product was
purified by column chromatography (SiO2 hexaneCH2Cl2 12) to
give the desired product as a pale yellow solid Yield 051 g 53 1H NMR (300 MHz DMSO-d6) δ 1014 (s 2H CHO) 756 (d J =
23 Hz 2H) 732 (d J = 80 Hz 2H) 716 (d J = 23 Hz 2H) 684
(d J = 12 Hz 2H) 676 (d J = 80 Hz 2H) 170 (s 6H CH3) 132 (s 18H tBu)
Compound L6 The procedure for the synthesis of L3
was adopted using L5 (200 g 782 mmol) and 2-hydroxy-5-
bromobenzaldehyde (346 g 172 mmol) The crude product
was purified by column chromatography (SiO2 CH2Cl2) to
give the desired product as a pale yellow solid Yield 24 g
75 1H NMR (300 MHz DMSO-d6) δ 1102 (s 2H OH)
S5
1036 (s 2H CHO) 830 (s 2H) 824ndash807 (m 4H) 773 (d J = 76 Hz 2H) 749 (dd J = 78
and 75 Hz 2H) 720 (d J = 86 Hz 2H)
Compound L7 The procedure for the synthesis of L3 was
adopted using L5 (080 g 31 mmol) The crude product was
purified by flash chromatography (SiO2 CH2Cl2hexane 11) to
give the desired product as a yellow powder Yield 12 g 74 1H NMR (400 MHz DMSO-d6) δ 1189 (s 2H OH) 1005 (s 2H
CHO) 823ndash819 (m 4H) 793 (d J = 22 Hz 2H) 773 (dd J =
76 and 12 Hz 2H) 755 (t J = 76 Hz 2H) 133 (s 18H tBu)
Compound L10 To a vigorously stirred solution of 12-
cyclohexanediamine (080 g 70 mmol) in dry CH2Cl2 (15 mL) at 0 oC
was added dropwise a solution of 35-di-tert-butylbenzaldehyde (109 g
467 mmol) in dry CH2Cl2 (10 mL) at 0 oC over 30 min The mixture
was then stirred at 0 oC for 3 h The resulting yellow solution was
evaporated under reduced pressure at 5 degC to give a pale yellow oil which was purified by
column chromatography (SiO2 ethyl acetate) to give the desired product as a pale yellow solid
Yield 052 g 34 1H NMR (400 MHz CDCl3) δ 1371 (s 1H OH) 843 (s 1H) 739 (d J =
24 Hz 1H) 710 (d J = 24 Hz 1H) 412 (q J = 71 Hz 2H) 293ndash274 (m 2H) 199ndash189 (m
2H) 183ndash171 (m 4H) 170ndash157 (m 2H) 145 (s 9H tBu) 130 (s 9H tBu)
Complex 2 Compound L4 (33 mg 0059 mmol
in powder form) and triethylamine (1 mL) were added
to a stirred solution of L9 (42 mg 013 mmol) and
Zn(OAc)2middot2H2O (28 mg 013 mmol) in MeOH (20 mL)
at room temperature The reaction mixture was stirred
at room temperature for 20 h to give a yellow
precipitate which was collected and washed copiously
with MeOH to afford 2 as a bright yellow solid Yield 64 mg 78 Anal Calcd for
C79H86N4O5Zn2(H2O)5 (139245) C 6814 H 695 N 402 Found C 6851 H 670 N 404
S6
1H NMR (300 MHz DMSO-d6) δ 897 (s 2H H11) 873 (s 2H H6) 784 (d J = 79 Hz 2H
H10) 753 (d J = 22 Hz 2H H1) 736 (d J = 85 Hz 2H H7) 732ndash719 (m 8H H5 H9 H12
H13) 718 (d J = 22 Hz 2H H2) 691 (dd J = 78 and 75 Hz 2H H8) 660 (d J = 13 Hz 2H
H3) 647 (dd J = 124 and 22 Hz 2H H4) 171 (s 6H H16) 145 (s 18H H14) 134 (s 18H
H17) 127 (s 18H H15) 13C NMR (101 MHz DMSO-d6) δ 1717 1703 1633 1615 1456
1451 1439 1407 1398 1392 1355 1334 1304 1296 1289 1284 1269 1265 1248
1232 1220 1183 1182 1163 1158 1155 352 348 343 336 315 314 297 ESI-MS
(+ve mode) mz 1304 [M + H]+
Complex 3 Compound L2 (025 g 045
mmol in powder form) was added to a stirred
solution of sodium methoxide (015 g 27
mmol) and zinc chloride (013 g 098 mmol)
in degassed EtOHCH2Cl2 (12 20 mL) at 0 degC
The mixture was stirred for 5 min after which
L10 (029 g 089 mmol) in EtOHCH2Cl2 (12
10 mL) was added The reaction mixture was stirred at room temperature for 12 h to give a pale
yellow suspension The filtrate was collected and all volatiles were removed under reduced
pressure to give a yellow solid which was purified by column chromatography (Et3N-saturated
SiO2 hexaneCH2Cl2 11) to afford 3 as a pale yellow solid Yield 013 g 21 Anal Calcd for
C79H98N4O5Zn2C6H14 (140064) C 7289 H 806 N 400 Found C 7269 H 782 N 377 1H NMR (300 MHz CD2Cl2) δ 765 (s 2H H13) 750 (d J = 22 Hz 2H H15) 749 (s 2H H6)
745 (dd J = 87 and 23 Hz 2H H4) 742 (d J = 23 Hz 2H H1) 731 (d J = 23 Hz 2H H3)
720 (d J = 23 Hz 2H H2) 694 (d J = 88 Hz 2H H5) 653 (d J = 23 Hz 2H H14) 379ndash
359 (m 4H H7 H12) 187ndash163 (m 8H H8 H11) 173 (s 6H H18) 150ndash128 (m 8H H10 H9)
147 (s 18H H17) 137 (s 18H H19) 132 (s 18H H16) 128ndash124 (m C6H14) 088 (t C6H14) 13C NMR (101 MHz CD2Cl2) δ 1737 1728 1702 1687 1459 1455 1417 1385 1382
1359 1314 1300 1298 1283 1267 1249 1237 1219 1178 1174 698 686 383 383
358 351 348 343 333 317 316 301 256 253 ESI-MS (+ve mode) mz 1316 [M + H]+
S7
Complex 4 The procedure for the synthesis
of 2 was adopted using L6 (50 mg 012 mmol) A
yellow precipitate was formed which was
collected and washed copiously with MeOH and
pentane to afford 4 as a yellow solid Yield 011 g
78 Anal Calcd for C68H64N4O5Zn2(H2O)3
(120213) C 6794 H 587 N 466 Found C
6787 H 596 N 445 1H NMR (400 MHz
DMSO-d6) δ 911 (s 2H H7) 893 (s 2H H12)
818 (d J = 22 Hz 2H H4) 809 (dd J = 24 and 26 Hz 2H H5) 805 (d J = 68 Hz 2H H1)
787 (d J = 86 Hz 2H H8) 784 (d J = 84 Hz 2H H11) 775 (d J = 75 Hz 2H H3) 750 (t J
= 76 Hz 2H H2) 737 (t J = 76 Hz 2H H9) 734 (d J = 25 Hz 2H H14) 730ndash722 (m 4H
H10 H13) 686 (d J = 89 Hz 2H H6) 149 (s 18H H16) 128 (s 18H H15) 13C NMR (101
MHz DMSO-d6) δ 1722 1707 1638 1623 1524 1410 1403 1391 1363 1345 1337
1299 1288 1278 1272 1254 1252 1246 1241 1240 1204 1199 1189 1184 1167
1163 354 338 316 299 ESI-MS (+ve mode) mz 1150 [M + H]+
Complex 5 Compound L3 (88 mg 013
mmol in powder form) and trimethylamine (1
mL) were added to a stirred solution of L8 (70
mg 026 mmol) and Zn(OAc)2middot2H2O (63 mg
029 mmol) in MeOH (20 mL) at room
temperature The reaction mixture was stirred
at 75 degC for 20 h to give a yellow precipitate
which was collected and washed copiously with cold MeOH to afford 5 as a bright yellow solid
Yield 80 mg 64 Anal Calcd for C79H86N4O5Zn2(CH3OH)2 (136646) C 7120 H 693 N
410 Found C 7130 H 674 N 413 1H NMR (400 MHz DMSO-d6) δ 838 (s 2H H10) 818
(s 2H H5) 752ndash735 (m 8H H4 H3 H6 H9) 739 (s 2H H1) 721 (s 2H H2) 707 (d J = 67
Hz 2H H13) 697 (dd J = 76 and 72 Hz 2H H7) 684 (d J = 72 Hz 2H H11) 676 (dd J =
80 and 72 Hz 2H H8) 638 (t J = 76 Hz 2H H12) 407 (br q J = 52 Hz CH3OH) 318 (d J
= 52 Hz CH3OH) 172 (s 6H H16) 137 (s 18H H17) 125 (s 18H H14) 123 (s 18H H15)
1
2
3
415
56
7 8
910
11
13
12
16
17
14
O
ON N
OZn
ON N
OZn
tBu
tBu
tBu
tBu
S8
13C NMR (101 MHz C6D6DMSO-d6 91) δ 1729 1722 1614 1612 1458 1448 1423
1420 1398 1396 1346 1329 1309 1300 1299 1261 1258 1257 1221 1199 1194
1192 1154 1151 1120 354 353 348 342 314 297 296 ESI-MS (+ve mode) mz
1304 [M + H]+
Complex 6 The procedure for the
synthesis of 5 was adopted using L3 (50 mg
0074 mmol) and L9 (48 mg 015 mmol) A
orange precipitate was formed which was
collected washed copiously with cold MeOH
and recrystallized from CH2Cl2hexane (19)
to afford 6 as a bright yellow solid Yield 46 mg 41 Anal Calcd for C87H102N4O5Zn2(H2O)5
(150466) C 6945 H 750 N 372 Found C 6977 H 736 N 389 1H NMR (400 MHz
DMSO-d6) δ 880 (s 2H H10) 852 (s 2H H5) 768 (d J = 80 Hz 2H H9) 763 (d J = 83 Hz
2H H6) 750 (d J = 23 Hz 2H H3) 745ndash739 (m 4H H1 H4) 720 (d J = 25 Hz 2H H12)
717 (d J = 23 Hz 2H H2) 719ndash712 (m 2H H7) 705 (d J = 26 Hz 2H H11) 707ndash699 (m
2H H8) 173 (s 6H H16) 136 (s 18H H17) 131 (s 18H H14) 124 (s 18H H13) 121 (s 18H
H15) 13C NMR (101 MHz DMSO-d6) δ 1721 1708 1626 1625 1452 1448 1412 1411
1399 1346 1332 1323 1298 1292 1285 1268 1267 1260 1260 1250 1218 1213
1196 1186 1165 1159 356 353 348 346 339 336 319 319 300 298 ESI-MS (+ve
mode) mz 1416 [M + H]+
Complex 7 and 7middotAcOH Compound L7 (60 mg
012 mmol in powder form) and Et3N (3 mL) were
added to a stirred solution of L8 (62 mg 023 mmol)
and Zn(OAc)2middot2H2O (56 mg 025 mmol) in MeOH
(20 mL) at room temperature The reaction mixture
was stirred at room temperature for 20 h to give a grey
solution All volatiles were removed under reduced
pressure and recrystallization from CH2Cl2hexane
(19) afforded a yellow crystalline solid which was characterized as 7middotAcOH Yield 98 mg
68 Anal Calcd for C68H64N4O5Zn2CH3CO2H (120813) C 6959 H 464 N 567 Found
S9
C 6999 H 464 N 599 1H NMR (400 MHz DMSO-d6) δ 871 (s 2H H11) 870 (s 2H H6)
832 (d J = 22 Hz 2H H4) 804 (dd J = 76 and 11 Hz 2H H1) 781ndash772 (m 4H H3 H5)
750 (t J = 76 Hz 2H H2) 743 (d J = 76 Hz 2H H10) 737 (d J = 81 Hz 2H H12) 732 (d
J = 79 Hz 2H H7) 727 (d J = 75 Hz 2H H14) 701 (t J = 77 Hz 2H H8) 662 (dd J = 79
and 75 Hz 2H H9) 650 (t J = 75 Hz 2H H13) 185 (s 3H H17) 161 (s 18H H16) 156 (s
18H H15) 13C NMR (151 MHz DMSO-d6) δ 1720 1719 1717 1616 1605 1522 1424
1414 1390 1377 1350 1345 1300 1299 1267 1264 1256 1244 1243 1236 1194
1188 1184 1181 1149 1146 1119 353 350 295 294 210
The yellow crystalline solid (7middotAcOH) was
dissolved in CH2Cl2 (15 mL) and washed with DI
water (20 mL times 3) The organic layer was collected
all volatiles were removed under reduced pressure
and recrystallization from acetonepentane (15)
afforded 7 as an orange solid Yield 62 mg 47
(based on L7) Anal Calcd for C68H64N4O5Zn2
(114808) C 7114 H 562 N 488 Found C 7116
H 579 N 473 1H NMR (400 MHz DMSO-d6) δ
870 (s 2H H11) 869 (s 2H H6) 832 (s 2H H4)
804 (dd J = 77 and 10 Hz 2H H1) 781ndash772 (m 4H H3 H5) 750 (t J = 76 Hz 2H H2)
743 (d J = 81 Hz 2H H10) 737 (d J = 68 Hz 2H H12) 732 (d J = 80 Hz 2H H7) 727 (d
J = 73 Hz 2H H14) 701 (dd J = 77 and 74 Hz 2H H8) 662 (t J = 75 Hz 2H H9) 650 (t J
= 75 Hz 2H H13) 161 (s 18H H16) 155 (s 18H H15) 13C NMR (101 MHz DMSO-d6) δ
1720 1717 1618 1606 1522 1425 1414 1390 1376 1352 1347 1301 1300 1268
1265 1256 1245 1243 1238 1195 1188 1185 1183 1150 1146 1120 354 352
296 295 ESI-MS (+ve mode) mz 1150 [M + H]+
S10
Complex 8 The procedure for the synthesis
of 4 was adopted using L7 (78 mg 015 mmol) A
brown precipitate was formed which was
collected and washed copiously with MeOH and
pentane to afford 8 as a brownish yellow solid
Yield 85 mg 43 Anal Calcd for
C76H80N4O5Zn2(H2O)4 (133235) C 6851 H
666 N 421 Found C 6840 H 688 N 429 1H NMR (400 MHz DMSO-d6) δ 883 (s 2H
H13) 882 (s 2H H20) 813 (d J = 22 Hz 2H H8) 805 (d J = 76 Hz 2H H2) 776 (d J = 23
Hz 2H H12) 771 (d J = 70 Hz 2H H4) 763 (d J = 78 Hz 2H H18) 754ndash745 (m 4H H315)
734 (d J = 25 Hz 2H H25) 724 (d J = 26 Hz 2H H23) 711 (dd J = 76 and 78 Hz 2H
H16) 689 (dd J = 78 and 80 Hz 2H H17) 152 (s 18H H32) 151 (s 18H H30) 132 (s 18H
H28) 13C NMR (151 MHz DMSO-d6 peak assignments based on combination of DEPT-135
and 2-D 1H-1H 13C-1H (HSQC and HMBC) and NOE correlation NMR experiments) δ 1719
(C10) 1702 (C21) 1621 (C20) 1612 (C13) 1523 (C6) 1422 (C11) 1407 (C26) 1392 (C19)
1382 (C14) 1346 (C8) 1331 (C24) 1301 (C12) 1294 (C23) 1281 (C25) 1266 (C17) 1265
(C16) 1258 (C5) 1250 (C4) 1243 (C1) 1236 (C3) 1190 (C9) 1188 (C7) 1181 (C2) 1180
(C22) 1152 (C18) 1151 (C15) 352 (C2931) 335 (C27) 313 (C28) 296 (C30) 294 (C32) ESI-
MS (+ve mode) mz 1264 [M + H]+
S11
Figure S1 1H NMR (400 MHz CDCl3 298 K inset expanded) spectrum of reaction mixture corresponding to Run 10 in Table 3 [reaction conditions 12-epoxybutane (575 mmol 5 mL) catalyst 8 (00025 mol) nBu4NI co-cat (0125 mol) mesitylene (internal standard 1 mol) 10 bar CO2 initial pressure 95 degC 2 h]
Hf
Hc
Hd Hdrsquo
Hcrsquo ampnBu4NI
Ha
Hb1
Hb2
Harsquo
Hbrsquo1
Hbrsquo2
CDCl3
He
S12
Figure S2 1H NMR (400 MHz CDCl3 298 K inset expanded) spectrum of reaction mixture corresponding to Run 12 in Table 3 [reaction conditions 12-epoxyhexane (249 mmol 3 mL) catalyst 8 (00025 mol) nBu4NI co-cat (0125 mol) mesitylene (internal standard 1 mol) 10 bar CO2 initial pressure 95 degC 2 h]
nBu4NI Hf
Hd Hdrsquo
Ha
Hb1
Hb2 Harsquo
Hbrsquo1
Hbrsquo2
CDCl3
He
Hc Hcrsquo
S13
ESI References
1 R Okamura T Wada K Aikawa T Nagata and K Tanaka Inorg Chem 2004 43 7210
2 W-L Tong S-M Yiu and M C W Chan Inorg Chem 2013 52 7114
3 M Hirotsu N Ohno T Nakajima C Kushibe K Ueno and I Kinoshita Dalton Trans 2010 39 139
4 E B Schwartz C B Knobler and D J Cram J Am Chem Soc 1992 114 10775
5 Z Guo S-M Yiu and M C W Chan Chem Eur J 2013 19 8937
S5
1036 (s 2H CHO) 830 (s 2H) 824ndash807 (m 4H) 773 (d J = 76 Hz 2H) 749 (dd J = 78
and 75 Hz 2H) 720 (d J = 86 Hz 2H)
Compound L7 The procedure for the synthesis of L3 was
adopted using L5 (080 g 31 mmol) The crude product was
purified by flash chromatography (SiO2 CH2Cl2hexane 11) to
give the desired product as a yellow powder Yield 12 g 74 1H NMR (400 MHz DMSO-d6) δ 1189 (s 2H OH) 1005 (s 2H
CHO) 823ndash819 (m 4H) 793 (d J = 22 Hz 2H) 773 (dd J =
76 and 12 Hz 2H) 755 (t J = 76 Hz 2H) 133 (s 18H tBu)
Compound L10 To a vigorously stirred solution of 12-
cyclohexanediamine (080 g 70 mmol) in dry CH2Cl2 (15 mL) at 0 oC
was added dropwise a solution of 35-di-tert-butylbenzaldehyde (109 g
467 mmol) in dry CH2Cl2 (10 mL) at 0 oC over 30 min The mixture
was then stirred at 0 oC for 3 h The resulting yellow solution was
evaporated under reduced pressure at 5 degC to give a pale yellow oil which was purified by
column chromatography (SiO2 ethyl acetate) to give the desired product as a pale yellow solid
Yield 052 g 34 1H NMR (400 MHz CDCl3) δ 1371 (s 1H OH) 843 (s 1H) 739 (d J =
24 Hz 1H) 710 (d J = 24 Hz 1H) 412 (q J = 71 Hz 2H) 293ndash274 (m 2H) 199ndash189 (m
2H) 183ndash171 (m 4H) 170ndash157 (m 2H) 145 (s 9H tBu) 130 (s 9H tBu)
Complex 2 Compound L4 (33 mg 0059 mmol
in powder form) and triethylamine (1 mL) were added
to a stirred solution of L9 (42 mg 013 mmol) and
Zn(OAc)2middot2H2O (28 mg 013 mmol) in MeOH (20 mL)
at room temperature The reaction mixture was stirred
at room temperature for 20 h to give a yellow
precipitate which was collected and washed copiously
with MeOH to afford 2 as a bright yellow solid Yield 64 mg 78 Anal Calcd for
C79H86N4O5Zn2(H2O)5 (139245) C 6814 H 695 N 402 Found C 6851 H 670 N 404
S6
1H NMR (300 MHz DMSO-d6) δ 897 (s 2H H11) 873 (s 2H H6) 784 (d J = 79 Hz 2H
H10) 753 (d J = 22 Hz 2H H1) 736 (d J = 85 Hz 2H H7) 732ndash719 (m 8H H5 H9 H12
H13) 718 (d J = 22 Hz 2H H2) 691 (dd J = 78 and 75 Hz 2H H8) 660 (d J = 13 Hz 2H
H3) 647 (dd J = 124 and 22 Hz 2H H4) 171 (s 6H H16) 145 (s 18H H14) 134 (s 18H
H17) 127 (s 18H H15) 13C NMR (101 MHz DMSO-d6) δ 1717 1703 1633 1615 1456
1451 1439 1407 1398 1392 1355 1334 1304 1296 1289 1284 1269 1265 1248
1232 1220 1183 1182 1163 1158 1155 352 348 343 336 315 314 297 ESI-MS
(+ve mode) mz 1304 [M + H]+
Complex 3 Compound L2 (025 g 045
mmol in powder form) was added to a stirred
solution of sodium methoxide (015 g 27
mmol) and zinc chloride (013 g 098 mmol)
in degassed EtOHCH2Cl2 (12 20 mL) at 0 degC
The mixture was stirred for 5 min after which
L10 (029 g 089 mmol) in EtOHCH2Cl2 (12
10 mL) was added The reaction mixture was stirred at room temperature for 12 h to give a pale
yellow suspension The filtrate was collected and all volatiles were removed under reduced
pressure to give a yellow solid which was purified by column chromatography (Et3N-saturated
SiO2 hexaneCH2Cl2 11) to afford 3 as a pale yellow solid Yield 013 g 21 Anal Calcd for
C79H98N4O5Zn2C6H14 (140064) C 7289 H 806 N 400 Found C 7269 H 782 N 377 1H NMR (300 MHz CD2Cl2) δ 765 (s 2H H13) 750 (d J = 22 Hz 2H H15) 749 (s 2H H6)
745 (dd J = 87 and 23 Hz 2H H4) 742 (d J = 23 Hz 2H H1) 731 (d J = 23 Hz 2H H3)
720 (d J = 23 Hz 2H H2) 694 (d J = 88 Hz 2H H5) 653 (d J = 23 Hz 2H H14) 379ndash
359 (m 4H H7 H12) 187ndash163 (m 8H H8 H11) 173 (s 6H H18) 150ndash128 (m 8H H10 H9)
147 (s 18H H17) 137 (s 18H H19) 132 (s 18H H16) 128ndash124 (m C6H14) 088 (t C6H14) 13C NMR (101 MHz CD2Cl2) δ 1737 1728 1702 1687 1459 1455 1417 1385 1382
1359 1314 1300 1298 1283 1267 1249 1237 1219 1178 1174 698 686 383 383
358 351 348 343 333 317 316 301 256 253 ESI-MS (+ve mode) mz 1316 [M + H]+
S7
Complex 4 The procedure for the synthesis
of 2 was adopted using L6 (50 mg 012 mmol) A
yellow precipitate was formed which was
collected and washed copiously with MeOH and
pentane to afford 4 as a yellow solid Yield 011 g
78 Anal Calcd for C68H64N4O5Zn2(H2O)3
(120213) C 6794 H 587 N 466 Found C
6787 H 596 N 445 1H NMR (400 MHz
DMSO-d6) δ 911 (s 2H H7) 893 (s 2H H12)
818 (d J = 22 Hz 2H H4) 809 (dd J = 24 and 26 Hz 2H H5) 805 (d J = 68 Hz 2H H1)
787 (d J = 86 Hz 2H H8) 784 (d J = 84 Hz 2H H11) 775 (d J = 75 Hz 2H H3) 750 (t J
= 76 Hz 2H H2) 737 (t J = 76 Hz 2H H9) 734 (d J = 25 Hz 2H H14) 730ndash722 (m 4H
H10 H13) 686 (d J = 89 Hz 2H H6) 149 (s 18H H16) 128 (s 18H H15) 13C NMR (101
MHz DMSO-d6) δ 1722 1707 1638 1623 1524 1410 1403 1391 1363 1345 1337
1299 1288 1278 1272 1254 1252 1246 1241 1240 1204 1199 1189 1184 1167
1163 354 338 316 299 ESI-MS (+ve mode) mz 1150 [M + H]+
Complex 5 Compound L3 (88 mg 013
mmol in powder form) and trimethylamine (1
mL) were added to a stirred solution of L8 (70
mg 026 mmol) and Zn(OAc)2middot2H2O (63 mg
029 mmol) in MeOH (20 mL) at room
temperature The reaction mixture was stirred
at 75 degC for 20 h to give a yellow precipitate
which was collected and washed copiously with cold MeOH to afford 5 as a bright yellow solid
Yield 80 mg 64 Anal Calcd for C79H86N4O5Zn2(CH3OH)2 (136646) C 7120 H 693 N
410 Found C 7130 H 674 N 413 1H NMR (400 MHz DMSO-d6) δ 838 (s 2H H10) 818
(s 2H H5) 752ndash735 (m 8H H4 H3 H6 H9) 739 (s 2H H1) 721 (s 2H H2) 707 (d J = 67
Hz 2H H13) 697 (dd J = 76 and 72 Hz 2H H7) 684 (d J = 72 Hz 2H H11) 676 (dd J =
80 and 72 Hz 2H H8) 638 (t J = 76 Hz 2H H12) 407 (br q J = 52 Hz CH3OH) 318 (d J
= 52 Hz CH3OH) 172 (s 6H H16) 137 (s 18H H17) 125 (s 18H H14) 123 (s 18H H15)
1
2
3
415
56
7 8
910
11
13
12
16
17
14
O
ON N
OZn
ON N
OZn
tBu
tBu
tBu
tBu
S8
13C NMR (101 MHz C6D6DMSO-d6 91) δ 1729 1722 1614 1612 1458 1448 1423
1420 1398 1396 1346 1329 1309 1300 1299 1261 1258 1257 1221 1199 1194
1192 1154 1151 1120 354 353 348 342 314 297 296 ESI-MS (+ve mode) mz
1304 [M + H]+
Complex 6 The procedure for the
synthesis of 5 was adopted using L3 (50 mg
0074 mmol) and L9 (48 mg 015 mmol) A
orange precipitate was formed which was
collected washed copiously with cold MeOH
and recrystallized from CH2Cl2hexane (19)
to afford 6 as a bright yellow solid Yield 46 mg 41 Anal Calcd for C87H102N4O5Zn2(H2O)5
(150466) C 6945 H 750 N 372 Found C 6977 H 736 N 389 1H NMR (400 MHz
DMSO-d6) δ 880 (s 2H H10) 852 (s 2H H5) 768 (d J = 80 Hz 2H H9) 763 (d J = 83 Hz
2H H6) 750 (d J = 23 Hz 2H H3) 745ndash739 (m 4H H1 H4) 720 (d J = 25 Hz 2H H12)
717 (d J = 23 Hz 2H H2) 719ndash712 (m 2H H7) 705 (d J = 26 Hz 2H H11) 707ndash699 (m
2H H8) 173 (s 6H H16) 136 (s 18H H17) 131 (s 18H H14) 124 (s 18H H13) 121 (s 18H
H15) 13C NMR (101 MHz DMSO-d6) δ 1721 1708 1626 1625 1452 1448 1412 1411
1399 1346 1332 1323 1298 1292 1285 1268 1267 1260 1260 1250 1218 1213
1196 1186 1165 1159 356 353 348 346 339 336 319 319 300 298 ESI-MS (+ve
mode) mz 1416 [M + H]+
Complex 7 and 7middotAcOH Compound L7 (60 mg
012 mmol in powder form) and Et3N (3 mL) were
added to a stirred solution of L8 (62 mg 023 mmol)
and Zn(OAc)2middot2H2O (56 mg 025 mmol) in MeOH
(20 mL) at room temperature The reaction mixture
was stirred at room temperature for 20 h to give a grey
solution All volatiles were removed under reduced
pressure and recrystallization from CH2Cl2hexane
(19) afforded a yellow crystalline solid which was characterized as 7middotAcOH Yield 98 mg
68 Anal Calcd for C68H64N4O5Zn2CH3CO2H (120813) C 6959 H 464 N 567 Found
S9
C 6999 H 464 N 599 1H NMR (400 MHz DMSO-d6) δ 871 (s 2H H11) 870 (s 2H H6)
832 (d J = 22 Hz 2H H4) 804 (dd J = 76 and 11 Hz 2H H1) 781ndash772 (m 4H H3 H5)
750 (t J = 76 Hz 2H H2) 743 (d J = 76 Hz 2H H10) 737 (d J = 81 Hz 2H H12) 732 (d
J = 79 Hz 2H H7) 727 (d J = 75 Hz 2H H14) 701 (t J = 77 Hz 2H H8) 662 (dd J = 79
and 75 Hz 2H H9) 650 (t J = 75 Hz 2H H13) 185 (s 3H H17) 161 (s 18H H16) 156 (s
18H H15) 13C NMR (151 MHz DMSO-d6) δ 1720 1719 1717 1616 1605 1522 1424
1414 1390 1377 1350 1345 1300 1299 1267 1264 1256 1244 1243 1236 1194
1188 1184 1181 1149 1146 1119 353 350 295 294 210
The yellow crystalline solid (7middotAcOH) was
dissolved in CH2Cl2 (15 mL) and washed with DI
water (20 mL times 3) The organic layer was collected
all volatiles were removed under reduced pressure
and recrystallization from acetonepentane (15)
afforded 7 as an orange solid Yield 62 mg 47
(based on L7) Anal Calcd for C68H64N4O5Zn2
(114808) C 7114 H 562 N 488 Found C 7116
H 579 N 473 1H NMR (400 MHz DMSO-d6) δ
870 (s 2H H11) 869 (s 2H H6) 832 (s 2H H4)
804 (dd J = 77 and 10 Hz 2H H1) 781ndash772 (m 4H H3 H5) 750 (t J = 76 Hz 2H H2)
743 (d J = 81 Hz 2H H10) 737 (d J = 68 Hz 2H H12) 732 (d J = 80 Hz 2H H7) 727 (d
J = 73 Hz 2H H14) 701 (dd J = 77 and 74 Hz 2H H8) 662 (t J = 75 Hz 2H H9) 650 (t J
= 75 Hz 2H H13) 161 (s 18H H16) 155 (s 18H H15) 13C NMR (101 MHz DMSO-d6) δ
1720 1717 1618 1606 1522 1425 1414 1390 1376 1352 1347 1301 1300 1268
1265 1256 1245 1243 1238 1195 1188 1185 1183 1150 1146 1120 354 352
296 295 ESI-MS (+ve mode) mz 1150 [M + H]+
S10
Complex 8 The procedure for the synthesis
of 4 was adopted using L7 (78 mg 015 mmol) A
brown precipitate was formed which was
collected and washed copiously with MeOH and
pentane to afford 8 as a brownish yellow solid
Yield 85 mg 43 Anal Calcd for
C76H80N4O5Zn2(H2O)4 (133235) C 6851 H
666 N 421 Found C 6840 H 688 N 429 1H NMR (400 MHz DMSO-d6) δ 883 (s 2H
H13) 882 (s 2H H20) 813 (d J = 22 Hz 2H H8) 805 (d J = 76 Hz 2H H2) 776 (d J = 23
Hz 2H H12) 771 (d J = 70 Hz 2H H4) 763 (d J = 78 Hz 2H H18) 754ndash745 (m 4H H315)
734 (d J = 25 Hz 2H H25) 724 (d J = 26 Hz 2H H23) 711 (dd J = 76 and 78 Hz 2H
H16) 689 (dd J = 78 and 80 Hz 2H H17) 152 (s 18H H32) 151 (s 18H H30) 132 (s 18H
H28) 13C NMR (151 MHz DMSO-d6 peak assignments based on combination of DEPT-135
and 2-D 1H-1H 13C-1H (HSQC and HMBC) and NOE correlation NMR experiments) δ 1719
(C10) 1702 (C21) 1621 (C20) 1612 (C13) 1523 (C6) 1422 (C11) 1407 (C26) 1392 (C19)
1382 (C14) 1346 (C8) 1331 (C24) 1301 (C12) 1294 (C23) 1281 (C25) 1266 (C17) 1265
(C16) 1258 (C5) 1250 (C4) 1243 (C1) 1236 (C3) 1190 (C9) 1188 (C7) 1181 (C2) 1180
(C22) 1152 (C18) 1151 (C15) 352 (C2931) 335 (C27) 313 (C28) 296 (C30) 294 (C32) ESI-
MS (+ve mode) mz 1264 [M + H]+
S11
Figure S1 1H NMR (400 MHz CDCl3 298 K inset expanded) spectrum of reaction mixture corresponding to Run 10 in Table 3 [reaction conditions 12-epoxybutane (575 mmol 5 mL) catalyst 8 (00025 mol) nBu4NI co-cat (0125 mol) mesitylene (internal standard 1 mol) 10 bar CO2 initial pressure 95 degC 2 h]
Hf
Hc
Hd Hdrsquo
Hcrsquo ampnBu4NI
Ha
Hb1
Hb2
Harsquo
Hbrsquo1
Hbrsquo2
CDCl3
He
S12
Figure S2 1H NMR (400 MHz CDCl3 298 K inset expanded) spectrum of reaction mixture corresponding to Run 12 in Table 3 [reaction conditions 12-epoxyhexane (249 mmol 3 mL) catalyst 8 (00025 mol) nBu4NI co-cat (0125 mol) mesitylene (internal standard 1 mol) 10 bar CO2 initial pressure 95 degC 2 h]
nBu4NI Hf
Hd Hdrsquo
Ha
Hb1
Hb2 Harsquo
Hbrsquo1
Hbrsquo2
CDCl3
He
Hc Hcrsquo
S13
ESI References
1 R Okamura T Wada K Aikawa T Nagata and K Tanaka Inorg Chem 2004 43 7210
2 W-L Tong S-M Yiu and M C W Chan Inorg Chem 2013 52 7114
3 M Hirotsu N Ohno T Nakajima C Kushibe K Ueno and I Kinoshita Dalton Trans 2010 39 139
4 E B Schwartz C B Knobler and D J Cram J Am Chem Soc 1992 114 10775
5 Z Guo S-M Yiu and M C W Chan Chem Eur J 2013 19 8937
S6
1H NMR (300 MHz DMSO-d6) δ 897 (s 2H H11) 873 (s 2H H6) 784 (d J = 79 Hz 2H
H10) 753 (d J = 22 Hz 2H H1) 736 (d J = 85 Hz 2H H7) 732ndash719 (m 8H H5 H9 H12
H13) 718 (d J = 22 Hz 2H H2) 691 (dd J = 78 and 75 Hz 2H H8) 660 (d J = 13 Hz 2H
H3) 647 (dd J = 124 and 22 Hz 2H H4) 171 (s 6H H16) 145 (s 18H H14) 134 (s 18H
H17) 127 (s 18H H15) 13C NMR (101 MHz DMSO-d6) δ 1717 1703 1633 1615 1456
1451 1439 1407 1398 1392 1355 1334 1304 1296 1289 1284 1269 1265 1248
1232 1220 1183 1182 1163 1158 1155 352 348 343 336 315 314 297 ESI-MS
(+ve mode) mz 1304 [M + H]+
Complex 3 Compound L2 (025 g 045
mmol in powder form) was added to a stirred
solution of sodium methoxide (015 g 27
mmol) and zinc chloride (013 g 098 mmol)
in degassed EtOHCH2Cl2 (12 20 mL) at 0 degC
The mixture was stirred for 5 min after which
L10 (029 g 089 mmol) in EtOHCH2Cl2 (12
10 mL) was added The reaction mixture was stirred at room temperature for 12 h to give a pale
yellow suspension The filtrate was collected and all volatiles were removed under reduced
pressure to give a yellow solid which was purified by column chromatography (Et3N-saturated
SiO2 hexaneCH2Cl2 11) to afford 3 as a pale yellow solid Yield 013 g 21 Anal Calcd for
C79H98N4O5Zn2C6H14 (140064) C 7289 H 806 N 400 Found C 7269 H 782 N 377 1H NMR (300 MHz CD2Cl2) δ 765 (s 2H H13) 750 (d J = 22 Hz 2H H15) 749 (s 2H H6)
745 (dd J = 87 and 23 Hz 2H H4) 742 (d J = 23 Hz 2H H1) 731 (d J = 23 Hz 2H H3)
720 (d J = 23 Hz 2H H2) 694 (d J = 88 Hz 2H H5) 653 (d J = 23 Hz 2H H14) 379ndash
359 (m 4H H7 H12) 187ndash163 (m 8H H8 H11) 173 (s 6H H18) 150ndash128 (m 8H H10 H9)
147 (s 18H H17) 137 (s 18H H19) 132 (s 18H H16) 128ndash124 (m C6H14) 088 (t C6H14) 13C NMR (101 MHz CD2Cl2) δ 1737 1728 1702 1687 1459 1455 1417 1385 1382
1359 1314 1300 1298 1283 1267 1249 1237 1219 1178 1174 698 686 383 383
358 351 348 343 333 317 316 301 256 253 ESI-MS (+ve mode) mz 1316 [M + H]+
S7
Complex 4 The procedure for the synthesis
of 2 was adopted using L6 (50 mg 012 mmol) A
yellow precipitate was formed which was
collected and washed copiously with MeOH and
pentane to afford 4 as a yellow solid Yield 011 g
78 Anal Calcd for C68H64N4O5Zn2(H2O)3
(120213) C 6794 H 587 N 466 Found C
6787 H 596 N 445 1H NMR (400 MHz
DMSO-d6) δ 911 (s 2H H7) 893 (s 2H H12)
818 (d J = 22 Hz 2H H4) 809 (dd J = 24 and 26 Hz 2H H5) 805 (d J = 68 Hz 2H H1)
787 (d J = 86 Hz 2H H8) 784 (d J = 84 Hz 2H H11) 775 (d J = 75 Hz 2H H3) 750 (t J
= 76 Hz 2H H2) 737 (t J = 76 Hz 2H H9) 734 (d J = 25 Hz 2H H14) 730ndash722 (m 4H
H10 H13) 686 (d J = 89 Hz 2H H6) 149 (s 18H H16) 128 (s 18H H15) 13C NMR (101
MHz DMSO-d6) δ 1722 1707 1638 1623 1524 1410 1403 1391 1363 1345 1337
1299 1288 1278 1272 1254 1252 1246 1241 1240 1204 1199 1189 1184 1167
1163 354 338 316 299 ESI-MS (+ve mode) mz 1150 [M + H]+
Complex 5 Compound L3 (88 mg 013
mmol in powder form) and trimethylamine (1
mL) were added to a stirred solution of L8 (70
mg 026 mmol) and Zn(OAc)2middot2H2O (63 mg
029 mmol) in MeOH (20 mL) at room
temperature The reaction mixture was stirred
at 75 degC for 20 h to give a yellow precipitate
which was collected and washed copiously with cold MeOH to afford 5 as a bright yellow solid
Yield 80 mg 64 Anal Calcd for C79H86N4O5Zn2(CH3OH)2 (136646) C 7120 H 693 N
410 Found C 7130 H 674 N 413 1H NMR (400 MHz DMSO-d6) δ 838 (s 2H H10) 818
(s 2H H5) 752ndash735 (m 8H H4 H3 H6 H9) 739 (s 2H H1) 721 (s 2H H2) 707 (d J = 67
Hz 2H H13) 697 (dd J = 76 and 72 Hz 2H H7) 684 (d J = 72 Hz 2H H11) 676 (dd J =
80 and 72 Hz 2H H8) 638 (t J = 76 Hz 2H H12) 407 (br q J = 52 Hz CH3OH) 318 (d J
= 52 Hz CH3OH) 172 (s 6H H16) 137 (s 18H H17) 125 (s 18H H14) 123 (s 18H H15)
1
2
3
415
56
7 8
910
11
13
12
16
17
14
O
ON N
OZn
ON N
OZn
tBu
tBu
tBu
tBu
S8
13C NMR (101 MHz C6D6DMSO-d6 91) δ 1729 1722 1614 1612 1458 1448 1423
1420 1398 1396 1346 1329 1309 1300 1299 1261 1258 1257 1221 1199 1194
1192 1154 1151 1120 354 353 348 342 314 297 296 ESI-MS (+ve mode) mz
1304 [M + H]+
Complex 6 The procedure for the
synthesis of 5 was adopted using L3 (50 mg
0074 mmol) and L9 (48 mg 015 mmol) A
orange precipitate was formed which was
collected washed copiously with cold MeOH
and recrystallized from CH2Cl2hexane (19)
to afford 6 as a bright yellow solid Yield 46 mg 41 Anal Calcd for C87H102N4O5Zn2(H2O)5
(150466) C 6945 H 750 N 372 Found C 6977 H 736 N 389 1H NMR (400 MHz
DMSO-d6) δ 880 (s 2H H10) 852 (s 2H H5) 768 (d J = 80 Hz 2H H9) 763 (d J = 83 Hz
2H H6) 750 (d J = 23 Hz 2H H3) 745ndash739 (m 4H H1 H4) 720 (d J = 25 Hz 2H H12)
717 (d J = 23 Hz 2H H2) 719ndash712 (m 2H H7) 705 (d J = 26 Hz 2H H11) 707ndash699 (m
2H H8) 173 (s 6H H16) 136 (s 18H H17) 131 (s 18H H14) 124 (s 18H H13) 121 (s 18H
H15) 13C NMR (101 MHz DMSO-d6) δ 1721 1708 1626 1625 1452 1448 1412 1411
1399 1346 1332 1323 1298 1292 1285 1268 1267 1260 1260 1250 1218 1213
1196 1186 1165 1159 356 353 348 346 339 336 319 319 300 298 ESI-MS (+ve
mode) mz 1416 [M + H]+
Complex 7 and 7middotAcOH Compound L7 (60 mg
012 mmol in powder form) and Et3N (3 mL) were
added to a stirred solution of L8 (62 mg 023 mmol)
and Zn(OAc)2middot2H2O (56 mg 025 mmol) in MeOH
(20 mL) at room temperature The reaction mixture
was stirred at room temperature for 20 h to give a grey
solution All volatiles were removed under reduced
pressure and recrystallization from CH2Cl2hexane
(19) afforded a yellow crystalline solid which was characterized as 7middotAcOH Yield 98 mg
68 Anal Calcd for C68H64N4O5Zn2CH3CO2H (120813) C 6959 H 464 N 567 Found
S9
C 6999 H 464 N 599 1H NMR (400 MHz DMSO-d6) δ 871 (s 2H H11) 870 (s 2H H6)
832 (d J = 22 Hz 2H H4) 804 (dd J = 76 and 11 Hz 2H H1) 781ndash772 (m 4H H3 H5)
750 (t J = 76 Hz 2H H2) 743 (d J = 76 Hz 2H H10) 737 (d J = 81 Hz 2H H12) 732 (d
J = 79 Hz 2H H7) 727 (d J = 75 Hz 2H H14) 701 (t J = 77 Hz 2H H8) 662 (dd J = 79
and 75 Hz 2H H9) 650 (t J = 75 Hz 2H H13) 185 (s 3H H17) 161 (s 18H H16) 156 (s
18H H15) 13C NMR (151 MHz DMSO-d6) δ 1720 1719 1717 1616 1605 1522 1424
1414 1390 1377 1350 1345 1300 1299 1267 1264 1256 1244 1243 1236 1194
1188 1184 1181 1149 1146 1119 353 350 295 294 210
The yellow crystalline solid (7middotAcOH) was
dissolved in CH2Cl2 (15 mL) and washed with DI
water (20 mL times 3) The organic layer was collected
all volatiles were removed under reduced pressure
and recrystallization from acetonepentane (15)
afforded 7 as an orange solid Yield 62 mg 47
(based on L7) Anal Calcd for C68H64N4O5Zn2
(114808) C 7114 H 562 N 488 Found C 7116
H 579 N 473 1H NMR (400 MHz DMSO-d6) δ
870 (s 2H H11) 869 (s 2H H6) 832 (s 2H H4)
804 (dd J = 77 and 10 Hz 2H H1) 781ndash772 (m 4H H3 H5) 750 (t J = 76 Hz 2H H2)
743 (d J = 81 Hz 2H H10) 737 (d J = 68 Hz 2H H12) 732 (d J = 80 Hz 2H H7) 727 (d
J = 73 Hz 2H H14) 701 (dd J = 77 and 74 Hz 2H H8) 662 (t J = 75 Hz 2H H9) 650 (t J
= 75 Hz 2H H13) 161 (s 18H H16) 155 (s 18H H15) 13C NMR (101 MHz DMSO-d6) δ
1720 1717 1618 1606 1522 1425 1414 1390 1376 1352 1347 1301 1300 1268
1265 1256 1245 1243 1238 1195 1188 1185 1183 1150 1146 1120 354 352
296 295 ESI-MS (+ve mode) mz 1150 [M + H]+
S10
Complex 8 The procedure for the synthesis
of 4 was adopted using L7 (78 mg 015 mmol) A
brown precipitate was formed which was
collected and washed copiously with MeOH and
pentane to afford 8 as a brownish yellow solid
Yield 85 mg 43 Anal Calcd for
C76H80N4O5Zn2(H2O)4 (133235) C 6851 H
666 N 421 Found C 6840 H 688 N 429 1H NMR (400 MHz DMSO-d6) δ 883 (s 2H
H13) 882 (s 2H H20) 813 (d J = 22 Hz 2H H8) 805 (d J = 76 Hz 2H H2) 776 (d J = 23
Hz 2H H12) 771 (d J = 70 Hz 2H H4) 763 (d J = 78 Hz 2H H18) 754ndash745 (m 4H H315)
734 (d J = 25 Hz 2H H25) 724 (d J = 26 Hz 2H H23) 711 (dd J = 76 and 78 Hz 2H
H16) 689 (dd J = 78 and 80 Hz 2H H17) 152 (s 18H H32) 151 (s 18H H30) 132 (s 18H
H28) 13C NMR (151 MHz DMSO-d6 peak assignments based on combination of DEPT-135
and 2-D 1H-1H 13C-1H (HSQC and HMBC) and NOE correlation NMR experiments) δ 1719
(C10) 1702 (C21) 1621 (C20) 1612 (C13) 1523 (C6) 1422 (C11) 1407 (C26) 1392 (C19)
1382 (C14) 1346 (C8) 1331 (C24) 1301 (C12) 1294 (C23) 1281 (C25) 1266 (C17) 1265
(C16) 1258 (C5) 1250 (C4) 1243 (C1) 1236 (C3) 1190 (C9) 1188 (C7) 1181 (C2) 1180
(C22) 1152 (C18) 1151 (C15) 352 (C2931) 335 (C27) 313 (C28) 296 (C30) 294 (C32) ESI-
MS (+ve mode) mz 1264 [M + H]+
S11
Figure S1 1H NMR (400 MHz CDCl3 298 K inset expanded) spectrum of reaction mixture corresponding to Run 10 in Table 3 [reaction conditions 12-epoxybutane (575 mmol 5 mL) catalyst 8 (00025 mol) nBu4NI co-cat (0125 mol) mesitylene (internal standard 1 mol) 10 bar CO2 initial pressure 95 degC 2 h]
Hf
Hc
Hd Hdrsquo
Hcrsquo ampnBu4NI
Ha
Hb1
Hb2
Harsquo
Hbrsquo1
Hbrsquo2
CDCl3
He
S12
Figure S2 1H NMR (400 MHz CDCl3 298 K inset expanded) spectrum of reaction mixture corresponding to Run 12 in Table 3 [reaction conditions 12-epoxyhexane (249 mmol 3 mL) catalyst 8 (00025 mol) nBu4NI co-cat (0125 mol) mesitylene (internal standard 1 mol) 10 bar CO2 initial pressure 95 degC 2 h]
nBu4NI Hf
Hd Hdrsquo
Ha
Hb1
Hb2 Harsquo
Hbrsquo1
Hbrsquo2
CDCl3
He
Hc Hcrsquo
S13
ESI References
1 R Okamura T Wada K Aikawa T Nagata and K Tanaka Inorg Chem 2004 43 7210
2 W-L Tong S-M Yiu and M C W Chan Inorg Chem 2013 52 7114
3 M Hirotsu N Ohno T Nakajima C Kushibe K Ueno and I Kinoshita Dalton Trans 2010 39 139
4 E B Schwartz C B Knobler and D J Cram J Am Chem Soc 1992 114 10775
5 Z Guo S-M Yiu and M C W Chan Chem Eur J 2013 19 8937
S7
Complex 4 The procedure for the synthesis
of 2 was adopted using L6 (50 mg 012 mmol) A
yellow precipitate was formed which was
collected and washed copiously with MeOH and
pentane to afford 4 as a yellow solid Yield 011 g
78 Anal Calcd for C68H64N4O5Zn2(H2O)3
(120213) C 6794 H 587 N 466 Found C
6787 H 596 N 445 1H NMR (400 MHz
DMSO-d6) δ 911 (s 2H H7) 893 (s 2H H12)
818 (d J = 22 Hz 2H H4) 809 (dd J = 24 and 26 Hz 2H H5) 805 (d J = 68 Hz 2H H1)
787 (d J = 86 Hz 2H H8) 784 (d J = 84 Hz 2H H11) 775 (d J = 75 Hz 2H H3) 750 (t J
= 76 Hz 2H H2) 737 (t J = 76 Hz 2H H9) 734 (d J = 25 Hz 2H H14) 730ndash722 (m 4H
H10 H13) 686 (d J = 89 Hz 2H H6) 149 (s 18H H16) 128 (s 18H H15) 13C NMR (101
MHz DMSO-d6) δ 1722 1707 1638 1623 1524 1410 1403 1391 1363 1345 1337
1299 1288 1278 1272 1254 1252 1246 1241 1240 1204 1199 1189 1184 1167
1163 354 338 316 299 ESI-MS (+ve mode) mz 1150 [M + H]+
Complex 5 Compound L3 (88 mg 013
mmol in powder form) and trimethylamine (1
mL) were added to a stirred solution of L8 (70
mg 026 mmol) and Zn(OAc)2middot2H2O (63 mg
029 mmol) in MeOH (20 mL) at room
temperature The reaction mixture was stirred
at 75 degC for 20 h to give a yellow precipitate
which was collected and washed copiously with cold MeOH to afford 5 as a bright yellow solid
Yield 80 mg 64 Anal Calcd for C79H86N4O5Zn2(CH3OH)2 (136646) C 7120 H 693 N
410 Found C 7130 H 674 N 413 1H NMR (400 MHz DMSO-d6) δ 838 (s 2H H10) 818
(s 2H H5) 752ndash735 (m 8H H4 H3 H6 H9) 739 (s 2H H1) 721 (s 2H H2) 707 (d J = 67
Hz 2H H13) 697 (dd J = 76 and 72 Hz 2H H7) 684 (d J = 72 Hz 2H H11) 676 (dd J =
80 and 72 Hz 2H H8) 638 (t J = 76 Hz 2H H12) 407 (br q J = 52 Hz CH3OH) 318 (d J
= 52 Hz CH3OH) 172 (s 6H H16) 137 (s 18H H17) 125 (s 18H H14) 123 (s 18H H15)
1
2
3
415
56
7 8
910
11
13
12
16
17
14
O
ON N
OZn
ON N
OZn
tBu
tBu
tBu
tBu
S8
13C NMR (101 MHz C6D6DMSO-d6 91) δ 1729 1722 1614 1612 1458 1448 1423
1420 1398 1396 1346 1329 1309 1300 1299 1261 1258 1257 1221 1199 1194
1192 1154 1151 1120 354 353 348 342 314 297 296 ESI-MS (+ve mode) mz
1304 [M + H]+
Complex 6 The procedure for the
synthesis of 5 was adopted using L3 (50 mg
0074 mmol) and L9 (48 mg 015 mmol) A
orange precipitate was formed which was
collected washed copiously with cold MeOH
and recrystallized from CH2Cl2hexane (19)
to afford 6 as a bright yellow solid Yield 46 mg 41 Anal Calcd for C87H102N4O5Zn2(H2O)5
(150466) C 6945 H 750 N 372 Found C 6977 H 736 N 389 1H NMR (400 MHz
DMSO-d6) δ 880 (s 2H H10) 852 (s 2H H5) 768 (d J = 80 Hz 2H H9) 763 (d J = 83 Hz
2H H6) 750 (d J = 23 Hz 2H H3) 745ndash739 (m 4H H1 H4) 720 (d J = 25 Hz 2H H12)
717 (d J = 23 Hz 2H H2) 719ndash712 (m 2H H7) 705 (d J = 26 Hz 2H H11) 707ndash699 (m
2H H8) 173 (s 6H H16) 136 (s 18H H17) 131 (s 18H H14) 124 (s 18H H13) 121 (s 18H
H15) 13C NMR (101 MHz DMSO-d6) δ 1721 1708 1626 1625 1452 1448 1412 1411
1399 1346 1332 1323 1298 1292 1285 1268 1267 1260 1260 1250 1218 1213
1196 1186 1165 1159 356 353 348 346 339 336 319 319 300 298 ESI-MS (+ve
mode) mz 1416 [M + H]+
Complex 7 and 7middotAcOH Compound L7 (60 mg
012 mmol in powder form) and Et3N (3 mL) were
added to a stirred solution of L8 (62 mg 023 mmol)
and Zn(OAc)2middot2H2O (56 mg 025 mmol) in MeOH
(20 mL) at room temperature The reaction mixture
was stirred at room temperature for 20 h to give a grey
solution All volatiles were removed under reduced
pressure and recrystallization from CH2Cl2hexane
(19) afforded a yellow crystalline solid which was characterized as 7middotAcOH Yield 98 mg
68 Anal Calcd for C68H64N4O5Zn2CH3CO2H (120813) C 6959 H 464 N 567 Found
S9
C 6999 H 464 N 599 1H NMR (400 MHz DMSO-d6) δ 871 (s 2H H11) 870 (s 2H H6)
832 (d J = 22 Hz 2H H4) 804 (dd J = 76 and 11 Hz 2H H1) 781ndash772 (m 4H H3 H5)
750 (t J = 76 Hz 2H H2) 743 (d J = 76 Hz 2H H10) 737 (d J = 81 Hz 2H H12) 732 (d
J = 79 Hz 2H H7) 727 (d J = 75 Hz 2H H14) 701 (t J = 77 Hz 2H H8) 662 (dd J = 79
and 75 Hz 2H H9) 650 (t J = 75 Hz 2H H13) 185 (s 3H H17) 161 (s 18H H16) 156 (s
18H H15) 13C NMR (151 MHz DMSO-d6) δ 1720 1719 1717 1616 1605 1522 1424
1414 1390 1377 1350 1345 1300 1299 1267 1264 1256 1244 1243 1236 1194
1188 1184 1181 1149 1146 1119 353 350 295 294 210
The yellow crystalline solid (7middotAcOH) was
dissolved in CH2Cl2 (15 mL) and washed with DI
water (20 mL times 3) The organic layer was collected
all volatiles were removed under reduced pressure
and recrystallization from acetonepentane (15)
afforded 7 as an orange solid Yield 62 mg 47
(based on L7) Anal Calcd for C68H64N4O5Zn2
(114808) C 7114 H 562 N 488 Found C 7116
H 579 N 473 1H NMR (400 MHz DMSO-d6) δ
870 (s 2H H11) 869 (s 2H H6) 832 (s 2H H4)
804 (dd J = 77 and 10 Hz 2H H1) 781ndash772 (m 4H H3 H5) 750 (t J = 76 Hz 2H H2)
743 (d J = 81 Hz 2H H10) 737 (d J = 68 Hz 2H H12) 732 (d J = 80 Hz 2H H7) 727 (d
J = 73 Hz 2H H14) 701 (dd J = 77 and 74 Hz 2H H8) 662 (t J = 75 Hz 2H H9) 650 (t J
= 75 Hz 2H H13) 161 (s 18H H16) 155 (s 18H H15) 13C NMR (101 MHz DMSO-d6) δ
1720 1717 1618 1606 1522 1425 1414 1390 1376 1352 1347 1301 1300 1268
1265 1256 1245 1243 1238 1195 1188 1185 1183 1150 1146 1120 354 352
296 295 ESI-MS (+ve mode) mz 1150 [M + H]+
S10
Complex 8 The procedure for the synthesis
of 4 was adopted using L7 (78 mg 015 mmol) A
brown precipitate was formed which was
collected and washed copiously with MeOH and
pentane to afford 8 as a brownish yellow solid
Yield 85 mg 43 Anal Calcd for
C76H80N4O5Zn2(H2O)4 (133235) C 6851 H
666 N 421 Found C 6840 H 688 N 429 1H NMR (400 MHz DMSO-d6) δ 883 (s 2H
H13) 882 (s 2H H20) 813 (d J = 22 Hz 2H H8) 805 (d J = 76 Hz 2H H2) 776 (d J = 23
Hz 2H H12) 771 (d J = 70 Hz 2H H4) 763 (d J = 78 Hz 2H H18) 754ndash745 (m 4H H315)
734 (d J = 25 Hz 2H H25) 724 (d J = 26 Hz 2H H23) 711 (dd J = 76 and 78 Hz 2H
H16) 689 (dd J = 78 and 80 Hz 2H H17) 152 (s 18H H32) 151 (s 18H H30) 132 (s 18H
H28) 13C NMR (151 MHz DMSO-d6 peak assignments based on combination of DEPT-135
and 2-D 1H-1H 13C-1H (HSQC and HMBC) and NOE correlation NMR experiments) δ 1719
(C10) 1702 (C21) 1621 (C20) 1612 (C13) 1523 (C6) 1422 (C11) 1407 (C26) 1392 (C19)
1382 (C14) 1346 (C8) 1331 (C24) 1301 (C12) 1294 (C23) 1281 (C25) 1266 (C17) 1265
(C16) 1258 (C5) 1250 (C4) 1243 (C1) 1236 (C3) 1190 (C9) 1188 (C7) 1181 (C2) 1180
(C22) 1152 (C18) 1151 (C15) 352 (C2931) 335 (C27) 313 (C28) 296 (C30) 294 (C32) ESI-
MS (+ve mode) mz 1264 [M + H]+
S11
Figure S1 1H NMR (400 MHz CDCl3 298 K inset expanded) spectrum of reaction mixture corresponding to Run 10 in Table 3 [reaction conditions 12-epoxybutane (575 mmol 5 mL) catalyst 8 (00025 mol) nBu4NI co-cat (0125 mol) mesitylene (internal standard 1 mol) 10 bar CO2 initial pressure 95 degC 2 h]
Hf
Hc
Hd Hdrsquo
Hcrsquo ampnBu4NI
Ha
Hb1
Hb2
Harsquo
Hbrsquo1
Hbrsquo2
CDCl3
He
S12
Figure S2 1H NMR (400 MHz CDCl3 298 K inset expanded) spectrum of reaction mixture corresponding to Run 12 in Table 3 [reaction conditions 12-epoxyhexane (249 mmol 3 mL) catalyst 8 (00025 mol) nBu4NI co-cat (0125 mol) mesitylene (internal standard 1 mol) 10 bar CO2 initial pressure 95 degC 2 h]
nBu4NI Hf
Hd Hdrsquo
Ha
Hb1
Hb2 Harsquo
Hbrsquo1
Hbrsquo2
CDCl3
He
Hc Hcrsquo
S13
ESI References
1 R Okamura T Wada K Aikawa T Nagata and K Tanaka Inorg Chem 2004 43 7210
2 W-L Tong S-M Yiu and M C W Chan Inorg Chem 2013 52 7114
3 M Hirotsu N Ohno T Nakajima C Kushibe K Ueno and I Kinoshita Dalton Trans 2010 39 139
4 E B Schwartz C B Knobler and D J Cram J Am Chem Soc 1992 114 10775
5 Z Guo S-M Yiu and M C W Chan Chem Eur J 2013 19 8937
S8
13C NMR (101 MHz C6D6DMSO-d6 91) δ 1729 1722 1614 1612 1458 1448 1423
1420 1398 1396 1346 1329 1309 1300 1299 1261 1258 1257 1221 1199 1194
1192 1154 1151 1120 354 353 348 342 314 297 296 ESI-MS (+ve mode) mz
1304 [M + H]+
Complex 6 The procedure for the
synthesis of 5 was adopted using L3 (50 mg
0074 mmol) and L9 (48 mg 015 mmol) A
orange precipitate was formed which was
collected washed copiously with cold MeOH
and recrystallized from CH2Cl2hexane (19)
to afford 6 as a bright yellow solid Yield 46 mg 41 Anal Calcd for C87H102N4O5Zn2(H2O)5
(150466) C 6945 H 750 N 372 Found C 6977 H 736 N 389 1H NMR (400 MHz
DMSO-d6) δ 880 (s 2H H10) 852 (s 2H H5) 768 (d J = 80 Hz 2H H9) 763 (d J = 83 Hz
2H H6) 750 (d J = 23 Hz 2H H3) 745ndash739 (m 4H H1 H4) 720 (d J = 25 Hz 2H H12)
717 (d J = 23 Hz 2H H2) 719ndash712 (m 2H H7) 705 (d J = 26 Hz 2H H11) 707ndash699 (m
2H H8) 173 (s 6H H16) 136 (s 18H H17) 131 (s 18H H14) 124 (s 18H H13) 121 (s 18H
H15) 13C NMR (101 MHz DMSO-d6) δ 1721 1708 1626 1625 1452 1448 1412 1411
1399 1346 1332 1323 1298 1292 1285 1268 1267 1260 1260 1250 1218 1213
1196 1186 1165 1159 356 353 348 346 339 336 319 319 300 298 ESI-MS (+ve
mode) mz 1416 [M + H]+
Complex 7 and 7middotAcOH Compound L7 (60 mg
012 mmol in powder form) and Et3N (3 mL) were
added to a stirred solution of L8 (62 mg 023 mmol)
and Zn(OAc)2middot2H2O (56 mg 025 mmol) in MeOH
(20 mL) at room temperature The reaction mixture
was stirred at room temperature for 20 h to give a grey
solution All volatiles were removed under reduced
pressure and recrystallization from CH2Cl2hexane
(19) afforded a yellow crystalline solid which was characterized as 7middotAcOH Yield 98 mg
68 Anal Calcd for C68H64N4O5Zn2CH3CO2H (120813) C 6959 H 464 N 567 Found
S9
C 6999 H 464 N 599 1H NMR (400 MHz DMSO-d6) δ 871 (s 2H H11) 870 (s 2H H6)
832 (d J = 22 Hz 2H H4) 804 (dd J = 76 and 11 Hz 2H H1) 781ndash772 (m 4H H3 H5)
750 (t J = 76 Hz 2H H2) 743 (d J = 76 Hz 2H H10) 737 (d J = 81 Hz 2H H12) 732 (d
J = 79 Hz 2H H7) 727 (d J = 75 Hz 2H H14) 701 (t J = 77 Hz 2H H8) 662 (dd J = 79
and 75 Hz 2H H9) 650 (t J = 75 Hz 2H H13) 185 (s 3H H17) 161 (s 18H H16) 156 (s
18H H15) 13C NMR (151 MHz DMSO-d6) δ 1720 1719 1717 1616 1605 1522 1424
1414 1390 1377 1350 1345 1300 1299 1267 1264 1256 1244 1243 1236 1194
1188 1184 1181 1149 1146 1119 353 350 295 294 210
The yellow crystalline solid (7middotAcOH) was
dissolved in CH2Cl2 (15 mL) and washed with DI
water (20 mL times 3) The organic layer was collected
all volatiles were removed under reduced pressure
and recrystallization from acetonepentane (15)
afforded 7 as an orange solid Yield 62 mg 47
(based on L7) Anal Calcd for C68H64N4O5Zn2
(114808) C 7114 H 562 N 488 Found C 7116
H 579 N 473 1H NMR (400 MHz DMSO-d6) δ
870 (s 2H H11) 869 (s 2H H6) 832 (s 2H H4)
804 (dd J = 77 and 10 Hz 2H H1) 781ndash772 (m 4H H3 H5) 750 (t J = 76 Hz 2H H2)
743 (d J = 81 Hz 2H H10) 737 (d J = 68 Hz 2H H12) 732 (d J = 80 Hz 2H H7) 727 (d
J = 73 Hz 2H H14) 701 (dd J = 77 and 74 Hz 2H H8) 662 (t J = 75 Hz 2H H9) 650 (t J
= 75 Hz 2H H13) 161 (s 18H H16) 155 (s 18H H15) 13C NMR (101 MHz DMSO-d6) δ
1720 1717 1618 1606 1522 1425 1414 1390 1376 1352 1347 1301 1300 1268
1265 1256 1245 1243 1238 1195 1188 1185 1183 1150 1146 1120 354 352
296 295 ESI-MS (+ve mode) mz 1150 [M + H]+
S10
Complex 8 The procedure for the synthesis
of 4 was adopted using L7 (78 mg 015 mmol) A
brown precipitate was formed which was
collected and washed copiously with MeOH and
pentane to afford 8 as a brownish yellow solid
Yield 85 mg 43 Anal Calcd for
C76H80N4O5Zn2(H2O)4 (133235) C 6851 H
666 N 421 Found C 6840 H 688 N 429 1H NMR (400 MHz DMSO-d6) δ 883 (s 2H
H13) 882 (s 2H H20) 813 (d J = 22 Hz 2H H8) 805 (d J = 76 Hz 2H H2) 776 (d J = 23
Hz 2H H12) 771 (d J = 70 Hz 2H H4) 763 (d J = 78 Hz 2H H18) 754ndash745 (m 4H H315)
734 (d J = 25 Hz 2H H25) 724 (d J = 26 Hz 2H H23) 711 (dd J = 76 and 78 Hz 2H
H16) 689 (dd J = 78 and 80 Hz 2H H17) 152 (s 18H H32) 151 (s 18H H30) 132 (s 18H
H28) 13C NMR (151 MHz DMSO-d6 peak assignments based on combination of DEPT-135
and 2-D 1H-1H 13C-1H (HSQC and HMBC) and NOE correlation NMR experiments) δ 1719
(C10) 1702 (C21) 1621 (C20) 1612 (C13) 1523 (C6) 1422 (C11) 1407 (C26) 1392 (C19)
1382 (C14) 1346 (C8) 1331 (C24) 1301 (C12) 1294 (C23) 1281 (C25) 1266 (C17) 1265
(C16) 1258 (C5) 1250 (C4) 1243 (C1) 1236 (C3) 1190 (C9) 1188 (C7) 1181 (C2) 1180
(C22) 1152 (C18) 1151 (C15) 352 (C2931) 335 (C27) 313 (C28) 296 (C30) 294 (C32) ESI-
MS (+ve mode) mz 1264 [M + H]+
S11
Figure S1 1H NMR (400 MHz CDCl3 298 K inset expanded) spectrum of reaction mixture corresponding to Run 10 in Table 3 [reaction conditions 12-epoxybutane (575 mmol 5 mL) catalyst 8 (00025 mol) nBu4NI co-cat (0125 mol) mesitylene (internal standard 1 mol) 10 bar CO2 initial pressure 95 degC 2 h]
Hf
Hc
Hd Hdrsquo
Hcrsquo ampnBu4NI
Ha
Hb1
Hb2
Harsquo
Hbrsquo1
Hbrsquo2
CDCl3
He
S12
Figure S2 1H NMR (400 MHz CDCl3 298 K inset expanded) spectrum of reaction mixture corresponding to Run 12 in Table 3 [reaction conditions 12-epoxyhexane (249 mmol 3 mL) catalyst 8 (00025 mol) nBu4NI co-cat (0125 mol) mesitylene (internal standard 1 mol) 10 bar CO2 initial pressure 95 degC 2 h]
nBu4NI Hf
Hd Hdrsquo
Ha
Hb1
Hb2 Harsquo
Hbrsquo1
Hbrsquo2
CDCl3
He
Hc Hcrsquo
S13
ESI References
1 R Okamura T Wada K Aikawa T Nagata and K Tanaka Inorg Chem 2004 43 7210
2 W-L Tong S-M Yiu and M C W Chan Inorg Chem 2013 52 7114
3 M Hirotsu N Ohno T Nakajima C Kushibe K Ueno and I Kinoshita Dalton Trans 2010 39 139
4 E B Schwartz C B Knobler and D J Cram J Am Chem Soc 1992 114 10775
5 Z Guo S-M Yiu and M C W Chan Chem Eur J 2013 19 8937
S9
C 6999 H 464 N 599 1H NMR (400 MHz DMSO-d6) δ 871 (s 2H H11) 870 (s 2H H6)
832 (d J = 22 Hz 2H H4) 804 (dd J = 76 and 11 Hz 2H H1) 781ndash772 (m 4H H3 H5)
750 (t J = 76 Hz 2H H2) 743 (d J = 76 Hz 2H H10) 737 (d J = 81 Hz 2H H12) 732 (d
J = 79 Hz 2H H7) 727 (d J = 75 Hz 2H H14) 701 (t J = 77 Hz 2H H8) 662 (dd J = 79
and 75 Hz 2H H9) 650 (t J = 75 Hz 2H H13) 185 (s 3H H17) 161 (s 18H H16) 156 (s
18H H15) 13C NMR (151 MHz DMSO-d6) δ 1720 1719 1717 1616 1605 1522 1424
1414 1390 1377 1350 1345 1300 1299 1267 1264 1256 1244 1243 1236 1194
1188 1184 1181 1149 1146 1119 353 350 295 294 210
The yellow crystalline solid (7middotAcOH) was
dissolved in CH2Cl2 (15 mL) and washed with DI
water (20 mL times 3) The organic layer was collected
all volatiles were removed under reduced pressure
and recrystallization from acetonepentane (15)
afforded 7 as an orange solid Yield 62 mg 47
(based on L7) Anal Calcd for C68H64N4O5Zn2
(114808) C 7114 H 562 N 488 Found C 7116
H 579 N 473 1H NMR (400 MHz DMSO-d6) δ
870 (s 2H H11) 869 (s 2H H6) 832 (s 2H H4)
804 (dd J = 77 and 10 Hz 2H H1) 781ndash772 (m 4H H3 H5) 750 (t J = 76 Hz 2H H2)
743 (d J = 81 Hz 2H H10) 737 (d J = 68 Hz 2H H12) 732 (d J = 80 Hz 2H H7) 727 (d
J = 73 Hz 2H H14) 701 (dd J = 77 and 74 Hz 2H H8) 662 (t J = 75 Hz 2H H9) 650 (t J
= 75 Hz 2H H13) 161 (s 18H H16) 155 (s 18H H15) 13C NMR (101 MHz DMSO-d6) δ
1720 1717 1618 1606 1522 1425 1414 1390 1376 1352 1347 1301 1300 1268
1265 1256 1245 1243 1238 1195 1188 1185 1183 1150 1146 1120 354 352
296 295 ESI-MS (+ve mode) mz 1150 [M + H]+
S10
Complex 8 The procedure for the synthesis
of 4 was adopted using L7 (78 mg 015 mmol) A
brown precipitate was formed which was
collected and washed copiously with MeOH and
pentane to afford 8 as a brownish yellow solid
Yield 85 mg 43 Anal Calcd for
C76H80N4O5Zn2(H2O)4 (133235) C 6851 H
666 N 421 Found C 6840 H 688 N 429 1H NMR (400 MHz DMSO-d6) δ 883 (s 2H
H13) 882 (s 2H H20) 813 (d J = 22 Hz 2H H8) 805 (d J = 76 Hz 2H H2) 776 (d J = 23
Hz 2H H12) 771 (d J = 70 Hz 2H H4) 763 (d J = 78 Hz 2H H18) 754ndash745 (m 4H H315)
734 (d J = 25 Hz 2H H25) 724 (d J = 26 Hz 2H H23) 711 (dd J = 76 and 78 Hz 2H
H16) 689 (dd J = 78 and 80 Hz 2H H17) 152 (s 18H H32) 151 (s 18H H30) 132 (s 18H
H28) 13C NMR (151 MHz DMSO-d6 peak assignments based on combination of DEPT-135
and 2-D 1H-1H 13C-1H (HSQC and HMBC) and NOE correlation NMR experiments) δ 1719
(C10) 1702 (C21) 1621 (C20) 1612 (C13) 1523 (C6) 1422 (C11) 1407 (C26) 1392 (C19)
1382 (C14) 1346 (C8) 1331 (C24) 1301 (C12) 1294 (C23) 1281 (C25) 1266 (C17) 1265
(C16) 1258 (C5) 1250 (C4) 1243 (C1) 1236 (C3) 1190 (C9) 1188 (C7) 1181 (C2) 1180
(C22) 1152 (C18) 1151 (C15) 352 (C2931) 335 (C27) 313 (C28) 296 (C30) 294 (C32) ESI-
MS (+ve mode) mz 1264 [M + H]+
S11
Figure S1 1H NMR (400 MHz CDCl3 298 K inset expanded) spectrum of reaction mixture corresponding to Run 10 in Table 3 [reaction conditions 12-epoxybutane (575 mmol 5 mL) catalyst 8 (00025 mol) nBu4NI co-cat (0125 mol) mesitylene (internal standard 1 mol) 10 bar CO2 initial pressure 95 degC 2 h]
Hf
Hc
Hd Hdrsquo
Hcrsquo ampnBu4NI
Ha
Hb1
Hb2
Harsquo
Hbrsquo1
Hbrsquo2
CDCl3
He
S12
Figure S2 1H NMR (400 MHz CDCl3 298 K inset expanded) spectrum of reaction mixture corresponding to Run 12 in Table 3 [reaction conditions 12-epoxyhexane (249 mmol 3 mL) catalyst 8 (00025 mol) nBu4NI co-cat (0125 mol) mesitylene (internal standard 1 mol) 10 bar CO2 initial pressure 95 degC 2 h]
nBu4NI Hf
Hd Hdrsquo
Ha
Hb1
Hb2 Harsquo
Hbrsquo1
Hbrsquo2
CDCl3
He
Hc Hcrsquo
S13
ESI References
1 R Okamura T Wada K Aikawa T Nagata and K Tanaka Inorg Chem 2004 43 7210
2 W-L Tong S-M Yiu and M C W Chan Inorg Chem 2013 52 7114
3 M Hirotsu N Ohno T Nakajima C Kushibe K Ueno and I Kinoshita Dalton Trans 2010 39 139
4 E B Schwartz C B Knobler and D J Cram J Am Chem Soc 1992 114 10775
5 Z Guo S-M Yiu and M C W Chan Chem Eur J 2013 19 8937
S10
Complex 8 The procedure for the synthesis
of 4 was adopted using L7 (78 mg 015 mmol) A
brown precipitate was formed which was
collected and washed copiously with MeOH and
pentane to afford 8 as a brownish yellow solid
Yield 85 mg 43 Anal Calcd for
C76H80N4O5Zn2(H2O)4 (133235) C 6851 H
666 N 421 Found C 6840 H 688 N 429 1H NMR (400 MHz DMSO-d6) δ 883 (s 2H
H13) 882 (s 2H H20) 813 (d J = 22 Hz 2H H8) 805 (d J = 76 Hz 2H H2) 776 (d J = 23
Hz 2H H12) 771 (d J = 70 Hz 2H H4) 763 (d J = 78 Hz 2H H18) 754ndash745 (m 4H H315)
734 (d J = 25 Hz 2H H25) 724 (d J = 26 Hz 2H H23) 711 (dd J = 76 and 78 Hz 2H
H16) 689 (dd J = 78 and 80 Hz 2H H17) 152 (s 18H H32) 151 (s 18H H30) 132 (s 18H
H28) 13C NMR (151 MHz DMSO-d6 peak assignments based on combination of DEPT-135
and 2-D 1H-1H 13C-1H (HSQC and HMBC) and NOE correlation NMR experiments) δ 1719
(C10) 1702 (C21) 1621 (C20) 1612 (C13) 1523 (C6) 1422 (C11) 1407 (C26) 1392 (C19)
1382 (C14) 1346 (C8) 1331 (C24) 1301 (C12) 1294 (C23) 1281 (C25) 1266 (C17) 1265
(C16) 1258 (C5) 1250 (C4) 1243 (C1) 1236 (C3) 1190 (C9) 1188 (C7) 1181 (C2) 1180
(C22) 1152 (C18) 1151 (C15) 352 (C2931) 335 (C27) 313 (C28) 296 (C30) 294 (C32) ESI-
MS (+ve mode) mz 1264 [M + H]+
S11
Figure S1 1H NMR (400 MHz CDCl3 298 K inset expanded) spectrum of reaction mixture corresponding to Run 10 in Table 3 [reaction conditions 12-epoxybutane (575 mmol 5 mL) catalyst 8 (00025 mol) nBu4NI co-cat (0125 mol) mesitylene (internal standard 1 mol) 10 bar CO2 initial pressure 95 degC 2 h]
Hf
Hc
Hd Hdrsquo
Hcrsquo ampnBu4NI
Ha
Hb1
Hb2
Harsquo
Hbrsquo1
Hbrsquo2
CDCl3
He
S12
Figure S2 1H NMR (400 MHz CDCl3 298 K inset expanded) spectrum of reaction mixture corresponding to Run 12 in Table 3 [reaction conditions 12-epoxyhexane (249 mmol 3 mL) catalyst 8 (00025 mol) nBu4NI co-cat (0125 mol) mesitylene (internal standard 1 mol) 10 bar CO2 initial pressure 95 degC 2 h]
nBu4NI Hf
Hd Hdrsquo
Ha
Hb1
Hb2 Harsquo
Hbrsquo1
Hbrsquo2
CDCl3
He
Hc Hcrsquo
S13
ESI References
1 R Okamura T Wada K Aikawa T Nagata and K Tanaka Inorg Chem 2004 43 7210
2 W-L Tong S-M Yiu and M C W Chan Inorg Chem 2013 52 7114
3 M Hirotsu N Ohno T Nakajima C Kushibe K Ueno and I Kinoshita Dalton Trans 2010 39 139
4 E B Schwartz C B Knobler and D J Cram J Am Chem Soc 1992 114 10775
5 Z Guo S-M Yiu and M C W Chan Chem Eur J 2013 19 8937
S11
Figure S1 1H NMR (400 MHz CDCl3 298 K inset expanded) spectrum of reaction mixture corresponding to Run 10 in Table 3 [reaction conditions 12-epoxybutane (575 mmol 5 mL) catalyst 8 (00025 mol) nBu4NI co-cat (0125 mol) mesitylene (internal standard 1 mol) 10 bar CO2 initial pressure 95 degC 2 h]
Hf
Hc
Hd Hdrsquo
Hcrsquo ampnBu4NI
Ha
Hb1
Hb2
Harsquo
Hbrsquo1
Hbrsquo2
CDCl3
He
S12
Figure S2 1H NMR (400 MHz CDCl3 298 K inset expanded) spectrum of reaction mixture corresponding to Run 12 in Table 3 [reaction conditions 12-epoxyhexane (249 mmol 3 mL) catalyst 8 (00025 mol) nBu4NI co-cat (0125 mol) mesitylene (internal standard 1 mol) 10 bar CO2 initial pressure 95 degC 2 h]
nBu4NI Hf
Hd Hdrsquo
Ha
Hb1
Hb2 Harsquo
Hbrsquo1
Hbrsquo2
CDCl3
He
Hc Hcrsquo
S13
ESI References
1 R Okamura T Wada K Aikawa T Nagata and K Tanaka Inorg Chem 2004 43 7210
2 W-L Tong S-M Yiu and M C W Chan Inorg Chem 2013 52 7114
3 M Hirotsu N Ohno T Nakajima C Kushibe K Ueno and I Kinoshita Dalton Trans 2010 39 139
4 E B Schwartz C B Knobler and D J Cram J Am Chem Soc 1992 114 10775
5 Z Guo S-M Yiu and M C W Chan Chem Eur J 2013 19 8937
S12
Figure S2 1H NMR (400 MHz CDCl3 298 K inset expanded) spectrum of reaction mixture corresponding to Run 12 in Table 3 [reaction conditions 12-epoxyhexane (249 mmol 3 mL) catalyst 8 (00025 mol) nBu4NI co-cat (0125 mol) mesitylene (internal standard 1 mol) 10 bar CO2 initial pressure 95 degC 2 h]
nBu4NI Hf
Hd Hdrsquo
Ha
Hb1
Hb2 Harsquo
Hbrsquo1
Hbrsquo2
CDCl3
He
Hc Hcrsquo
S13
ESI References
1 R Okamura T Wada K Aikawa T Nagata and K Tanaka Inorg Chem 2004 43 7210
2 W-L Tong S-M Yiu and M C W Chan Inorg Chem 2013 52 7114
3 M Hirotsu N Ohno T Nakajima C Kushibe K Ueno and I Kinoshita Dalton Trans 2010 39 139
4 E B Schwartz C B Knobler and D J Cram J Am Chem Soc 1992 114 10775
5 Z Guo S-M Yiu and M C W Chan Chem Eur J 2013 19 8937
S13
ESI References
1 R Okamura T Wada K Aikawa T Nagata and K Tanaka Inorg Chem 2004 43 7210
2 W-L Tong S-M Yiu and M C W Chan Inorg Chem 2013 52 7114
3 M Hirotsu N Ohno T Nakajima C Kushibe K Ueno and I Kinoshita Dalton Trans 2010 39 139
4 E B Schwartz C B Knobler and D J Cram J Am Chem Soc 1992 114 10775
5 Z Guo S-M Yiu and M C W Chan Chem Eur J 2013 19 8937