Table 3 Molecular Geometrya of Triphenylsilane: Comparison of Experimental and Theoretical

Molecular structure and conformation of triphenylsilane from gas-phase electron diffraction and theoretical calculations, and structural variations in H4nSiPhn molecules (n = 14)

Anna Rita Campanelli · Aldo Domenicano · Fabio Ramondo · István Hargittai

SUPPLEMENTARY MATERIAL

Table S1 Equilibrium molecular geometrya,b of phenylsilane from MO calculations
Parameterc / Basis set 6-31G* / Basis set 6-311++G**
HF / B3LYP / HF / B3LYP
r(SiC) / 1.8817 / 1.8798 / 1.8824 / 1.8826
r(SiHA) / 1.4783 / 1.4903 / 1.4803 / 1.4881
r(SiHB) / 1.4766 / 1.4884 / 1.4789 / 1.4862
r(C1C2) / 1.3957 / 1.4063 / 1.3952 / 1.4041
r(C2C3) / 1.3853 / 1.3956 / 1.3856 / 1.3938
r(C3C4) / 1.3855 / 1.3960 / 1.3853 / 1.3939
r(C2H2) / 1.0768 / 1.0881 / 1.0770 / 1.0858
r(C3H3) / 1.0756 / 1.0870 / 1.0757 / 1.0846
r(C4H4) / 1.0756 / 1.0870 / 1.0757 / 1.0844
C1SiHA / 111.78 / 112.02 / 111.35 / 111.39
C1SiHB / 109.78 / 109.96 / 109.65 / 109.76
HASiHB / 107.99 / 107.76 / 108.20 / 108.11
HBSiHC / 109.47 / 109.30 / 109.75 / 109.68
SiC1C2 / 121.08 / 121.03 / 121.08 / 121.02
C2C1C6 / 117.85 / 117.94 / 117.84 / 117.96
C1C2C3 / 121.22 / 121.13 / 121.23 / 121.11
C2C3C4 / 119.94 / 120.00 / 119.96 / 120.03
C3C4C5 / 119.83 / 119.78 / 119.79 / 119.74
C1C2H2 / 119.95 / 119.91 / 119.98 / 119.96
Table S1, continued
C3C2H2 / 118.83 / 118.96 / 118.79 / 118.93
C2C3H3 / 119.95 / 119.91 / 119.94 / 119.89
C4C3H3 / 120.11 / 120.09 / 120.10 / 120.07
C3C4H4 / 120.08 / 120.11 / 120.10 / 120.13
a The molecule has Cs symmetry in its equilibrium conformation, with the symmetry plane perpendicular to the plane of the benzene ring. b Bond distances are given in Å, angles in degrees. c The ring atoms are numbered as in Fig. 4 of Ref. [4]. Atom HA lies in the symmetry plane, while HB and HC are mirror images of each other.
Table S2 Equilibrium molecular geometry of diphenylsilane from MO calculationsa,b
Parameterc / Basis set 6-31G* / Basis set 6-311++G**
HF / B3LYP / HF / B3LYP
r(SiC) / 1.8841 / 1.8822 / 1.8843 / 1.8851
r(SiH) / 1.4788 / 1.4918 / 1.4811 / 1.4890
r(C1C2) / 1.3951 / 1.4063 / 1.3942 / 1.4037
r(C2C3) / 1.3867 / 1.3962 / 1.3875 / 1.3949
r(C3C4) / 1.3843 / 1.3955 / 1.3837 / 1.3931
r(C4C5) / 1.3868 / 1.3967 / 1.3872 / 1. 3949
r(C5C6) / 1.3842 / 1.3951 / 1.3838 / 1. 3930
r(C1C6) / 1.3973 / 1.4074 / 1.3971 / 1.4050
r(C2H2) / 1.0764 / 1.0879 / 1.0767 / 1.0856
r(C3H3) / 1.0756 / 1.0871 / 1.0757 / 1.0846
r(C4H4) / 1.0757 / 1.0870 / 1.0758 / 1.0845
r(C5H5) / 1.0756 / 1.0871 / 1.0757 / 1.0846
r(C6H6) / 1.0765 / 1.0880 / 1.0770 / 1.0858
C1ASiC1B / 111.99 / 112.15 / 112.19 / 112.20
C1ASiHC / 107.24 / 107.10 / 107.18 / 107.15
C1ASiHD / 111.33 / 111.58 / 110.98 / 111.05
HCSiHD / 107.65 / 107.27 / 108.31 / 108.21
SiC1C2 / 120.72 / 120.68 / 120.75 / 120.76
SiC1C6 / 121.50 / 121.46 / 121.46 / 121.31
Table S2, continued
C2C1C6 / 117.78 / 117.85 / 117.77 / 117.92
C1C2C3 / 121.28 / 121.21 / 121.28 / 121.16
C2C3C4 / 119.91 / 119.97 / 119.92 / 119.99
C3C4C5 / 119.84 / 119.79 / 119.80 / 119.76
C4C5C6 / 119.96 / 120.01 / 119.97 / 120.04
C1C6C5 / 121.24 / 121.17 / 121.25 / 121.13
C1C2H2 / 119.85 / 119.73 / 119.89 / 119.79
C3C2H2 / 118.87 / 119.07 / 118.83 / 119.06
C2C3H3 / 119.96 / 119.93 / 119.94 / 119.92
C4C3H3 / 120.13 / 120.10 / 120.14 / 120.09
C3C4H4 / 120.10 / 120.12 / 120.13 / 120.13
C5C4H4 / 120.06 / 120.10 / 120.07 / 120.10
C4C5H5 / 120.07 / 120.07 / 120.07 / 120.04
C6C5H5 / 119.97 / 119.93 / 119.96 / 119.93
C5C6H6 / 118.88 / 119.00 / 118.81 / 118.95
C1C6H6 / 119.88 / 119.82 / 119.94 / 119.92
d / 44.2 / 43.2 / 47.9 / 47.7
a The molecule has C2 symmetry in its equilibrium conformation. b Bond distances are given in Å, angles in degrees. c Atoms are labeled as in tetraphenylsilane, see Fig. 1 of Ref. [1], with atoms HC and HD replacing rings C and D, respectively. dDefined as the dihedral angle between the least-squares plane through the carbon atoms of the benzene ring and the plane defined by the SiC bond and the C2 axis.
Table S3 Equilibrium molecular geometry of triphenylsilane from MO calculationsa,b
Parameterc / Basis set 6-31G* / Basis set 6-311++G**
HF / B3LYP / HF / B3LYP
r(SiC) / 1.8883 / 1.8865 / 1.8882 / 1.8892
r(SiH) / 1.4791 / 1.4920 / 1.4820 / 1.4901
r(C1C2) / 1.3951 / 1.4065 / 1.3943 / 1.4036
r(C2C3) / 1.3871 / 1.3965 / 1.3875 / 1.3951
r(C3C4) / 1.3843 / 1.3956 / 1.3840 / 1.3933
r(C4C5) / 1.3868 / 1.3966 / 1.3868 / 1. 3948
r(C5C6) / 1.3840 / 1.3951 / 1.3843 / 1. 3932
r(C1C6) / 1.3979 / 1.4075 / 1.3973 / 1.4053
r(C2H2) / 1.0757 / 1.0877 / 1.0760 / 1.0852
r(C3H3) / 1.0757 / 1.0872 / 1.0758 / 1.0847
r(C4H4) / 1.0757 / 1.0871 / 1.0758 / 1.0845
r(C5H5) / 1.0757 / 1.0872 / 1.0758 / 1.0847
r(C6H6) / 1.0771 / 1.0884 / 1.0774 / 1.0861
C1ASiC1B / 110.98 / 110.79 / 110.90 / 110.67
C1ASiH / 107.91 / 108.12 / 108.00 / 108.24
SiC1C2 / 122.33 / 121.92 / 122.40 / 121.95
SiC1C6 / 119.97 / 120.28 / 119.90 / 120.18
C2C1C6 / 117.70 / 117.78 / 117.70 / 117.86
C1C2C3 / 121.23 / 121.20 / 121.24 / 121.14
Table S3, continued
C2C3C4 / 120.01 / 120.02 / 120.02 / 120.06
C3C4C5 / 119.81 / 119.76 / 119.77 / 119.73
C4C5C6 / 119.89 / 119.97 / 119.89 / 119.98
C1C6C5 / 121.37 / 121.26 / 121.38 / 121.22
C1C2H2 / 119.86 / 119.71 / 119.91 / 119.78
C3C2H2 / 118.91 / 119.09 / 118.85 / 119.08
C2C3H3 / 119.89 / 119.90 / 119.87 / 119.88
C4C3H3 / 120.10 / 120.08 / 120.11 / 120.06
C3C4H4 / 120.12 / 120.14 / 120.14 / 120.16
C5C4H4 / 120.07 / 120.10 / 120.09 / 120.11
C4C5H5 / 120.10 / 120.08 / 120.12 / 120.07
C6C5H5 / 120.01 / 119.95 / 119.99 / 119.95
C5C6H6 / 118.79 / 118.94 / 118.73 / 118.90
C1C6H6 / 119.84 / 119.80 / 119.89 / 119.88
d / 41.6 / 35.9 / 41.9 / 40.7
a The molecule has C3 symmetry in its equilibrium conformation. b Bond distances are given in Å, angles in degrees. c Atoms are labeled according to Fig. 1. dDefined as the dihedral angle between the least-squares plane through the carbon atoms of the benzene ring and the plane defined by the SiC bond and the C3 axis.
Table S4 Equilibrium molecular geometry of tetraphenylsilane from MO calculationsa,b
Parameterc / Basis set 6-31G* / Basis set 6-311++G**
HF / B3LYP / HF / B3LYP
r(SiC) / 1.8966 / 1.8941 / 1.8963 / 1.8961
r(C1C2) / 1.3960 / 1.4069 / 1.3949 / 1.4041
r(C2C3) / 1.3867 / 1.3962 / 1.3875 / 1.3949
r(C3C4) / 1.3843 / 1.3956 / 1.3836 / 1.3932
r(C4C5) / 1.3861 / 1.3961 / 1.3865 / 1. 3943
r(C5C6) / 1.3849 / 1.3960 / 1.3844 / 1. 3938
r(C1C6) / 1.3989 / 1.4088 / 1.3984 / 1.4062
r(C2H2) / 1.0749 / 1.0871 / 1.0751 / 1.0847
r(C3H3) / 1.0757 / 1.0872 / 1.0758 / 1.0847
r(C4H4) / 1.0757 / 1.0871 / 1.0758 / 1.0846
r(C5H5) / 1.0758 / 1.0872 / 1.0758 / 1.0848
r(C6H6) / 1.0762 / 1.0878 / 1.0767 / 1.0857
C1ASiC1B / 108.16 / 108.64 / 107.90 / 108.20
C1ASiC1C / 110.13 / 109.89 / 110.26 / 110.11
SiC1C2 / 121.90 / 121.53 / 122.16 / 121.90
SiC1C6 / 120.71 / 120.91 / 120.46 / 120.47
C2C1C6 / 117.38 / 117.54 / 117.38 / 117.62
C1C2C3 / 121.42 / 121.34 / 121.43 / 121.28
C2C3C4 / 120.07 / 120.08 / 120.07 / 120.10
Table S4, continued
C3C4C5 / 119.67 / 119.67 / 119.64 / 119.64
C4C5C6 / 119.96 / 120.01 / 119.96 / 120.03
C1C6C5 / 121.50 / 121.36 / 121.53 / 121.33
C1C2H2 / 119.89 / 119.65 / 119.99 / 119.79
C3C2H2 / 118.69 / 119.01 / 118.59 / 118.92
C2C3H3 / 119.84 / 119.85 / 119.81 / 119.83
C4C3H3 / 120.09 / 120.07 / 120.12 / 120.07
C3C4H4 / 120.18 / 120.18 / 120.21 / 120.20
C5C4H4 / 120.14 / 120.15 / 120.16 / 120.16
C4C5H5 / 120.13 / 120.10 / 120.13 / 120.07
C6C5H5 / 119.92 / 119.89 / 119.92 / 119.90
C5C6H6 / 118.66 / 118.85 / 118.57 / 118.81
C1C6H6 / 119.84 / 119.78 / 119.89 / 119.86
d / 40.4 / 38.9 / 42.5 / 41.8
a The molecule has S4 symmetry in its equilibrium conformation. b Bond distances are given in Å, angles in degrees. c Atoms are labeled according to Fig. 1 of Ref. [1]. dDefined as the dihedral angle between the least-squares plane through the carbon atoms of the benzene ring and the plane defined by the SiC bond and the S4 axis.
Table S5 Distances and mean amplitudes of vibration for conformation-dependent CC pairs in triphenylsilane, from electron diffraction
Atom paira / ra (Å)b / l (Å)
Experimentalc / Calculatedd
C1AC1B / 3.073 / 0.112(5)e / 0.110
C1AC2B / 3.341 / 0.225 / 0.223
C1AC3B / 4.710 / 0.218 / 0.216
C1AC4B / 5.628 / 0.166 / 0.164
C1AC5B / 5.481 / 0.141 / 0.139
C1AC6B / 4.360 / 0.141 / 0.139
C2AC1B / 3.977 / 0.308 / 0.306
C2AC2B / 3.968 / 0.489 / 0.487
C2AC3B / 5.293 / 0.533 / 0.531
C2AC4B / 6.370 / 0.465 / 0.463
C2AC5B / 6.384 / 0.354 / 0.352
C2AC6B / 5.335 / 0.269 / 0.267
C3AC1B / 5.181 / 0.288 / 0.286
C3AC2B / 4.955 / 0.488 / 0.486
C3AC3B / 6.178 / 0.564 / 0.562
C3AC4B / 7.372 / 0.489 / 0.487
C3AC5B / 7.535 / 0.358 / 0.356
C3AC6B / 6.567 / 0.260 / 0.258
Table S5, continued
C4AC1B / 5.628 / 0.210 / 0.208
C4AC2B / 5.376 / 0.404 / 0.402
C4AC3B / 6.531 / 0.460 / 0.458
C4AC4B / 7.710 / 0.381 / 0.379
C4AC5B / 7.897 / 0.309 / 0.307
C4AC6B / 6.970 / 0.256 / 0.254
C5AC1B / 5.038 / 0.294 / 0.292
C5AC2B / 4.936 / 0.535 / 0.533
C5AC3B / 6.074 / 0.594 / 0.592
C5AC4B / 7.119 / 0.512 / 0.510
C5AC5B / 7.198 / 0.462 / 0.460
C5AC6B / 6.266 / 0.400 / 0.398
C6AC1B / 3.789 / 0.331 / 0.329
C6AC2B / 3.944 / 0.552 / 0.550
C6AC3B / 5.171 / 0.582 / 0.580
C6AC4B / 6.075 / 0.508 / 0.506
C6AC5B / 5.983 / 0.465 / 0.463
C6AC6B / 4.960 / 0.415 / 0.413
a The multiplicity is 3 for all CC pairs. b All distances are dependent parameters. c The amplitudes have been refined in a single group, including also conformation-dependent CH pairs, with constant differences between them. d From spectroscopic calculations based on the B3LYP/6-31G* force field. e The least-squares standard deviation is in parentheses in units of the last digit.

Table S6 Total experimental electron diffraction intensities of triphenylsilane, IT(s)

Part 1: 50 cm camera distance (2.000 s 14.000 Å1, with s = 0.125 Å1; the Table develops horizontally)

.32768

.31669

.31860

.32965

.35080

.37492

.39159

.39893

.39925

.39476

.38545

.37547

.36426

.35344

.34395

.33747

.33711

.34315

.35788

.37887

.40542

.43581

.46448

.48907

.50490

.51123

.50956

.50503

.50076

.49762

.49345

.48765

.47765

.46580

.45349

.44185

.43020

.41934

.40768

.39569

.38358

.37228

.36296

.35552

.35069

.34858

.34684

.34634

.34553

.34372

.34137

.33909

.33741

.33835

.34116

.34671

.35301

.35919

.36434

.36724

.36741

.36497

.36142

.35599

.35099

.34668

.34499

.34503

.34698

.34885

.35139

.35323

.35315

.35093

.34688

.34085

.33401

.32695

.31880

.31267

.30723

.30272

.30049

.29835

. 29765

.29831

.29938

.30258

.30706

.31286

.31955

.32655

.33279

.33759

.34061

.34119

.33994

Table S6, continued

Part 2: 19 cm camera distance (8.50 s 35.00 Å1, with s = 0. 25 Å1; the Table develops horizontally)

.56840

.56387

.57225

.58103

.57641

.55791

.53409

.51750

.51278

.51380

.50945

.49426

.46908

.44158

.41881

.40317

.39465

.39393

.40140

.41596

.43138

.43937

.43459

.42204

.40678

.39512

.38833

.38419

.37903

.37356

.36755

.36205

.35598

.34924

.34274

.33994

.34093

.34497

.35049

.35606

.35770

.35554

.35036

.34319

.33639

.33041

.32758

.32492

.32256

.32065

.31902

.31692

.31508

.31257

.31064

.30994

.31063

.31197

.31360

.31465

. 31469

.31359

.31183

.30968

.30631

.30188

.29793

.29437

.29266

.29212

.29185

.29301

. 29380

.29480

.29584

.29591

.29564

.29509

.29415

.29346

.29319

.29215

. 29097

.28950

.28787

.28654

.28491

.28432

.28407

.28444

.28531

.28595

.28684

.28720

.28715

28703

.28606

.28509

.28443

.28392

.28396

.28373

.28334

.28331

.28283

.28277

.28269