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All results from a given calculation for Si2H6 (disilane)

using model chemistry: B1B95/6-311G*

19 10 17 12 22

States and conformations

State Conformation minimum conformation conformer description state description
1 1 yes D3D 1A1g
Energy calculated at B1B95/6-311G*
 hartrees
Energy at 0K-582.623600
Energy at 298.15K-582.629445
HF Energy-582.623600
Nuclear repulsion energy90.835569
The energy at 298.15K was derived from the energy at 0K and an integrated heat capacity that used the calculated vibrational frequencies.
Vibrational Frequencies calculated at B1B95/6-311G*
Mode Number Symmetry Frequency
(cm-1)		 Scaled Frequency
(cm-1)		 IR Intensities
(km mol-1)		 Raman Act
4/u)		 Dep P Dep U
1 A1g 2228 2135 0.00      
2 A1g 914 876 0.00      
3 A1g 432 414 0.00      
4 A1u 146 140 0.00      
5 A2u 2220 2128 110.92      
6 A2u 840 805 508.76      
7 Eg 2231 2139 0.00      
7 Eg 2231 2139 0.00      
8 Eg 936 897 0.00      
8 Eg 936 897 0.00      
9 Eg 632 606 0.00      
9 Eg 632 606 0.00      
10 Eu 2241 2148 190.03      
10 Eu 2241 2148 190.06      
11 Eu 949 910 83.48      
11 Eu 949 910 83.49      
12 Eu 381 365 24.14      
12 Eu 381 365 24.14      

Unscaled Zero Point Vibrational Energy (zpe) 10759.1 cm-1
Scaled (by 0.9586) Zero Point Vibrational Energy (zpe) 10313.7 cm-1
See section III.C.1 List or set vibrational scaling factors to change the scale factors used here.
See section III.C.2 Calculate a vibrational scaling factor for a given set of molecules to determine the least squares best scaling factor.
Rotational Constants (cm-1) from geometry optimized at B1B95/6-311G*
ABC
1.43694 0.16946 0.16946

See section I.F.4 to change rotational constant units
Geometric Data calculated at B1B95/6-311G*

Point Group is D3d

Cartesians (Å)
Atom x (Å) y (Å) z (Å)
Si1 0.000 0.000 1.169
Si2 0.000 0.000 -1.169
H3 0.000 1.393 1.686
H4 -1.206 -0.696 1.686
H5 1.206 -0.696 1.686
H6 0.000 -1.393 -1.686
H7 -1.206 0.696 -1.686
H8 1.206 0.696 -1.686

Atom - Atom Distances (Å)
  Si1 Si2 H3 H4 H5 H6 H7 H8
Si12.33741.48581.48581.48583.17623.17623.1762
Si22.33743.17623.17623.17621.48581.48581.4858
H31.48583.17622.41252.41254.37363.64803.6480
H41.48583.17622.41252.41253.64803.64804.3736
H51.48583.17622.41252.41253.64804.37363.6480
H63.17621.48584.37363.64803.64802.41252.4125
H73.17621.48583.64803.64804.37362.41252.4125
H83.17621.48583.64804.37363.64802.41252.4125

picture of disilane state 1 conformation 1
More geometry information
Calculated Bond Angles
atom1 atom2 atom3 angle atom1 atom2 atom3 angle
Si1 Si2 H6 110.368 Si1 Si2 H7 110.368
Si1 Si2 H8 110.368 Si2 Si1 H3 110.368
Si2 Si1 H4 110.368 Si2 Si1 H5 110.368
H3 Si1 H4 108.560 H3 Si1 H5 108.560
H4 Si1 H5 108.560 H6 Si2 H7 108.560
H6 Si2 H8 108.560 H7 Si2 H8 108.560
Electronic energy levels
Charges, Dipole, Quadrupole and Polarizability
Charges from optimized geometry at B1B95/6-311G* Charges (e)
Number Element Mulliken CHELPG AIM ESP
1 Si 0.273      
2 Si 0.273      
3 H -0.091      
4 H -0.091      
5 H -0.091      
6 H -0.091      
7 H -0.091      
8 H -0.091      


Electric dipole moments
Electric dipole components in Debye
(What's a Debye? See section VII.A.3)
  x y z Total
  0.000 0.000 0.000 0.000
CHELPG        
AIM        
ESP        


Electric Quadrupole moment
Quadrupole components in D Å
Primitive
 xyz
x -31.163 0.000 0.000
y 0.000 -31.163 0.000
z 0.000 0.000 -32.078
Traceless
 xyz
x 0.457 0.000 0.000
y 0.000 0.457 0.000
z 0.000 0.000 -0.915
Polar
3z2-r2-1.830
x2-y20.000
xy0.000
xz0.000
yz0.000


Polarizabilities
Components of the polarizability tensor.
Units are Å3 (Angstrom cubed)
Change units.
  x y z
x 7.504 0.000 0.000
y 0.000 7.504 0.000
z 0.000 0.000 9.849


<r2> (average value of r2) Å2
<r2> 86.591
(<r2>)1/2 9.305