All results from a given calculation for C₃H₆O (Acetone enol)

Energy calculated at SVWN/6-311G*

	hartrees
Energy at 0K	-192.145823
Energy at 298.15K	-192.152166
HF Energy	-192.145823
Nuclear repulsion energy	120.997322

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 SVWN/6-311G*

Mode Number	Symmetry	Frequency (cm-1)	Scaled Frequency (cm-1)	IR Intensities (km mol-1)	Raman Act (Å4/u)	Dep P	Dep U
1	A'	3659	3624	17.67
2	A'	3176	3146	6.09
3	A'	3090	3060	8.31
4	A'	3073	3044	5.56
5	A'	2975	2947	12.58
6	A'	1713	1697	159.20
7	A'	1435	1421	12.37
8	A'	1416	1403	14.30
9	A'	1374	1361	50.00
10	A'	1332	1320	9.12
11	A'	1186	1174	169.49
12	A'	994	984	20.99
13	A'	952	942	3.29
14	A'	880	872	2.33
15	A'	473	468	21.00
16	A'	402	398	1.55
17	A"	3037	3008	7.52
18	A"	1412	1398	15.44
19	A"	1034	1024	2.20
20	A"	744	737	99.74
21	A"	704	697	0.07
22	A"	495	491	9.11
23	A"	475	470	113.51
24	A"	179	177	1.80

Unscaled Zero Point Vibrational Energy (zpe) 18103.1 cm^-1
Scaled (by 0.9904) Zero Point Vibrational Energy (zpe) 17929.3 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 SVWN/6-311G*

A	B	C
0.34116	0.30811	0.16696

See section I.F.4 to change rotational constant units

Geometric Data calculated at SVWN/6-311G*

Point Group is C_s

Cartesians (Å)

Atom	x (Å)	y (Å)	z (Å)
C1	0.864	-1.104	0.000
C2	0.000	0.092	0.000
C3	0.436	1.353	0.000
O4	-1.305	-0.261	0.000
H5	1.928	-0.833	0.000
H6	0.654	-1.727	0.885
H7	0.654	-1.727	-0.885
H8	1.504	1.574	0.000
H9	-0.252	2.205	0.000
H10	-1.851	0.548	0.000

Atom - Atom Distances (Å)

	C1	C2	C3	O4	H5	H6	H7	H8	H9	H10
C1		1.4760	2.4940	2.3275	1.0977	1.1025	1.1025	2.7536	3.4926	3.1781
C2	1.4760		1.3339	1.3519	2.1383	2.1266	2.1266	2.1113	2.1279	1.9059
C3	2.4940	1.3339		2.3739	2.6461	3.2122	3.2122	1.0904	1.0956	2.4242
O4	2.3275	1.3519	2.3739		3.2831	2.6023	2.6023	3.3551	2.6814	0.9757
H5	1.0977	2.1383	2.6461	3.2831		1.7905	1.7905	2.4439	3.7392	4.0229
H6	1.1025	2.1266	3.2122	2.6023	1.7905		1.7698	3.5221	4.1316	3.4978
H7	1.1025	2.1266	3.2122	2.6023	1.7905	1.7698		3.5221	4.1316	3.4978
H8	2.7536	2.1113	1.0904	3.3551	2.4439	3.5221	3.5221		1.8660	3.5079
H9	3.4926	2.1279	1.0956	2.6814	3.7392	4.1316	4.1316	1.8660		2.3024
H10	3.1781	1.9059	2.4242	0.9757	4.0229	3.4978	3.4978	3.5079	2.3024

More geometry information
Calculated Bond Angles

atom1	atom2	atom3	angle		atom1	atom2	atom3	angle
C1	C2	C3	125.070		C1	C2	O4	110.701
C2	C1	H5	111.525		C2	C1	H6	110.279
C2	C1	H7	110.279		C2	C3	H8	120.797
C2	C3	H9	121.991		C2	O4	H10	108.859
C3	C2	O4	124.228		H5	C1	H6	108.934
H5	C1	H7	108.934		H6	C1	H7	106.756
H8	C3	H9	117.212

Electronic energy levels

Charges, Dipole, Quadrupole and Polarizability
Charges from optimized geometry at SVWN/6-311G* Charges (e)

Number	Element	Mulliken	CHELPG	AIM	ESP
1	C	-0.751
2	C	0.220
3	C	-0.585
4	O	-0.502
5	H	0.252
6	H	0.261
7	H	0.261
8	H	0.230
9	H	0.212
10	H	0.402

Electric dipole moments
Electric dipole components in Debye
(What's a Debye? See section VII.A.3)

	x	y	z	Total
	-0.247	0.593	0.000	0.642
CHELPG
AIM
ESP

Electric Quadrupole moment
Quadrupole components in D Å

Primitive   x y z x -22.157 -3.504 0.000 y -3.504 -24.547 0.000 z 0.000 0.000 -27.375

Traceless   x y z x 3.804 -3.504 0.000 y -3.504 0.219 0.000 z 0.000 0.000 -4.023

Polar 3z2-r2 -8.046 x2-y2 2.390 xy -3.504 xz 0.000 yz 0.000

Polarizabilities
Components of the polarizability tensor.
Units are ų (Angstrom cubed)
Change units.

	x	y	z
x	5.920	0.249	0.000
y	0.249	7.548	0.000
z	0.000	0.000	3.682

<r²> (average value of r²) Ų

<r2>	79.753
(<r2>)1/2	8.930