CDMS

Ethyl alcohol, ethanol, ethyl hydroxide, alcohol

a-CH3CH2OD

v=0

Tag: 47515

Version: 1*

Date of Entry: Aug. 7, 2015

Contributor: H. S. P. Müller, A. Walters

A	34773.74 MHz
B	8768.85 MHz
C	7687.89 MHz

µ_a	0.046 D
µ_b	1.438 D
µ_c	0 D

detected in ISM/CSM	no
Egy	0.0 1/cm
HTML-Title	a-CH3CH2OD
image	PNG/EtOH_cat.png
Isotope Corr.	-3.819
Lines Listed	3088
log STR0	-7.3
log STR1	-6.0
Max. Frequency	1000 GHz
Max. J	60

	All
Q(2.725 /K)	16.3817
Q(5.0 /K)	39.8908
Q(9.375 /K)	101.2593
Q(18.75 /K)	284.5668
Q(37.5 /K)	802.3666
Q(75.0 /K)	2266.3082
Q(150.0 /K)	6408.002
Q(225.0 /K)	11774.7917
Q(300.0 /K)	18134.8566

Description

The anti conformer of ethanol is lower in energy than the symmetric and antisymmetric combinations of the gauche conformer by 39.49 and 42.77cm^–1, respectively, as determined for the main isotopolog by
(1) J. C. Pearson, C. S. Brauer, and B. J. Drouin, 2008, J. Mol. Spectrosc. 251, 394.
These conformers are caused by the large amplitude motion of the OH-group. Even though there is extensive internal rotation interaction between the anti and the gauche conformers, the energy differences permit these interactions to be neglected for transitions with low quantum numbers; in practice, for transitions with J+2K_a ≤32; in the case of the OD isotopolog, the value appears to be larger, at least at low values of K_a. The analysis was restricted to such transitions because these are the ones most likely to be observed by radioastronomical means. Internal rotation of the methyl group has been resolved in part in the laboratory. The splittings are small enough to be negligible for most astronomical observations. The data have been summarized by
(2) A. Walters, M. Schäfer, M. Ordu, F. Lewen, S. Schlemmer, and H. S. P. Müller, 2015, J. Mol. Spectrosc. 314, 6.
Additional microwave frequencies have been reported by
(3) J. P. Culot, 1971, PhD thesis, Université Catolique Louvain.
Predictions with J+2K_a >32 should be viewed with caution. The predictions have been truncated at J=60 and K_a=10.
Note: The partition function does not take into account the gauche-conformers. Therefore, scaled partition function values are available. The scaling factors were taken from the main isotopolog and refer to the ground vibrational state (anti plus gauche conformers versus only the anti conformer). The correction should be quite good. The first excited methyl and OH torsional modes are both about 250cm^–1 above ground for the main isotolog, and this value may differ somewhat for the deuterated isotopologs.
The dipole moment was assumed to agree with that of the main species. This assumption should be very good for the large b dipole moment component, but may be very different for the almost vanishing a dipole moment component. The values were taken from
(4) M. Takano, Y. Sasada, and T. Satoh, 1968, J. Mol. Spectrosc. 26, 157.

ID	Name	Type
8523	c047515.cat	mrg
8524	c047515.egy	egy
8525	c047515i.cat	cat
8526	C2H5OD.lin	lin

Filename	Type	Comment	Createdate
c047515i.cat	cat	Predicted transition frequencies without experimental values	Oct. 16, 2015, 12:34 p.m.
e047515.cat	doc	wonderful wonderful CDMS documentation	Sept. 30, 2015, 4:43 p.m.
c047515.egy	egy	State energy listing	Oct. 16, 2015, 12:33 p.m.
C2H5OD.fit	fit	Spfit's log file	Sept. 30, 2015, 4:47 p.m.
C2H5OD.int	int	Input file for spcat (dipole)	Sept. 30, 2015, 4:47 p.m.
C2H5OD.lin	lin	Experimental transition frequencies	Sept. 30, 2015, 4:47 p.m.
c047515.lit	lit	References	Oct. 16, 2015, 12:33 p.m.
c047515.cat	mrg	Predicted transition frequencies with experimental values merged	Oct. 16, 2015, 12:33 p.m.
C2H5OD.opt	opt	Input file for calmrg (merge conditions)	Oct. 16, 2015, 12:32 p.m.
c047515.out	out	Partition functions	Oct. 16, 2015, 12:34 p.m.
C2H5OD.par	par	Input file for spfit (parameters)	Oct. 16, 2015, 12:32 p.m.
C2H5OD.var	var	Input file for spcat (parameters, variance)	Oct. 16, 2015, 12:32 p.m.

CDMS

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