Analysis of the pure-rotational spectrum in the ν28 = 1 excited torsional state and torsional couplings of trans-ethyl methyl ether

Kaori Kobayashi; Takanori Matsui; Norimichi Mori; Shozo Tsunekawa; Nobukimi Ohashi

doi:10.1016/j.jms.2011.08.002

Analysis of the pure-rotational spectrum in the ν₂₈ = 1 excited torsional state and torsional couplings of trans-ethyl methyl ether

Kaori Kobayashi^*, Takanori Matsui, Norimichi Mori, Shozo Tsunekawa, Nobukimi Ohashi

^*Corresponding author for this work

Department of Physics

Research output: Contribution to journal › Article › peer-review

4 Scopus citations

Abstract

The trans-ethyl methyl ether molecule has three low-lying torsional modes, that is, two inequivalent methyl internal rotations and an asymmetric skeletal torsion. The internal rotations of the CCH₃ and OCH₃ methyl rotors and the skeletal torsion correspond to the vibrational modes, ν₂₈, ν₂₉ and ν₃₀ respectively. In this study, the microwave absorption spectrum in the ν₂₈ = 1 CCH ₃ torsional state was analyzed for the first time. Nine hundred fifty seven lines up to J = 48 and K = 4 were assigned, and the rotational, centrifugal distortion and internal rotational tunneling parameters were determined with the use of a tunneling matrix formalism. By combining the present results on the ν₂₈ = 1 torsional state with those for the ν₃₀ = 1 skeletal torsional state and the ν₂₉ = 1 OCH₃ torsional state, torsional couplings are estimated in order to understand quantitatively the inverted A/E sequence patterns observed for those three excited torsional states.

Original language	English
Pages (from-to)	242-247
Number of pages	6
Journal	Journal of Molecular Spectroscopy
Volume	269
Issue number	2
DOIs	https://doi.org/10.1016/j.jms.2011.08.002
State	Published - 2011/10

Keywords

Barrier height to internal rotation
Methyl internal rotation
Microwave spectroscopy
Torsional couplings
Trans-ethyl methyl ether

ASJC Scopus subject areas

Atomic and Molecular Physics, and Optics
Spectroscopy
Physical and Theoretical Chemistry

Access to Document

10.1016/j.jms.2011.08.002

Cite this

@article{252c43c1e78249e7994d7d0caee3b4b0,

title = "Analysis of the pure-rotational spectrum in the ν28 = 1 excited torsional state and torsional couplings of trans-ethyl methyl ether",

abstract = "The trans-ethyl methyl ether molecule has three low-lying torsional modes, that is, two inequivalent methyl internal rotations and an asymmetric skeletal torsion. The internal rotations of the CCH3 and OCH3 methyl rotors and the skeletal torsion correspond to the vibrational modes, ν28, ν29 and ν30 respectively. In this study, the microwave absorption spectrum in the ν28 = 1 CCH 3 torsional state was analyzed for the first time. Nine hundred fifty seven lines up to J = 48 and K = 4 were assigned, and the rotational, centrifugal distortion and internal rotational tunneling parameters were determined with the use of a tunneling matrix formalism. By combining the present results on the ν28 = 1 torsional state with those for the ν30 = 1 skeletal torsional state and the ν29 = 1 OCH3 torsional state, torsional couplings are estimated in order to understand quantitatively the inverted A/E sequence patterns observed for those three excited torsional states.",

keywords = "Barrier height to internal rotation, Methyl internal rotation, Microwave spectroscopy, Torsional couplings, Trans-ethyl methyl ether",

author = "Kaori Kobayashi and Takanori Matsui and Norimichi Mori and Shozo Tsunekawa and Nobukimi Ohashi",

note = "Funding Information: K.K. would like to thank Y. Hori and K. Murata for helping the microwave spectral measurement. This study was partially supported by Grant-in-Aid for Young Scientists (B) by the Ministry of Education, Culture, Sports, Science and Technology of Japan (Grant No. 20740103 ) and National Astronomical Observatory of Japan. ",

year = "2011",

month = oct,

doi = "10.1016/j.jms.2011.08.002",

language = "英語",

volume = "269",

pages = "242--247",

journal = "Journal of Molecular Spectroscopy",

issn = "0022-2852",

publisher = "Academic Press Inc.",

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TY - JOUR

T1 - Analysis of the pure-rotational spectrum in the ν28 = 1 excited torsional state and torsional couplings of trans-ethyl methyl ether

AU - Kobayashi, Kaori

AU - Matsui, Takanori

AU - Mori, Norimichi

AU - Tsunekawa, Shozo

AU - Ohashi, Nobukimi

N1 - Funding Information: K.K. would like to thank Y. Hori and K. Murata for helping the microwave spectral measurement. This study was partially supported by Grant-in-Aid for Young Scientists (B) by the Ministry of Education, Culture, Sports, Science and Technology of Japan (Grant No. 20740103 ) and National Astronomical Observatory of Japan.

PY - 2011/10

Y1 - 2011/10

N2 - The trans-ethyl methyl ether molecule has three low-lying torsional modes, that is, two inequivalent methyl internal rotations and an asymmetric skeletal torsion. The internal rotations of the CCH3 and OCH3 methyl rotors and the skeletal torsion correspond to the vibrational modes, ν28, ν29 and ν30 respectively. In this study, the microwave absorption spectrum in the ν28 = 1 CCH 3 torsional state was analyzed for the first time. Nine hundred fifty seven lines up to J = 48 and K = 4 were assigned, and the rotational, centrifugal distortion and internal rotational tunneling parameters were determined with the use of a tunneling matrix formalism. By combining the present results on the ν28 = 1 torsional state with those for the ν30 = 1 skeletal torsional state and the ν29 = 1 OCH3 torsional state, torsional couplings are estimated in order to understand quantitatively the inverted A/E sequence patterns observed for those three excited torsional states.

AB - The trans-ethyl methyl ether molecule has three low-lying torsional modes, that is, two inequivalent methyl internal rotations and an asymmetric skeletal torsion. The internal rotations of the CCH3 and OCH3 methyl rotors and the skeletal torsion correspond to the vibrational modes, ν28, ν29 and ν30 respectively. In this study, the microwave absorption spectrum in the ν28 = 1 CCH 3 torsional state was analyzed for the first time. Nine hundred fifty seven lines up to J = 48 and K = 4 were assigned, and the rotational, centrifugal distortion and internal rotational tunneling parameters were determined with the use of a tunneling matrix formalism. By combining the present results on the ν28 = 1 torsional state with those for the ν30 = 1 skeletal torsional state and the ν29 = 1 OCH3 torsional state, torsional couplings are estimated in order to understand quantitatively the inverted A/E sequence patterns observed for those three excited torsional states.

KW - Barrier height to internal rotation

KW - Methyl internal rotation

KW - Microwave spectroscopy

KW - Torsional couplings

KW - Trans-ethyl methyl ether

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DO - 10.1016/j.jms.2011.08.002

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VL - 269

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