Methyl Internal Rotation in Fruit Esters: Chain-Length Effect Observed in the Microwave Spectrum of Methyl Hexanoate

Publikation: Beitrag in FachzeitschriftArtikelForschungPeer-Review

Autoren

  • Nhu Ngoc Dang
  • Hoang Nam Pham
  • Isabelle Kleiner
  • Martin Schwell
  • Jens Uwe Grabow
  • Ha Vinh Lam Nguyen

Externe Organisationen

  • Hanoi University of Technology
  • Universite Paris XII
Forschungs-netzwerk anzeigen

Details

OriginalspracheEnglisch
Aufsatznummer2639
FachzeitschriftMOLECULES
Jahrgang27
Ausgabenummer9
Frühes Online-Datum20 Apr. 2022
PublikationsstatusVeröffentlicht - 1 Mai 2022

Abstract

The gas-phase structures of the fruit ester methyl hexanoate, CH3-O-(C=O)-C5 H11, have been determined using a combination of molecular jet Fourier-transform microwave spectroscopy and quantum chemistry. The microwave spectrum was measured in the frequency range of 3 to 23 GHz. Two conformers were assigned, one with Cs symmetry and the other with C1 symmetry where the γ-carbon atom of the hexyl chain is in a gauche orientation in relation to the carbonyl bond. Splittings of all rotational lines into doublets were observed due to internal rotation of the methoxy methyl group CH3-O, from which torsional barriers of 417 cm−1 and 415 cm−1, respectively, could be deduced. Rotational constants obtained from geometry optimizations at various levels of theory were compared to the experimental values, confirming the soft degree of freedom of the (C=O)-C bond observed for the C1 conformer of shorter methyl alkynoates like methyl butyrate and methyl valerate. Comparison of the barriers to methyl internal rotation of methyl hexanoate to those of other CH3-O-(C=O)-R molecules leads to the conclusion that though the barrier height is relatively constant at about 420 cm−1, it decreases in molecules with longer R.

ASJC Scopus Sachgebiete

Zitieren

Methyl Internal Rotation in Fruit Esters: Chain-Length Effect Observed in the Microwave Spectrum of Methyl Hexanoate. / Dang, Nhu Ngoc; Pham, Hoang Nam; Kleiner, Isabelle et al.
in: MOLECULES, Jahrgang 27, Nr. 9, 2639, 01.05.2022.

Publikation: Beitrag in FachzeitschriftArtikelForschungPeer-Review

Dang, N. N., Pham, H. N., Kleiner, I., Schwell, M., Grabow, J. U., & Nguyen, H. V. L. (2022). Methyl Internal Rotation in Fruit Esters: Chain-Length Effect Observed in the Microwave Spectrum of Methyl Hexanoate. MOLECULES, 27(9), Artikel 2639. https://doi.org/10.3390/molecules27092639
Dang NN, Pham HN, Kleiner I, Schwell M, Grabow JU, Nguyen HVL. Methyl Internal Rotation in Fruit Esters: Chain-Length Effect Observed in the Microwave Spectrum of Methyl Hexanoate. MOLECULES. 2022 Mai 1;27(9):2639. Epub 2022 Apr 20. doi: 10.3390/molecules27092639
Dang, Nhu Ngoc ; Pham, Hoang Nam ; Kleiner, Isabelle et al. / Methyl Internal Rotation in Fruit Esters : Chain-Length Effect Observed in the Microwave Spectrum of Methyl Hexanoate. in: MOLECULES. 2022 ; Jahrgang 27, Nr. 9.
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abstract = "The gas-phase structures of the fruit ester methyl hexanoate, CH3-O-(C=O)-C5 H11, have been determined using a combination of molecular jet Fourier-transform microwave spectroscopy and quantum chemistry. The microwave spectrum was measured in the frequency range of 3 to 23 GHz. Two conformers were assigned, one with Cs symmetry and the other with C1 symmetry where the γ-carbon atom of the hexyl chain is in a gauche orientation in relation to the carbonyl bond. Splittings of all rotational lines into doublets were observed due to internal rotation of the methoxy methyl group CH3-O, from which torsional barriers of 417 cm−1 and 415 cm−1, respectively, could be deduced. Rotational constants obtained from geometry optimizations at various levels of theory were compared to the experimental values, confirming the soft degree of freedom of the (C=O)-C bond observed for the C1 conformer of shorter methyl alkynoates like methyl butyrate and methyl valerate. Comparison of the barriers to methyl internal rotation of methyl hexanoate to those of other CH3-O-(C=O)-R molecules leads to the conclusion that though the barrier height is relatively constant at about 420 cm−1, it decreases in molecules with longer R.",
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T1 - Methyl Internal Rotation in Fruit Esters

T2 - Chain-Length Effect Observed in the Microwave Spectrum of Methyl Hexanoate

AU - Dang, Nhu Ngoc

AU - Pham, Hoang Nam

AU - Kleiner, Isabelle

AU - Schwell, Martin

AU - Grabow, Jens Uwe

AU - Nguyen, Ha Vinh Lam

N1 - Funding Information: Funding: This research was funded by the Agence Nationale de la Recherche (ANR), grant number ANR-18-CE29-0011 and the Deutsche Forschungsgemeinschaft (DFG), grant number GR1344/4-1, 4-2, 4-3.

PY - 2022/5/1

Y1 - 2022/5/1

N2 - The gas-phase structures of the fruit ester methyl hexanoate, CH3-O-(C=O)-C5 H11, have been determined using a combination of molecular jet Fourier-transform microwave spectroscopy and quantum chemistry. The microwave spectrum was measured in the frequency range of 3 to 23 GHz. Two conformers were assigned, one with Cs symmetry and the other with C1 symmetry where the γ-carbon atom of the hexyl chain is in a gauche orientation in relation to the carbonyl bond. Splittings of all rotational lines into doublets were observed due to internal rotation of the methoxy methyl group CH3-O, from which torsional barriers of 417 cm−1 and 415 cm−1, respectively, could be deduced. Rotational constants obtained from geometry optimizations at various levels of theory were compared to the experimental values, confirming the soft degree of freedom of the (C=O)-C bond observed for the C1 conformer of shorter methyl alkynoates like methyl butyrate and methyl valerate. Comparison of the barriers to methyl internal rotation of methyl hexanoate to those of other CH3-O-(C=O)-R molecules leads to the conclusion that though the barrier height is relatively constant at about 420 cm−1, it decreases in molecules with longer R.

AB - The gas-phase structures of the fruit ester methyl hexanoate, CH3-O-(C=O)-C5 H11, have been determined using a combination of molecular jet Fourier-transform microwave spectroscopy and quantum chemistry. The microwave spectrum was measured in the frequency range of 3 to 23 GHz. Two conformers were assigned, one with Cs symmetry and the other with C1 symmetry where the γ-carbon atom of the hexyl chain is in a gauche orientation in relation to the carbonyl bond. Splittings of all rotational lines into doublets were observed due to internal rotation of the methoxy methyl group CH3-O, from which torsional barriers of 417 cm−1 and 415 cm−1, respectively, could be deduced. Rotational constants obtained from geometry optimizations at various levels of theory were compared to the experimental values, confirming the soft degree of freedom of the (C=O)-C bond observed for the C1 conformer of shorter methyl alkynoates like methyl butyrate and methyl valerate. Comparison of the barriers to methyl internal rotation of methyl hexanoate to those of other CH3-O-(C=O)-R molecules leads to the conclusion that though the barrier height is relatively constant at about 420 cm−1, it decreases in molecules with longer R.

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KW - large amplitude motion

KW - microwave spectroscopy

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