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Rotational Energy Relaxation Time for Vibrationally Excited Molecules. / Bechina, A. I.; Kustova, E. V.

в: Vestnik St. Petersburg University: Mathematics, Том 52, № 1, 01.2019, стр. 81-91.

Результаты исследований: Научные публикации в периодических изданияхстатьяРецензирование

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Bechina, AI & Kustova, EV 2019, 'Rotational Energy Relaxation Time for Vibrationally Excited Molecules', Vestnik St. Petersburg University: Mathematics, Том. 52, № 1, стр. 81-91. https://doi.org/10.3103/S1063454119010035

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Author

Bechina, A. I. ; Kustova, E. V. / Rotational Energy Relaxation Time for Vibrationally Excited Molecules. в: Vestnik St. Petersburg University: Mathematics. 2019 ; Том 52, № 1. стр. 81-91.

BibTeX

@article{ef26f089899d4a8393c804649ae7ae35,
title = "Rotational Energy Relaxation Time for Vibrationally Excited Molecules",
abstract = " The effect of the vibrational level of a molecule on the relaxation time of its rotational energy is studied within the state-to-state kinetic theory approach. The rotational levels of molecules are described by the non-rigid rotator model, while the interaction between molecules is described by the variable soft sphere model. This model is used to calculate the N 2 -N, O 2 -O, and NO-O collision cross sections for different vibrational and rotational levels of molecules. The rotational energy relaxation time is introduced for each vibrational level using the methods of the kinetic theory of nonequilibrium processes. The relaxation times are numerically calculated within a broad temperature range and compared with the relaxation time determined by the well-known Parker formula. The effect of various multi-quantum rotational transitions on the accuracy of the rotational relaxation time calculation is analyzed, and the convergence of the solution with an increase in the maximally possible number of quanta transmitted in the course of transition is demonstrated. It has been established that the vibrational state of a molecule has an appreciable effect on the rotational energy relaxation time in the state-to-state approach, and using the Parker formula may lead to a noticeable error in the calculation of state-to-state transport coefficients. The Parker formula provides a satisfactory agreement with the results obtained via the averaging of state-resolved relaxation times with a Boltzmann vibrational energy distribution in the one-temperature approximation at moderate temperatures. ",
keywords = "relaxation time, rotational energy, state-to-state approach, vibrationally excited state, MODEL",
author = "Bechina, {A. I.} and Kustova, {E. V.}",
year = "2019",
month = jan,
doi = "10.3103/S1063454119010035",
language = "English",
volume = "52",
pages = "81--91",
journal = "Vestnik St. Petersburg University: Mathematics",
issn = "1063-4541",
publisher = "Pleiades Publishing",
number = "1",

}

RIS

TY - JOUR

T1 - Rotational Energy Relaxation Time for Vibrationally Excited Molecules

AU - Bechina, A. I.

AU - Kustova, E. V.

PY - 2019/1

Y1 - 2019/1

N2 - The effect of the vibrational level of a molecule on the relaxation time of its rotational energy is studied within the state-to-state kinetic theory approach. The rotational levels of molecules are described by the non-rigid rotator model, while the interaction between molecules is described by the variable soft sphere model. This model is used to calculate the N 2 -N, O 2 -O, and NO-O collision cross sections for different vibrational and rotational levels of molecules. The rotational energy relaxation time is introduced for each vibrational level using the methods of the kinetic theory of nonequilibrium processes. The relaxation times are numerically calculated within a broad temperature range and compared with the relaxation time determined by the well-known Parker formula. The effect of various multi-quantum rotational transitions on the accuracy of the rotational relaxation time calculation is analyzed, and the convergence of the solution with an increase in the maximally possible number of quanta transmitted in the course of transition is demonstrated. It has been established that the vibrational state of a molecule has an appreciable effect on the rotational energy relaxation time in the state-to-state approach, and using the Parker formula may lead to a noticeable error in the calculation of state-to-state transport coefficients. The Parker formula provides a satisfactory agreement with the results obtained via the averaging of state-resolved relaxation times with a Boltzmann vibrational energy distribution in the one-temperature approximation at moderate temperatures.

AB - The effect of the vibrational level of a molecule on the relaxation time of its rotational energy is studied within the state-to-state kinetic theory approach. The rotational levels of molecules are described by the non-rigid rotator model, while the interaction between molecules is described by the variable soft sphere model. This model is used to calculate the N 2 -N, O 2 -O, and NO-O collision cross sections for different vibrational and rotational levels of molecules. The rotational energy relaxation time is introduced for each vibrational level using the methods of the kinetic theory of nonequilibrium processes. The relaxation times are numerically calculated within a broad temperature range and compared with the relaxation time determined by the well-known Parker formula. The effect of various multi-quantum rotational transitions on the accuracy of the rotational relaxation time calculation is analyzed, and the convergence of the solution with an increase in the maximally possible number of quanta transmitted in the course of transition is demonstrated. It has been established that the vibrational state of a molecule has an appreciable effect on the rotational energy relaxation time in the state-to-state approach, and using the Parker formula may lead to a noticeable error in the calculation of state-to-state transport coefficients. The Parker formula provides a satisfactory agreement with the results obtained via the averaging of state-resolved relaxation times with a Boltzmann vibrational energy distribution in the one-temperature approximation at moderate temperatures.

KW - relaxation time

KW - rotational energy

KW - state-to-state approach

KW - vibrationally excited state

KW - MODEL

UR - http://www.scopus.com/inward/record.url?scp=85064908596&partnerID=8YFLogxK

UR - http://www.mendeley.com/research/rotational-energy-relaxation-time-vibrationally-excited-molecules

U2 - 10.3103/S1063454119010035

DO - 10.3103/S1063454119010035

M3 - Article

AN - SCOPUS:85064908596

VL - 52

SP - 81

EP - 91

JO - Vestnik St. Petersburg University: Mathematics

JF - Vestnik St. Petersburg University: Mathematics

SN - 1063-4541

IS - 1

ER -

ID: 41689784