Standard

Modelling of the spectral absorption coefficient in a pure CO2 atmosphere in the region of 17 mu m. / Filippov, NN; Tonkov, MV; Ogibalov, VP.

IRS 2000: CURRENT PROBLEMS IN ATMOSPHERIC RADIATION. ed. / WL Smith; YM Timofeyev. A. Deepak Publishing, 2001. p. 627-630 (STUDIES IN GEOPHYSICAL OPTICS AND REMOTE SENSING).

Research output: Chapter in Book/Report/Conference proceedingConference contributionResearchpeer-review

Harvard

Filippov, NN, Tonkov, MV & Ogibalov, VP 2001, Modelling of the spectral absorption coefficient in a pure CO2 atmosphere in the region of 17 mu m. in WL Smith & YM Timofeyev (eds), IRS 2000: CURRENT PROBLEMS IN ATMOSPHERIC RADIATION. STUDIES IN GEOPHYSICAL OPTICS AND REMOTE SENSING, A. Deepak Publishing, pp. 627-630, International Radiation Symposium, ST PETERSBURG, 24/07/00.

APA

Filippov, NN., Tonkov, MV., & Ogibalov, VP. (2001). Modelling of the spectral absorption coefficient in a pure CO2 atmosphere in the region of 17 mu m. In WL. Smith, & YM. Timofeyev (Eds.), IRS 2000: CURRENT PROBLEMS IN ATMOSPHERIC RADIATION (pp. 627-630). (STUDIES IN GEOPHYSICAL OPTICS AND REMOTE SENSING). A. Deepak Publishing.

Vancouver

Filippov NN, Tonkov MV, Ogibalov VP. Modelling of the spectral absorption coefficient in a pure CO2 atmosphere in the region of 17 mu m. In Smith WL, Timofeyev YM, editors, IRS 2000: CURRENT PROBLEMS IN ATMOSPHERIC RADIATION. A. Deepak Publishing. 2001. p. 627-630. (STUDIES IN GEOPHYSICAL OPTICS AND REMOTE SENSING).

Author

Filippov, NN ; Tonkov, MV ; Ogibalov, VP. / Modelling of the spectral absorption coefficient in a pure CO2 atmosphere in the region of 17 mu m. IRS 2000: CURRENT PROBLEMS IN ATMOSPHERIC RADIATION. editor / WL Smith ; YM Timofeyev. A. Deepak Publishing, 2001. pp. 627-630 (STUDIES IN GEOPHYSICAL OPTICS AND REMOTE SENSING).

BibTeX

@inproceedings{c779a6a17c2b49ecb7c159c366ab1069,
title = "Modelling of the spectral absorption coefficient in a pure CO2 atmosphere in the region of 17 mu m",
abstract = "The absorption coefficients of the pure CO2 gas in the region of 17 mum were examined. A special attention was paid to the line mixing effect that influenced the spectral shape in the Q-branch regions of the absorption bands. Two methods in shape description were analyzed. The first method uses the Rosenkranz line shapes with the line mixing parameters, which are found from an empirical rotational relaxation matrix; this matrix is constructed using the shape analyses of the band of a different spectral region (Edwards and Strow, 1991). The second method is based on the strong collision model with adjusted branch coupling (Tonkov et al., 1996), and it is necessary to use only one empirical parameter for all the bands to describe the line mixing effect on line shapes. This method was generalized to the bands of a PiDelta type. The merits and the demerits of these two methods are discussed, and the results of the correspondent calculations are compared to experimental shapes. It is inferred that the strong collision model for the absorption coefficient calculations can be applied in solving the non-LTE radiative transfer problem in CO2 bands in the atmosphere of Mars.",
keywords = "INFRARED EMISSIONS, LINE",
author = "NN Filippov and MV Tonkov and VP Ogibalov",
year = "2001",
language = "Английский",
isbn = "0-937194-43-3",
series = "STUDIES IN GEOPHYSICAL OPTICS AND REMOTE SENSING",
publisher = "A. Deepak Publishing",
pages = "627--630",
editor = "WL Smith and YM Timofeyev",
booktitle = "IRS 2000: CURRENT PROBLEMS IN ATMOSPHERIC RADIATION",
address = "Соединенные Штаты Америки",
note = "null ; Conference date: 24-07-2000 Through 29-07-2000",

}

RIS

TY - GEN

T1 - Modelling of the spectral absorption coefficient in a pure CO2 atmosphere in the region of 17 mu m

AU - Filippov, NN

AU - Tonkov, MV

AU - Ogibalov, VP

PY - 2001

Y1 - 2001

N2 - The absorption coefficients of the pure CO2 gas in the region of 17 mum were examined. A special attention was paid to the line mixing effect that influenced the spectral shape in the Q-branch regions of the absorption bands. Two methods in shape description were analyzed. The first method uses the Rosenkranz line shapes with the line mixing parameters, which are found from an empirical rotational relaxation matrix; this matrix is constructed using the shape analyses of the band of a different spectral region (Edwards and Strow, 1991). The second method is based on the strong collision model with adjusted branch coupling (Tonkov et al., 1996), and it is necessary to use only one empirical parameter for all the bands to describe the line mixing effect on line shapes. This method was generalized to the bands of a PiDelta type. The merits and the demerits of these two methods are discussed, and the results of the correspondent calculations are compared to experimental shapes. It is inferred that the strong collision model for the absorption coefficient calculations can be applied in solving the non-LTE radiative transfer problem in CO2 bands in the atmosphere of Mars.

AB - The absorption coefficients of the pure CO2 gas in the region of 17 mum were examined. A special attention was paid to the line mixing effect that influenced the spectral shape in the Q-branch regions of the absorption bands. Two methods in shape description were analyzed. The first method uses the Rosenkranz line shapes with the line mixing parameters, which are found from an empirical rotational relaxation matrix; this matrix is constructed using the shape analyses of the band of a different spectral region (Edwards and Strow, 1991). The second method is based on the strong collision model with adjusted branch coupling (Tonkov et al., 1996), and it is necessary to use only one empirical parameter for all the bands to describe the line mixing effect on line shapes. This method was generalized to the bands of a PiDelta type. The merits and the demerits of these two methods are discussed, and the results of the correspondent calculations are compared to experimental shapes. It is inferred that the strong collision model for the absorption coefficient calculations can be applied in solving the non-LTE radiative transfer problem in CO2 bands in the atmosphere of Mars.

KW - INFRARED EMISSIONS

KW - LINE

M3 - статья в сборнике материалов конференции

SN - 0-937194-43-3

T3 - STUDIES IN GEOPHYSICAL OPTICS AND REMOTE SENSING

SP - 627

EP - 630

BT - IRS 2000: CURRENT PROBLEMS IN ATMOSPHERIC RADIATION

A2 - Smith, WL

A2 - Timofeyev, YM

PB - A. Deepak Publishing

Y2 - 24 July 2000 through 29 July 2000

ER -

ID: 41409805