Experimental and theoretical study of line mixing in methane spectra. II. Influence of the collision partner (He and Ar) in the v3 IR band

Standard

Experimental and theoretical study of line mixing in methane spectra. II. Influence of the collision partner (He and Ar) in the v₃ IR band. / Pieroni, D.; Nguyen-Van-Thanh; Brodbeck, C.; Hartmann, J. M.; Gabard, T.; Champion, J. P.; Bermejo, D.; Domenech, J. L.; Claveau, C.; Valentin, A.; Tonkov, M. V.; Grigoriev, I. M.; Le Doucen, R.

In: Journal of Chemical Physics, Vol. 111, No. 15, 15.10.1999, p. 6850-6863.

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

Harvard

Pieroni, D, Nguyen-Van-Thanh, Brodbeck, C, Hartmann, JM, Gabard, T, Champion, JP, Bermejo, D, Domenech, JL, Claveau, C, Valentin, A, Tonkov, MV, Grigoriev, IM & Le Doucen, R 1999, 'Experimental and theoretical study of line mixing in methane spectra. II. Influence of the collision partner (He and Ar) in the v₃ IR band', Journal of Chemical Physics, vol. 111, no. 15, pp. 6850-6863. https://doi.org/10.1063/1.480095

APA

Pieroni, D., Nguyen-Van-Thanh, Brodbeck, C., Hartmann, J. M., Gabard, T., Champion, J. P., Bermejo, D., Domenech, J. L., Claveau, C., Valentin, A., Tonkov, M. V., Grigoriev, I. M., & Le Doucen, R. (1999). Experimental and theoretical study of line mixing in methane spectra. II. Influence of the collision partner (He and Ar) in the v₃ IR band. Journal of Chemical Physics, 111(15), 6850-6863. https://doi.org/10.1063/1.480095

Vancouver

Pieroni D, Nguyen-Van-Thanh, Brodbeck C, Hartmann JM, Gabard T, Champion JP et al. Experimental and theoretical study of line mixing in methane spectra. II. Influence of the collision partner (He and Ar) in the v₃ IR band. Journal of Chemical Physics. 1999 Oct 15;111(15):6850-6863. https://doi.org/10.1063/1.480095

Author

Pieroni, D. ; Nguyen-Van-Thanh ; Brodbeck, C. ; Hartmann, J. M. ; Gabard, T. ; Champion, J. P. ; Bermejo, D. ; Domenech, J. L. ; Claveau, C. ; Valentin, A. ; Tonkov, M. V. ; Grigoriev, I. M. ; Le Doucen, R. / Experimental and theoretical study of line mixing in methane spectra. II. Influence of the collision partner (He and Ar) in the v₃ IR band. In: Journal of Chemical Physics. 1999 ; Vol. 111, No. 15. pp. 6850-6863.

BibTeX

@article{9abe7fc21e1e466bba5e9cebb89c62b2,

title = "Experimental and theoretical study of line mixing in methane spectra. II. Influence of the collision partner (He and Ar) in the v3 IR band",

abstract = "Line mixing effects are studied in the v3 band of CH4 perturbed by Ar and He at room temperature. Experiments have been made in the 2800-3200 cm-1 spectral region using four different setups. They cover a wide range of total densities, including low (0.25-2 atm), medium (25-100 atm), and high (200-1000 atm) pressure conditions. Analysis of the spectra demonstrates that the spectral shapes (of the band, the Q branch, the P and R manifolds,...) are significantly influenced by line mixing. The theoretical approach proposed in the preceding paper is used in order to model and analyze these effects. As done previously, semiclassical state-to-state rates are used together with a few empirical constants. Comparisons between measurements and spectra computed with and without the inclusion of line mixing are made. They prove the quality of the approach which satisfactorily accounts for the effects of pressure and of rotational quantum numbers on the spectral shape. It is shown that collisions with He and Ar lead to different line-coupling schemes (e.g., more coupling within the branches and less between branches) and hence to different shapes. The influence of line coupling between different branches and manifolds is evidenced and studied using high pressure spectra and absorption in the band wings.",

author = "D. Pieroni and Nguyen-Van-Thanh and C. Brodbeck and Hartmann, {J. M.} and T. Gabard and Champion, {J. P.} and D. Bermejo and Domenech, {J. L.} and C. Claveau and A. Valentin and Tonkov, {M. V.} and Grigoriev, {I. M.} and {Le Doucen}, R.",

year = "1999",

month = oct,

day = "15",

doi = "10.1063/1.480095",

language = "English",

volume = "111",

pages = "6850--6863",

journal = "Journal of Chemical Physics",

issn = "0021-9606",

publisher = "American Institute of Physics",

number = "15",

}

RIS

TY - JOUR

T1 - Experimental and theoretical study of line mixing in methane spectra. II. Influence of the collision partner (He and Ar) in the v3 IR band

AU - Pieroni, D.

AU - Nguyen-Van-Thanh,

AU - Brodbeck, C.

AU - Hartmann, J. M.

AU - Gabard, T.

AU - Champion, J. P.

AU - Bermejo, D.

AU - Domenech, J. L.

AU - Claveau, C.

AU - Valentin, A.

AU - Tonkov, M. V.

AU - Grigoriev, I. M.

AU - Le Doucen, R.

PY - 1999/10/15

Y1 - 1999/10/15

N2 - Line mixing effects are studied in the v3 band of CH4 perturbed by Ar and He at room temperature. Experiments have been made in the 2800-3200 cm-1 spectral region using four different setups. They cover a wide range of total densities, including low (0.25-2 atm), medium (25-100 atm), and high (200-1000 atm) pressure conditions. Analysis of the spectra demonstrates that the spectral shapes (of the band, the Q branch, the P and R manifolds,...) are significantly influenced by line mixing. The theoretical approach proposed in the preceding paper is used in order to model and analyze these effects. As done previously, semiclassical state-to-state rates are used together with a few empirical constants. Comparisons between measurements and spectra computed with and without the inclusion of line mixing are made. They prove the quality of the approach which satisfactorily accounts for the effects of pressure and of rotational quantum numbers on the spectral shape. It is shown that collisions with He and Ar lead to different line-coupling schemes (e.g., more coupling within the branches and less between branches) and hence to different shapes. The influence of line coupling between different branches and manifolds is evidenced and studied using high pressure spectra and absorption in the band wings.

AB - Line mixing effects are studied in the v3 band of CH4 perturbed by Ar and He at room temperature. Experiments have been made in the 2800-3200 cm-1 spectral region using four different setups. They cover a wide range of total densities, including low (0.25-2 atm), medium (25-100 atm), and high (200-1000 atm) pressure conditions. Analysis of the spectra demonstrates that the spectral shapes (of the band, the Q branch, the P and R manifolds,...) are significantly influenced by line mixing. The theoretical approach proposed in the preceding paper is used in order to model and analyze these effects. As done previously, semiclassical state-to-state rates are used together with a few empirical constants. Comparisons between measurements and spectra computed with and without the inclusion of line mixing are made. They prove the quality of the approach which satisfactorily accounts for the effects of pressure and of rotational quantum numbers on the spectral shape. It is shown that collisions with He and Ar lead to different line-coupling schemes (e.g., more coupling within the branches and less between branches) and hence to different shapes. The influence of line coupling between different branches and manifolds is evidenced and studied using high pressure spectra and absorption in the band wings.

UR - http://www.scopus.com/inward/record.url?scp=18244430024&partnerID=8YFLogxK

U2 - 10.1063/1.480095

DO - 10.1063/1.480095

M3 - Article

AN - SCOPUS:18244430024

VL - 111

SP - 6850

EP - 6863

JO - Journal of Chemical Physics

JF - Journal of Chemical Physics

SN - 0021-9606

IS - 15

ER -

ID: 35918369