Line-Mixing Effects in Q Branches of CO2: I. Influence of Parity in Δ ↔ Π Bands

R. Rodrigues; Gh Blanquet; J. Walrand; B. Khalil; R. Le Doucen; F. Thibault; J. M. Hartmann

doi:10.1006/jmsp.1997.7453

Line-Mixing Effects in Q Branches of CO₂: I. Influence of Parity in Δ ↔ Π Bands

R. Rodrigues
, Gh Blanquet
, J. Walrand
, B. Khalil
, R. Le Doucen
, F. Thibault
, J. M. Hartmann

Université Paris-Saclay
UNamur
University of Rennes

Résultats de recherche: Contribution à un journal › Article › Revue par des pairs

Résumé

A theoretical model based on the energy corrected sudden (ECS) approximation is used in order to account for line- mixing effects in Δ ↔ Π infrared Q branches of ¹²C¹⁶O₂. Its quality is demonstrated by comparisons with numerous laboratory spectra of CO₂-He and CO₂-N₂ mixtures: three Q branches in the 4 and 17 μm regions are investigated at room temperature in a wide pressure range. The influence of mixing between Q(J) lines associated with odd and even values of the rotational quantum number J is demonstrated and analyzed in detail. It is shown that, in contrast to available fitting law approaches, the ECS model correctly predicts the influence of the parity of the rotational quantum numbers J and J′ on coupling between the Q(J) and Q(J′) lines. Comparisons between the effects of collisions of CO₂ with N₂ and He are made and analyzed. They show that these two systems involve different line couplings within the Q branch.

langue originale	Anglais
Pages (de - à)	256-268
Nombre de pages	13
journal	Journal of Molecular Spectroscopy
Volume	186
Numéro de publication	2
Les DOIs	https://doi.org/10.1006/jmsp.1997.7453
état	Publié - 1 janv. 1997
Modification externe	Oui

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10.1006/jmsp.1997.7453

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title = "Line-Mixing Effects in Q Branches of CO2: I. Influence of Parity in Δ ↔ Π Bands",

abstract = "A theoretical model based on the energy corrected sudden (ECS) approximation is used in order to account for line- mixing effects in Δ ↔ Π infrared Q branches of 12C16O2. Its quality is demonstrated by comparisons with numerous laboratory spectra of CO2-He and CO2-N2 mixtures: three Q branches in the 4 and 17 μm regions are investigated at room temperature in a wide pressure range. The influence of mixing between Q(J) lines associated with odd and even values of the rotational quantum number J is demonstrated and analyzed in detail. It is shown that, in contrast to available fitting law approaches, the ECS model correctly predicts the influence of the parity of the rotational quantum numbers J and J′ on coupling between the Q(J) and Q(J′) lines. Comparisons between the effects of collisions of CO2 with N2 and He are made and analyzed. They show that these two systems involve different line couplings within the Q branch.",

author = "R. Rodrigues and Gh Blanquet and J. Walrand and B. Khalil and \{Le Doucen\}, R. and F. Thibault and Hartmann, \{J. M.\}",

year = "1997",

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doi = "10.1006/jmsp.1997.7453",

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TY - JOUR

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T2 - I. Influence of Parity in Δ ↔ Π Bands

AU - Rodrigues, R.

AU - Blanquet, Gh

AU - Walrand, J.

AU - Khalil, B.

AU - Le Doucen, R.

AU - Thibault, F.

AU - Hartmann, J. M.

PY - 1997/1/1

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N2 - A theoretical model based on the energy corrected sudden (ECS) approximation is used in order to account for line- mixing effects in Δ ↔ Π infrared Q branches of 12C16O2. Its quality is demonstrated by comparisons with numerous laboratory spectra of CO2-He and CO2-N2 mixtures: three Q branches in the 4 and 17 μm regions are investigated at room temperature in a wide pressure range. The influence of mixing between Q(J) lines associated with odd and even values of the rotational quantum number J is demonstrated and analyzed in detail. It is shown that, in contrast to available fitting law approaches, the ECS model correctly predicts the influence of the parity of the rotational quantum numbers J and J′ on coupling between the Q(J) and Q(J′) lines. Comparisons between the effects of collisions of CO2 with N2 and He are made and analyzed. They show that these two systems involve different line couplings within the Q branch.

AB - A theoretical model based on the energy corrected sudden (ECS) approximation is used in order to account for line- mixing effects in Δ ↔ Π infrared Q branches of 12C16O2. Its quality is demonstrated by comparisons with numerous laboratory spectra of CO2-He and CO2-N2 mixtures: three Q branches in the 4 and 17 μm regions are investigated at room temperature in a wide pressure range. The influence of mixing between Q(J) lines associated with odd and even values of the rotational quantum number J is demonstrated and analyzed in detail. It is shown that, in contrast to available fitting law approaches, the ECS model correctly predicts the influence of the parity of the rotational quantum numbers J and J′ on coupling between the Q(J) and Q(J′) lines. Comparisons between the effects of collisions of CO2 with N2 and He are made and analyzed. They show that these two systems involve different line couplings within the Q branch.

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