Infrared and Raman study of liquids. III. Theory of the rotation-vibration coupling effects. Diatomic molecules in inert solutions
- 1 May 1974
- journal article
- research article
- Published by American Physical Society (APS) in Physical Review A
- Vol. 9 (5), 2136-2150
- https://doi.org/10.1103/physreva.9.2136
Abstract
A theory is proposed to explain the effects of the rotation-vibration coupling in the ir and Raman spectra of inert solutions of diatomic molecules. This theory is a stochastic-type theory related to similar theories of NMR spectra. Spectral manifestations of the rotation-vibration interaction are found to depend very strongly on whether an ir, isotropic, or anisotropic Raman spectrum is concerned, on the nature of molecular rotations in the liquid, and on the properties of the solvent-solute interaction forces. Explicit expressions are given for a number of profiles which are perturbed by this interaction.Keywords
This publication has 30 references indexed in Scilit:
- Infrared and Raman Spectra of Inert Solutions of Diatomic Molecules. II. Stochastic Theory of Band MomentsPhysical Review A, 1972
- Reorientation and Vibrational Relaxation as Line Broadening Factors in Vibrational SpectroscopyThe Journal of Chemical Physics, 1972
- Raman Band Shapes and Molecular ReorientationThe Journal of Chemical Physics, 1972
- Angular Time-Correlation Functions from Spectra for Some Molecular LiquidsThe Journal of Chemical Physics, 1972
- Raman Scattering: Orientational Motions in LiquidsThe Journal of Chemical Physics, 1972
- Analysis of Orientational Broadening of Raman Line ShapesThe Journal of Chemical Physics, 1972
- Raman Study of Liquids. I. Theory of the Raman Spectra of Diatomic Molecules in Inert SolutionsPhysical Review A, 1971
- Relaxation Processes and Molecular Motion in Liquids and GasesThe Journal of Chemical Physics, 1971
- Infrared Study of Liquids. I. The Theory of the ir Spectra of Diatomic Molecules in Inert SolutionsThe Journal of Chemical Physics, 1970
- Semiclassical Theory of Spectra and Relaxation in Molecular GasesThe Journal of Chemical Physics, 1966