On the Rotational Diffusion of Molecules
- 1 March 1966
- journal article
- Published by AIP Publishing in The Journal of Chemical Physics
- Vol. 44 (5), 1830-1836
- https://doi.org/10.1063/1.1726949
Abstract
The Debye model of rotational diffusion by small angular steps is generalized to allow molecular reorientation through angular steps of arbitrarily large size. The generalized diffusion models are found to give a rather accurate representation of molecular reorientation in liquids and gases, as observed in the infrared and Raman spectra of simple molecules. One interesting feature of both the theoretical and experimental correlation functions is that the approach to rotational equilibrium often takes the form of a damped oscillation, rather than the monotonic decay which is usually assumed.Keywords
This publication has 14 references indexed in Scilit:
- Relations between Raman Spectroscopy and Nuclear Spin RelaxationThe Journal of Chemical Physics, 1965
- Nuclear spin-lattice relaxation, including the spin-rotation interaction, in liquid benzene and several benzene derivatives up to the critical temperatureProceedings of the Physical Society, 1965
- Infrared Spectra of Liquid and Solid Carbon MonoxideThe Journal of Chemical Physics, 1962
- Nuclear Relaxation in Gases: Mixtures of Methane and OxygenThe Journal of Chemical Physics, 1961
- On the Mechanism of Nuclear Relaxation in Gaseous and Liquid CHF3The Journal of Chemical Physics, 1961
- Nuclear Magnetic Spin-Lattice Relaxation by Spin-Rotational InteractionsPhysical Review Letters, 1961
- Perturbation de quelques fréquences d'absorption infrarouges par les gaz comprimés à des pressions de l'ordre de 1000 atmJournal de Physique et le Radium, 1954
- ROTATIONAL WINGS OF RAMAN BANDS AND FREE ROTATION IN LIQUID OXYGEN, NITROGEN, AND METHANECanadian Journal of Physics, 1952
- Relaxation Effects in Nuclear Magnetic Resonance AbsorptionPhysical Review B, 1948
- Mouvement brownien d'un ellipsoide - I. Dispersion diélectrique pour des molécules ellipsoidalesJournal de Physique et le Radium, 1934