Inertial effects in butane stochastic dynamics
- 1 July 1989
- journal article
- Published by AIP Publishing in The Journal of Chemical Physics
- Vol. 91 (1) , 211-218
- https://doi.org/10.1063/1.457508
Abstract
The range of validity of diffusive algorithms is studied by comparing the isomerization rates and rotational reorientation times from a series of Langevin dynamics trajectories of butane with the results of a Brownian dynamics (diffusive) trajectory, as well as with analytic approximations. It is found that inertial effects may be ignored for rotation at most liquid densities and contribute approximately 10% to the isomerization rate at water viscosities. For neat butane, or other short-chain alkane solvents at room temperature, the effect of inertial terms on isomerization rates is significant.Keywords
This publication has 56 references indexed in Scilit:
- Brownian motion in a field of force and the diffusion model of chemical reactionsPublished by Elsevier ,2004
- Breakdown of Kramers theory description of photochemical isomerization and the possible involvement of frequency dependent frictionThe Journal of Chemical Physics, 1983
- Raman study of the pressure and temperature effects on reorientational motions of tetrafluoromethane and tetrafluoromethane in argon and neonThe Journal of Physical Chemistry, 1981
- Depolarized light scattering in dilute solutions of alkanes: A comparison of the bond additive and interacting atom approximations to the molecular polarizabilityThe Journal of Chemical Physics, 1981
- Brownian Dynamics Study of Polymer Conformational Transitions±Macromolecules, 1980
- Simulation of polymer dynamics. I. General theoryThe Journal of Chemical Physics, 1978
- Calculations of the Diffusion Coefficients of n-AlkanesThe Journal of Chemical Physics, 1968
- Preparation and Physical Properties of a Series of n-AlkanesJournal of the American Chemical Society, 1951
- Stochastic Problems in Physics and AstronomyReviews of Modern Physics, 1943
- The Activated Complex in Chemical ReactionsThe Journal of Chemical Physics, 1935