Direct Molecular Dynamics Simulation of Flow Down a Chemical Potential Gradient in a Slit-Shaped Micropore
- 27 March 1995
- journal article
- research article
- Published by American Physical Society (APS) in Physical Review Letters
- Vol. 74 (13) , 2463-2466
- https://doi.org/10.1103/physrevlett.74.2463
Abstract
A novel nonequilibrium molecular dynamics simulation technique has been developed whereby the flux of particles, flowing between explicitly defined regions of different constant chemical potential, is measured directly by counting particles. The method uses both stochastic and dynamic steps. A linear relationship between flux and concentration gradient (Fick's law) is found for methane in a carbonaceous slit micropore with a diffuse wall condition. Diffusion coefficients thereby calculated are larger than transport diffusivities from equilibrium simulations using Darken's rule.Keywords
This publication has 16 references indexed in Scilit:
- Transport theory of dense, strongly inhomogeneous fluidsThe Journal of Chemical Physics, 1993
- Transport diffusivity of methane in silicalite from equilibrium and nonequilibrium simulationsThe Journal of Physical Chemistry, 1993
- Capillary condensation and molecular-dynamics simulations of flow in narrow poresPhysical Review A, 1991
- Nonequilibrium gas flow in the transition regime: A molecular-dynamics studyPhysical Review A, 1991
- Molecular-dynamics simulation of flow in a two-dimensional channel with atomically rough wallsPhysical Review A, 1990
- Liquid flow in pores: Slip, no-slip, or multilayer stickingPhysical Review A, 1989
- Molecular dynamics of fluid flow at solid surfacesPhysics of Fluids A: Fluid Dynamics, 1989
- Molecular dynamics of flow in microporesThe Journal of Chemical Physics, 1987
- Molecular dynamics simulation simulation of channel flowPhysics Letters A, 1986
- Statistical–mechanical theory of membrane transport for multicomponent systems: Passive transport through open membranesThe Journal of Chemical Physics, 1978