Resolution of Loschmidt’s paradox: The origin of irreversible behavior in reversible atomistic dynamics
- 6 July 1987
- journal article
- research article
- Published by American Physical Society (APS) in Physical Review Letters
- Vol. 59 (1) , 10-13
- https://doi.org/10.1103/physrevlett.59.10
Abstract
We show that Nosromanē mechanics provides a link between computer simulations of nonequilibrium processes and real-world experiments. Reversible Nose¯ equations of motion, when used to constrain non- equilibrium boundary regions, generate stable dissipative behavior within an adjoining bulk sample governed by Newton’s equations of motion. Thus, irreversible behavior consistent with the second law of thermodynamics arises from completely reversible microscopic motion. Loschmidt’s reversibility paradox is surmounted by this Nose¯-Newton system, because the steady-state nonequilibrium probability density in the many-body phase space is confined to a zero-volume attractor.Keywords
This publication has 9 references indexed in Scilit:
- Entropy evolution as a guide for replacing the Liouville equationPhysical Review A, 1986
- Numerical test of the Liouville equationPhysical Review A, 1986
- Canonical dynamics of the Nosé oscillator: Stability, order, and chaosPhysical Review A, 1986
- Classical response theory propagators: An illustrative exampleThe Journal of Chemical Physics, 1986
- Flows Far From Equilibrium Via Molecular DynamicsAnnual Review of Fluid Mechanics, 1986
- The Nose–Hoover thermostatThe Journal of Chemical Physics, 1985
- Canonical dynamics: Equilibrium phase-space distributionsPhysical Review A, 1985
- A unified formulation of the constant temperature molecular dynamics methodsThe Journal of Chemical Physics, 1984
- Dense-fluid shear viscosity via nonequilibrium molecular dynamicsPhysical Review A, 1975