The Principle of Minimal Resistance in Non-equilibrium Thermodynamics

Foundations of Physics 46 (4):393-408 (2016)
  Copy   BIBTEX

Abstract

Analytical models describing the motion of colloidal particles in given force fields are presented. In addition to local approaches, leading to well known master equations such as the Langevin and the Fokker–Planck equations, a global description based on path integration is reviewed. A new result is presented, showing that under very broad conditions, during its evolution a dissipative system tends to minimize its energy dissipation in such a way to keep constant the Hamiltonian time rate, equal to the difference between the flux-based and the force-based Rayleigh dissipation functions. In fact, the Fokker–Planck equation can be interpreted as the Hamilton–Jacobi equation resulting from such minumum principle. At steady state, the Hamiltonian time rate is maximized, leading to a minimum resistance principle. In the unsteady case, we consider the relaxation to equilibrium of harmonic oscillators and the motion of a Brownian particle in shear flow, obtaining results that coincide with the solution of the Fokker–Planck and the Langevin equations

Categories

Keywords

Reprint years

DOI

10.1007/s10701-015-9969-3

Links

PhilArchive



    Upload a copy of this work     Papers currently archived: 91,219

External links

Setup an account with your affiliations in order to access resources via your University's proxy server

Through your library

My notes

Similar books and articles

Incompatibility of the Schrödinger equation with Langevin and Fokker-Planck equations.Daniel T. Gillespie - 1995 - Foundations of Physics 25 (7):1041-1053.
Brownian Motion of a Charged Particle in Electromagnetic Fluctuations at Finite Temperature.Jen-Tsung Hsiang, Tai-Hung Wu & Da-Shin Lee - 2011 - Foundations of Physics 41 (1):77-87.
An ecological approach to biosystem thermodynamics.Lionel Johnson - 1992 - Biology and Philosophy 7 (1):35-60.
Fokker–Planck Theory of Nonequilibrium Systems Governed by Hierarchical Dynamics.Sumiyoshi Abe - 2014 - Foundations of Physics 44 (2):175-182.
A Classical Explanation of Quantization.Gerhard Grössing, Johannes Mesa Pascasio & Herbert Schwabl - 2011 - Foundations of Physics 41 (9):1437-1453.
Quantum thermodynamics of nonequilibrium. Onsager reciprocity and dispersion-dissipation relations.Gian Paolo Beretta - 1987 - Foundations of Physics 17 (4):365-381.
On the validity of the Onsager-Machlup postulate for nonlinear stochastic processes.B. H. Lavenda - 1979 - Foundations of Physics 9 (5-6):405-420.
Ambiguities in order-theoretic formulations of thermodynamics.Robert Marsland Iii, Harvey R. Brown & Giovanni Valente - unknown
The approach towards equilibrium in Lanford’s theorem.Giovanni Valente - 2014 - European Journal for Philosophy of Science 4 (3):309-335.
Hamilton and the Law of Varying Action Revisited.C. D. Bailey - 2004 - Foundations of Physics 34 (9):1385-1406.
“Principle of Indistinguishability” and Equations of Motion for Particles with Spin.Mauro Napsuciale - 2003 - Foundations of Physics 33 (5):741-768.
Relativistic Brownian Motion and Gravity as an Eikonal Approximation to a Quantum Evolution Equation.O. Oron & L. P. Horwitz - 2005 - Foundations of Physics 35 (7):1181-1203.
Boltzmann and Fokker-planck equations modelling opinion formation in the presence of strong leaders.Peter Bertram Düring, Jan-Frederik Pietschmann A. Markowich & Marie-Therese Wolfram - unknown
Hamiltonian description and quantization of dissipative systems.Charles P. Enz - 1994 - Foundations of Physics 24 (9):1281-1292.
Information and gravitation.W. J. Cocke & B. Roy Frieden - 1997 - Foundations of Physics 27 (10):1397-1412.

Analytics

Added to PP
2015-11-07

Downloads
20 (#723,940)

6 months
10 (#219,185)

Historical graph of downloads
How can I increase my downloads?

Citations of this work

No citations found.

Add more citations

References found in this work

No references found.

Add more references