Predictive Statistical Mechanics and Macroscopic Time Evolution: Hydrodynamics and Entropy Production

Foundations of Physics 46 (7):891-914 (2016)
  Copy   BIBTEX

Abstract

In the previous papers, it was demonstrated that applying the principle of maximum information entropy by maximizing the conditional information entropy, subject to the constraint given by the Liouville equation averaged over the phase space, leads to a definition of the rate of entropy change for closed Hamiltonian systems without any additional assumptions. Here, we generalize this basic model and, with the introduction of the additional constraints which are equivalent to the hydrodynamic continuity equations, show that the results obtained are consistent with the known results from the nonequilibrium statistical mechanics and thermodynamics of irreversible processes. In this way, as a part of the approach developed in this paper, the rate of entropy change and entropy production density for the classical Hamiltonian fluid are obtained. The results obtained suggest the general applicability of the foundational principles of predictive statistical mechanics and their importance for the theory of irreversibility.

Categories

Keywords

Reprint years

DOI

10.1007/s10701-016-0009-8

Links

PhilArchive



    Upload a copy of this work     Papers currently archived: 91,853

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

Time Evolution in Macroscopic Systems. II. The Entropy.W. T. Grandy - 2004 - Foundations of Physics 34 (1):21-57.
Statistical Mechanical Theory of a Closed Oscillating Universe.A. Pérez-Madrid & I. Santamaría-Holek - 2010 - Foundations of Physics 40 (3):267-275.
Macroscopic Time Evolution and MaxEnt Inference for Closed Systems with Hamiltonian Dynamics.Domagoj Kuić, Paško Županović & Davor Juretić - 2012 - Foundations of Physics 42 (2):319-339.
Reconsidering the concept of equilibrium in classical statistical mechanics.Janneke van Lith - 1999 - Philosophy of Science 66 (3):118.
Choosing a Definition of Entropy that Works.Robert H. Swendsen - 2012 - Foundations of Physics 42 (4):582-593.
Gravity, Entropy, and Cosmology: in Search of Clarity.David Wallace - 2010 - British Journal for the Philosophy of Science 61 (3):513-540.
Identities for Entropy Change Associated with the Time-Evolution of an Open System.Hiroki Majima & Akira Suzuki - 2015 - Foundations of Physics 45 (8):914-922.
Is There a Unique Physical Entropy? Micro versus Macro.Dennis Dieks - 2012 - In Hanne Andersen, Dennis Dieks, Wenceslao González, Thomas Uebel & Gregory Wheeler (eds.), New Challenges to Philosophy of Science. Springer Verlag. pp. 23--34.
Chance in Boltzmannian Statistical Mechanics.Roman Frigg - 2008 - Philosophy of Science 75 (5):670-681.
Reducing thermodynamics to statistical mechanics: The case of entropy.Craig Callender - 1999 - Journal of Philosophy 96 (7):348-373.
Entropy, von Neumann and the von Neumann Entropy.Dénes Petz - 2001 - Vienna Circle Institute Yearbook 8:83-96.
Boltzmann's Approach to Statistical Mechanics.Sheldon Goldstein - unknown
Microscopic non-equilibrium structure and dynamical model of entropy flow.T. Petrosky & M. Rosenberg - 1997 - Foundations of Physics 27 (2):239-259.
Is - kTr( ln ) the entropy in quantum mechanics.Orly Shenker - 1999 - British Journal for the Philosophy of Science 50 (1):33-48.
Thermodynamics: What One Needs to Know.Carl S. Helrich - 1999 - Zygon 34 (3):501-514.

Analytics

Added to PP
2016-04-13

Downloads
47 (#338,390)

6 months
5 (#639,314)

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

Time Evolution in Macroscopic Systems. II. The Entropy.W. T. Grandy - 2004 - Foundations of Physics 34 (1):21-57.

Add more references