Heuristic derivation of continuum kinetic equations from microscopic
  dynamics

B. Dammann; B. Schmittmann; B. Schmittmann; C. DeDominicis; D. P. Landau; F. de los Santos; F. de los Santos; G. Korniss; H. A. Rose; H. K. Janssen; H. K. Janssen; J. S. Langer; K. Kawasaki; K.-t. Leung; K.-t. Leung; K.-t. Leung; K.-t. Leung; K.-t. Leung; Kwan-tai Leung; L. Peliti; M. C. Cross; M. Doi; M. F. Sykes; M. Kardar; N. G. van Kampen; N.G. van Kampen; P. C. Hohenberg; P. Grassberger; P. L. Garrido; P. Langevin; R. J. Glauber; S. Katz; Z. Racz

research

Heuristic derivation of continuum kinetic equations from microscopic dynamics

Authors: B. Dammann
B. Schmittmann
B. Schmittmann
C. DeDominicis
D. P. Landau
F. de los Santos
F. de los Santos
G. Korniss
H. A. Rose
H. K. Janssen
H. K. Janssen
J. S. Langer
K. Kawasaki
K.-t. Leung
K.-t. Leung
K.-t. Leung
K.-t. Leung
K.-t. Leung
Kwan-tai Leung
L. Peliti
M. C. Cross
M. Doi
M. F. Sykes
M. Kardar
N. G. van Kampen
N.G. van Kampen
P. C. Hohenberg
P. Grassberger
P. L. Garrido
P. Langevin
R. J. Glauber
S. Katz
Z. Racz
Publication date: 14 June 2000
Publisher: 'American Physical Society (APS)'
Doi

Abstract

We present an approximate and heuristic scheme for the derivation of continuum kinetic equations from microscopic dynamics for stochastic, interacting systems. The method consists of a mean-field type, decoupled approximation of the master equation followed by the `naive' continuum limit. The Ising model and driven diffusive systems are used as illustrations. The equations derived are in agreement with other approaches, and consequences of the microscopic dependences of coarse-grained parameters compare favorably with exact or high-temperature expansions. The method is valuable when more systematic and rigorous approaches fail, and when microscopic inputs in the continuum theory are desirable.Comment: 7 pages, RevTeX, two-column, 4 PS figures include

Similar works

Full text

Available Versions

Crossref

Last time updated on 02/01/2020