A maximum entropy mean field method for driven diffusive systems

Autor:	Yitzhak Shnidman, Royce K.P. Zia, Nina Pesheva
Rok vydání:	1993
Předmět:	Mean field theory Stochastic process Principle of maximum entropy Maxwell construction Master equation Statistical and Nonlinear Physics Ising model Detailed balance Statistical physics Statistical mechanics Mathematical Physics Mathematics
Zdroj:	Journal of Statistical Physics. 70:737-771
ISSN:	1572-9613 0022-4715
DOI:	10.1007/bf01053593
Popis:	We introduce a method of generating systematic mean field (MF) approximations for the nonequilibrium steady state of ferromagnetic Ising driven diffusive systems (DDS), based on the maximum entropy principle due to Jaynes. In the phase coexistence region, MF approximations to the master equation do not provide a closed system of equations in the MF variables. This can be traced to the conservation of the order parameter by the stochastic dynamics. Our maximum entropy mean field (MEMF) approximation method is applicable to high temperatures as well to the low-temperature phase coexistence region. It is based on a derivation of a generalized variational free energy from the maximum entropy principle, with the MF evolution equations playing the role of constraints. In the phase coexistence region this free energy is nonconvex and is interpreted by means of a Maxwell construction. We use a pair-level variant of the MEMF approximation to calculate quantities of interest for the ferro-magnetic Ising DDS on a square lattice. Results of calculations with several different choices of transition rates satisfying local detailed balance are discussed and compared with those obtained by other methods.
Databáze:	OpenAIRE
Externí odkaz:	https://explore.openaire.eu/search/publication?articleId=doi_________::5f8da88be44a239fa0bc03becd665e00 https://doi.org/10.1007/bf01053593 Zobrazit plný text záznamu Full text from SpringerLink