English

Classical small systems coupled to finite baths

Statistical Mechanics 2015-05-20 v3

Abstract

We have studied the properties of a classical NSN_S-body system coupled to a bath containing NBN_B-body harmonic oscillators, employing an (NS+NB)(N_S+N_B) model which is different from most of the existing models with NS=1N_S=1. We have performed simulations for NSN_S-oscillator systems, solving 2(NS+NB)2(N_S+N_B) first-order differential equations with NS110N_S \simeq 1 - 10 and NB101000N_B \simeq 10 - 1000, in order to calculate the time-dependent energy exchange between the system and the bath. The calculated energy in the system rapidly changes while its envelope has a much slower time dependence. Detailed calculations of the stationary energy distribution of the system fS(u)f_S(u) (uu: an energy per particle in the system) have shown that its properties are mainly determined by NSN_S but weakly depend on NBN_B. The calculated fS(u)f_S(u) is analyzed with the use of the Γ\Gamma and qq-Γ\Gamma distributions: the latter is derived with the superstatistical approach (SSA) and microcanonical approach (MCA) to the nonextensive statistics, where qq stands for the entropic index. Based on analyses of our simulation results, a critical comparison is made between the SSA and MCA. Simulations have been performed also for the NSN_S-body ideal-gas system. The effect of the coupling between oscillators in the bath has been examined by additional (NS+NBN_S+N_B) models which include baths consisting of coupled linear chains with periodic and fixed-end boundary conditions.

Keywords

Cite

@article{arxiv.1010.4292,
  title  = {Classical small systems coupled to finite baths},
  author = {Hideo Hasegawa},
  journal= {arXiv preprint arXiv:1010.4292},
  year   = {2015}
}

Comments

30 pages, 16 figures; the final version accepted in Phys. Rev. E

R2 v1 2026-06-21T16:31:46.713Z