English

Driven inelastic Maxwell gases

Statistical Mechanics 2015-07-23 v2 Soft Condensed Matter

Abstract

We consider the inelastic Maxwell model, which consists of a collection of particles that are characterized by only their velocities, and evolving through binary collisions and external driving. At any instant, a particle is equally likely to collide with any of the remaining particles. The system evolves in continuous time with mutual collisions and driving taken to be point processes with rates τc1\tau_c^-{1} and τw1\tau_w^{-1} respectively. The mutual collisions conserve momentum and are inelastic, with a coefficient of restitution rr. The velocity change of a particle with velocity vv, due to driving, is taken to be Δv=(1+rw)v+η\Delta v=-(1+r_w) v+\eta, mimicking the collision with a vibrating wall, where rwr_w the coefficient of restitution of the particle with the "wall" and η\eta is Gaussian white noise. The Ornstein-Uhlenbeck driving mechanism given by dvdt=Γv+η\frac{dv}{dt}=-\Gamma v+\eta is found to be a special case of the driving modeled as a point process. Using both the continuum and discrete versions we show that while the equations for the one-particle and the two-particle velocity distribution functions do not close, the joint evolution equations of the variance and the two-particle velocity correlation functions close. With the exact formula for the variance we find that, for rw1r_w\ne-1, the system goes to a steady state. On the other hand, for rw=1r_w=-1, the system does not have a steady state. Similarly, the system goes to a steady state for the Ornstein-Uhlenbeck driving with Γ0\Gamma\not=0, whereas for the purely diffusive driving (Γ=0\Gamma=0), the system does not have a steady state.

Keywords

Cite

@article{arxiv.1408.3964,
  title  = {Driven inelastic Maxwell gases},
  author = {V. V. Prasad and Sanjib Sabhapandit and Abhishek Dhar},
  journal= {arXiv preprint arXiv:1408.3964},
  year   = {2015}
}

Comments

9 pages, 4 figures

R2 v1 2026-06-22T05:31:55.337Z