Intermediate regimes in granular Brownian motion: Superdiffusion and subdiffusion

TL;DR

This paper investigates the complex intermediate diffusion behaviors of Brownian particles in granular gases, revealing transitions from ballistic to superdiffusive, then subdiffusive, and finally normal diffusion through theoretical analysis and molecular dynamics simulations.

Contribution

It introduces a theoretical framework for understanding non-monotonous temperature ratios and diffusion regimes in granular Brownian motion with impact-velocity dependent restitution.

Findings

Temperature ratio exhibits non-monotonous behavior.

Transitions between ballistic, superdiffusive, subdiffusive, and normal diffusion regimes.

Qualitative agreement between theory and molecular dynamics simulations.

Abstract

Brownian motion in a granular gas in a homogeneous cooling state is studied theoretically and by means of molecular dynamics. We use the simplest first-principle model for the impact-velocity dependent restitution coefficient, as it follows for the model of viscoelastic spheres. We reveal that for a wide range of initial conditions the ratio of granular temperatures of Brownian and bath particles demonstrates complicated non-monotonous behavior, which results in transition between different regimes of Brownian dynamics: It starts from the ballistic motion, switches later to superballistic one and turns at still later times into subdiffusion; eventually normal diffusion is achieved. Our theory agrees very well with the MD results, although extreme computational costs prevented to detect the final diffusion regime. Qualitatively, the reported intermediate diffusion regimes are generic for granular gases with any realistic dependence of the restitution coefficient on the impact velocity.