Dynamic properties in a collisional model for confined granular fluids. A review

TL;DR

This review discusses a simplified collisional model for confined granular fluids driven by vertical vibration, analyzing its kinetic theory, hydrodynamics, and agreement with simulations.

Contribution

It introduces and analyzes the $ ext{ extDelta}$-model, extending kinetic theory to granular mixtures and deriving hydrodynamic equations with transport coefficients.

Findings

The $ ext{ extDelta}$-model predicts stable homogeneous states.

Hydrodynamic equations show unconditional stability.

Theoretical results agree with simulations.

Abstract

Granular systems confined in a shallow box and driven by vertical vibration provide a simple geometry to study fluidized granular media. Grains gain kinetic energy vertically through collisions with the walls and redistribute it horizontally via interparticle collisions. The $\Delta$-model has been proposed as a simplified description of this setup. In this model, a fixed velocity increment $\Delta$ is added to the normal component of the relative velocity at collisions, effectively integrating out the vertical motion while preserving collisional energy injection. This compensates for inelastic losses and yields stable homogeneous steady states amenable to kinetic theory. An Enskog kinetic equation is formulated and analyzed to obtain the stationary temperature and equation of state. The Chapman--Enskog method is then applied to derive the Navier--Stokes transport coefficients and study inhomogeneous states. The theory is extended to granular mixtures with different masses, sizes, restitution coefficients, or $\Delta$ values, leading to nonequipartition of energy even in homogeneous states. The resulting hydrodynamic equations, with transport coefficients obtained in the low-density regime, show unconditional stability of the homogeneous state and violation of Onsager reciprocity. Theoretical predictions agree well with molecular dynamics and direct simulation Monte Carlo results.