Universal Aging Dynamics and Scaling Laws in Three-Dimensional Driven Granular Gases

Abstract

We establish universal scaling laws and quantify aging in three-dimensional uniformly heated hard sphere granular gases through large-scale event-driven molecular dynamics (N=500,000). We report three primary quantitative discoveries: (i) The characteristic energy decay time exhibits a universal inverse scaling τ0 ε-1.03 0.02 with the dissipation parameter ε = 1 - e2. (ii) The steady-state temperature follows a precise power-law Tsteady ε-1.51 0.03, reflecting the non-linear balance between thermostat heating and collisional dissipation. (iii) The velocity autocorrelation function A(τw, τ) demonstrates pronounced aging, with decay rates λ following a power-law slowing down λ(τw) τw-0.82 0.05. These results establish the first 3D quantitative benchmarks for aging in driven dissipative gases, where near-Gaussian statistics persist despite extreme structural clustering.

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