Equilibration of Concentrated Hard Sphere Fluids

Abstract

We report a systematic molecular dynamics study of the isochoric equilibration of hard-sphere fluids in their metastable regime close to the glass transition. The thermalization process starts with the system prepared in a non-equilibrium state with the desired final volume fraction φ but with a prescribed non-equilibrium static structure factor S0(k; φ). The evolution of the α- relaxation time τα (k) and long-time self-diffusion coefficient DL as a function of the evolution time tw is then monitored for an array of volume fractions. For a given waiting time the plot of τα (k; φ, tw) as a function of φ exhibits two regimes corresponding to samples that have fully equilibrated within this waiting time (φ ≤ φ(c) (tw)), and to samples for which equilibration is not yet complete (φ ≥ φ(c) (tw)). The crossover volume fraction φ(c) (tw) increases with tw but seems to saturate to a value φ(a) φ(c) (tw → ∞) ≈ 0.582. We also find that the waiting time t(eq)w(φ) required to equilibrate a system grows faster than the corresponding equilibrium relaxation time, t(eq)(φ) ≈ 0.27 × [τα (k; φ)]1.43, and that both characteristic times increase strongly as φ approaches φ(a), thus suggesting that the measurement of equilibrium properties at and above φ(a) is experimentally impossible.