Thermodynamics of condensed matter with strong pressure-energy correlations

Abstract

We show that for any liquid or solid with strong correlation between its NVT virial and potential-energy equilibrium fluctuations, the temperature is a product of a function of excess entropy per particle and a function of density, T=f(s)h(). This implies that 1) the system's isomorphs (curves in the phase diagram of invariant structure and dynamics) are described by h()/T= Const., 2) the density-scaling exponent is a function of density only, 3) a Gr\"uneisen-type equation of state applies for the configurational degrees of freedom. For strongly correlating atomic systems one has h()=ΣnCnn/3 in which the only non-zero terms are those appearing in the pair potential expanded as v(r)=Σn vn r-n. Molecular dynamics simulations of Lennard-Jones type systems confirm the theory.