Litcius/Paper detail

An entropy scaling demarcation of gas- and liquid-like fluid behaviors

Ian H. Bell, Guillaume Galliéro, Stéphanie Delage Santacreu, Lorenzo Costigliola

2020The Journal of Chemical Physics43 citationsDOIOpen Access PDF

Abstract

In this work, we propose a generic and simple definition of a line separating gas-like and liquid-like fluid behaviors from the standpoint of shear viscosity. This definition is valid even for fluids such as the hard sphere and the inverse power law that exhibit a unique fluid phase. We argue that this line is defined by the location of the minimum of the macroscopically scaled viscosity when plotted as a function of the excess entropy, which differs from the popular Widom lines. For hard sphere, Lennard-Jones, and inverse-power-law fluids, such a line is located at an excess entropy approximately equal to -2/3 times Boltzmann's constant and corresponds to points in the thermodynamic phase diagram for which the kinetic contribution to viscosity is approximately half of the total viscosity. For flexible Lennard-Jones chains, the excess entropy at the minimum is a linear function of the chain length. This definition opens a straightforward route to classify the dynamical behavior of fluids from a single thermodynamic quantity obtainable from high-accuracy thermodynamic models.

Topics & Concepts

ScalingThermodynamicsInversePower lawStatistical physicsEntropy (arrow of time)Phase diagramComplex fluidPhysicsViscosityShear viscosityPhase (matter)MathematicsGeometryStatisticsQuantum mechanicsPhase Equilibria and ThermodynamicsMaterial Dynamics and PropertiesAdvanced Thermodynamics and Statistical Mechanics