Pressure and surface tension of an active simple liquid: a comparison between kinetic, mechanical and free-energy based approaches

TL;DR

This paper compares three different approaches—kinetic, mechanical, and free-energy based—to defining pressure in an active particle system driven by non-thermal noise, showing they agree up to first order.

Contribution

It demonstrates the equivalence of three pressure definitions in active matter systems and links the partition function to non-equilibrium thermodynamics.

Findings

All three approaches yield the same pressure results.

The partition function determines the stationary non-equilibrium thermodynamics.

The mechanical approach provides local pressure and surface tension in inhomogeneous systems.

Abstract

We discuss different definitions of pressure for a system of active spherical particles driven by a non-thermal coloured noise. We show that mechanical, kinetic and free-energy based approaches lead to the same result up to first order in the non-equilibrium expansion parameter. The first prescription is based on a generalisation of the kinetic mesoscopic virial equation and expresses the pressure exerted on the walls in terms of the average of the virial of the inter-particle forces. In the second approach, the pressure and the surface tension are identified with the volume and area derivatives, respectively, of the partition function associated with the known stationary non-equilibrium distribution of the model. The third method is a mechanical approach and is related to the work necessary to deform the system. The pressure is obtained by comparing the expression of the work in terms of local stress and strain with the corresponding expression in terms of microscopic distribution. This is determined from the force balance encoded in the Born-Green-Yvon equation. Such a method has the advantage of giving a formula for the local pressure tensor and the surface tension even in inhomogeneous situations. By direct inspection, we show that the three procedures lead to the same values of the pressure, and give support to the idea that the partition function, obtained via the unified coloured noise approximation, is more than a formal property of the system, but determines the stationary non-equilibrium thermodynamics of the model.