Information geometry in vapour-liquid equilibrium

TL;DR

This paper explores how information geometry, using the square-root map, can describe vapour-liquid equilibrium, revealing geometric features that relate to physical properties like phase transitions and stability.

Contribution

It provides a geometric characterization of the family of Gaussian densities and applies this framework to analyze vapour-liquid phase transitions.

Findings

Geometry of M is flat for ideal gases.

Scalar curvature diverges at the spinodal boundary for van der Waals gases.

Geometric features relate to system stability and phase behavior.

Abstract

Using the square-root map p-->\sqrt{p} a probability density function p can be represented as a point of the unit sphere S in the Hilbert space of square-integrable functions. If the density function depends smoothly on a set of parameters, the image of the map forms a Riemannian submanifold M in S. The metric on M induced by the ambient spherical geometry of S is the Fisher information matrix. Statistical properties of the system modelled by a parametric density function p can then be expressed in terms of information geometry. An elementary introduction to information geometry is presented, followed by a precise geometric characterisation of the family of Gaussian density functions. When the parametric density function describes the equilibrium state of a physical system, certain physical characteristics can be identified with geometric features of the associated information manifold M. Applying this idea, the properties of vapour-liquid phase transitions are elucidated in geometrical terms. For an ideal gas, phase transitions are absent and the geometry of M is flat. In this case, the solutions to the geodesic equations yield the adiabatic equations of state. For a van der Waals gas, the associated geometry of M is highly nontrivial. The scalar curvature of M diverges along the spinodal boundary which envelopes the unphysical region in the phase diagram. The curvature is thus closely related to the stability of the system.