Non-equilibrium behavior at a liquid-gas critical point

TL;DR

This study investigates non-equilibrium critical behavior in a liquid-gas model, revealing stable equilibrium-like behavior and unstable anisotropic fixed points, with implications for understanding phase transitions under non-equilibrium conditions.

Contribution

It introduces a dynamic field theory analysis of non-equilibrium liquid-gas critical points, identifying new unstable fixed points and critical exponents for anisotropic noise conditions.

Findings

Stable fixed point reproduces equilibrium critical behavior.

Unstable fixed point features diverging temperature ratios.

Anisotropic noise leads to critical softening in perpendicular directions.

Abstract

Second-order phase transitions in a non-equilibrium liquid-gas model with reversible mode couplings, i.e., model H for binary-fluid critical dynamics, are studied using dynamic field theory and the renormalization group. The system is driven out of equilibrium either by considering different values for the noise strengths in the Langevin equations describing the evolution of the dynamic variables (effectively placing these at different temperatures), or more generally by allowing for anisotropic noise strengths, i.e., by constraining the dynamics to be at different temperatures in d_par- and d_perp-dimensional subspaces, respectively. In the first, case, we find one infrared-stable and one unstable renormalization group fixed point. At the stable fixed point, detailed balance is dynamically restored, with the two noise strengths becoming asymptotically equal. The ensuing critical behavior is that of the standard equilibrium model H. At the novel unstable fixed point, the temperature ratio for the dynamic variables is renormalized to infinity, resulting in an effective decoupling between the two modes. We compute the critical exponents at this new fixed point to one-loop order. For model H with spatially anisotropic noise, we observe a critical softening only in the d_perp-dimensional sector in wave vector space with lower noise temperature. The ensuing effective two-temperature model H does not have any stable fixed point in any physical dimension, at least to one-loop order. We obtain formal expressions for the novel critical exponents in a double expansion about the upper critical dimension d_c = 4 - d_par and with respect to d_par, i.e., about the equilibrium theory.