Extending Israel and Stewart hydrodynamics to relativistic superfluids via Carter's multifluid approach

TL;DR

This paper develops a relativistic superfluid hydrodynamics model extending Israel-Stewart theory, incorporating dissipation via Carter's multifluid approach, predicting four bulk viscosity coefficients with microscopic derivations and frequency-dependent relaxation effects.

Contribution

It introduces a novel relativistic superfluid model based on Carter's multifluid approach, extending Israel-Stewart theory to include bulk viscosity and heat conduction with microscopic formulas.

Findings

Predicts four bulk viscosity coefficients with explicit formulas.

Extends Israel-Stewart theory to relativistic superfluids.

Accounts for frequency dependence in bulk viscosity relaxation.

Abstract

We construct a relativistic model for bulk viscosity and heat conduction in a superfluid. Building on the principles of Unified Extended Irreversible Thermodynamics, the model is derived from Carter's multifluid approach for a theory with 3 four-currents: particles, entropy, and quasi-particles. Dissipation arises directly from the fact that the quasi-particle four-current is an independent degree of freedom that does not necessarily comove with the entropy. For small deviations from local thermodynamic equilibrium, the model provides an extension of the Israel-Stewart theory to superfluid systems. It can, therefore, be made hyperbolic, causal and stable if the microscopic input is accurate. The non-dissipative limit of the model is the relativistic two-fluid model of Carter, Khalatnikov and Gusakov. The Newtonian limit of the model is an Extended-Irreversible-Thermodynamic extension of Landau's two-fluid model. The model predicts the existence of four bulk viscosity coefficients and accounts for their microscopic origin, providing their exact formulas in terms of the quasi-particle creation rate. Furthermore, when fast oscillations of small amplitude around the equilibrium are considered, the relaxation-time term in the telegraph-type equations for the bulk viscosities accounts directly for their expected dependence on the frequency.