A Second Order Fully-discrete Linear Energy Stable Scheme for a Binary Compressible Viscous Fluid Model

TL;DR

This paper introduces a second-order, fully discrete, energy-stable numerical scheme for a binary compressible fluid model, ensuring mass conservation and energy dissipation, with proven solvability and demonstrated effectiveness through numerical examples.

Contribution

It develops a novel linear, second-order, energy-stable scheme for a thermodynamically consistent binary fluid model, combining energy quadratization and staggered grid discretization.

Findings

Scheme preserves mass and energy dissipation laws.

Proven unique solvability of the linear system.

Numerical examples confirm convergence and applicability.

Abstract

We present a linear, second order fully discrete numerical scheme on a staggered grid for a thermodynamically consistent hydrodynamic phase field model of binary compressible fluid flow mixtures derived from the generalized Onsager Principle. The hydrodynamic model not only possesses the variational structure, but also warrants the mass, linear momentum conservation as well as energy dissipation. We first reformulate the model in an equivalent form using the energy quadratization method and then discretize the reformulated model to obtain a semi-discrete partial differential equation system using the Crank-Nicolson method in time. The numerical scheme so derived preserves the mass conservation and energy dissipation law at the semi-discrete level. Then, we discretize the semi-discrete PDE system on a staggered grid in space to arrive at a fully discrete scheme using the 2nd order finite difference method, which respects a discrete energy dissipation law. We prove the unique solvability of the linear system resulting from the fully discrete scheme. Mesh refinements and two numerical examples on phase separation due to the spinodal decomposition in two polymeric fluids and interface evolution in the gas-liquid mixture are presented to show the convergence property and the usefulness of the new scheme in applications.