Low Mach Number Fluctuating Hydrodynamics of Diffusively Mixing Fluids

TL;DR

This paper develops a low Mach number fluctuating hydrodynamics model for diffusive mixing of fluids with different densities, ensuring accurate fluctuation spectra and conservation, validated against molecular dynamics.

Contribution

It introduces a novel low Mach number formulation with a conservative discretization and fluctuation-dissipation balance for modeling diffusive mixing.

Findings

Model accurately captures giant concentration fluctuations.

Discretization maintains second-order accuracy and the equation of state.

Continuum simulations agree well with molecular dynamics results.

Abstract

We formulate low Mach number fluctuating hydrodynamic equations appropriate for modeling diffusive mixing in isothermal mixtures of fluids with different density and transport coefficients. These equations eliminate the fluctuations in pressure associated with the propagation of sound waves by replacing the equation of state with a local thermodynamic constraint. We demonstrate that the low Mach number model preserves the spatio-temporal spectrum of the slower diffusive fluctuations. We develop a strictly conservative finite-volume spatial discretization of the low Mach number fluctuating equations in both two and three dimensions and construct several explicit Runge-Kutta temporal integrators that strictly maintain the equation of state constraint. The resulting spatio-temporal discretization is second-order accurate deterministically and maintains fluctuation-dissipation balance in the linearized stochastic equations. We apply our algorithms to model the development of giant concentration fluctuations in the presence of concentration gradients, and investigate the validity of common simplifications such as neglecting the spatial non-homogeneity of density and transport properties. We perform simulations of diffusive mixing of two fluids of different densities in two dimensions and compare the results of low Mach number continuum simulations to hard-disk molecular dynamics simulations. Excellent agreement is observed between the particle and continuum simulations of giant fluctuations during time-dependent diffusive mixing.