Phase-field model for the Rayleigh--Taylor instability of immiscible fluids

TL;DR

This paper develops a phase-field model for Rayleigh--Taylor instability in immiscible fluids, enabling detailed analysis of linear and nonlinear stages, including bubble velocity, with good agreement to theory.

Contribution

It introduces a phase-field approach coupled with Navier--Stokes equations to model Rayleigh--Taylor instability, accurately capturing linear and nonlinear dynamics.

Findings

Rederived gravity-capillary dispersion relation analytically.

Numerical simulations match known linear phase properties.

Measured terminal bubble velocity agrees with theoretical predictions.

Abstract

The Rayleigh--Taylor instability of two immiscible fluids in the limit of small Atwood numbers is studied by means of a phase-field description. In this method the sharp fluid interface is replaced by a thin, yet finite, transition layer where the interfacial forces vary smoothly. This is achieved by introducing an order parameter (the phase field) whose variation is continuous across the interfacial layers and is uniform in the bulk region. The phase field model obeys a Cahn--Hilliard equation and is two-way coupled to the standard Navier--Stokes equations. Starting from this system of equations we have first performed a linear analysis from which we have analytically rederived the known gravity-capillary dispersion relation in the limit of vanishing mixing energy density and capillary width. We have performed numerical simulations and identified a region of parameters in which the known properties of the linear phase (both stable and unstable) are reproduced in a very accurate way. This has been done both in the case of negligible viscosity and in the case of nonzero viscosity. In the latter situation only upper and lower bounds for the perturbation growth-rate are known. Finally, we have also investigated the weakly-nonlinear stage of the perturbation evolution and identified a regime characterized by a constant terminal velocity of bubbles/spikes. The measured value of the terminal velocity is in perfect agreement with available theoretical prediction. The phase-field approach thus appears to be a valuable tecnhique for the dynamical description of the stages where hydrodynamic turbulence and wave-turbulence enter into play.