Explicit-Implicit Domain Splitting for Two Phase Flows with Phase Transition

TL;DR

This paper introduces an explicit-implicit domain splitting method for simulating two-phase flows with phase transitions, improving computational efficiency by handling tiny cells implicitly while maintaining explicit treatment elsewhere.

Contribution

The paper proposes a novel explicit-implicit domain splitting approach combined with dual time stepping for efficient simulation of phase transition flows with sharp interfaces.

Findings

The new scheme is robust and stable.

It achieves significant speed-up over fully explicit methods.

It effectively handles tiny cells near phase interfaces.

Abstract

Two phase flows that include phase transition, especially phase creation, with a sharp interface remain a challenging task for numerics. We consider the isothermal Euler equations with phase transition between a liquid and a vapor phase. The phase interface is modeled as a sharp interface and the mass transfer across the phase boundary is modeled by a kinetic relation. Existence and uniqueness results were proven in Ref. \cite{Hantke2019a}. Using sharp interfaces for simulating nucleation and cavitation results in the grid containing tiny cells that are several orders of magnitude smaller than the remaining grid cells. This forces explicit time stepping schemes to take tiny time steps on these cells. As a remedy we suggest an explicit implicit domain splitting where the majority of the grid cells is treated explicitly and only the neighborhood of the tiny cells is treated implicitly. We use dual time stepping to solve the resulting small implicit systems. Our numerical results indicate that the new scheme is robust and provides significant speed-up compared to a fully explicit treatment.