A Multiscale Kinetic-Fluid Solver with Dynamic Localization of Kinetic Effects

TL;DR

This paper introduces a multiscale kinetic-fluid solver that dynamically localizes kinetic effects in fluid simulations, improving efficiency in regions with non-equilibrium phenomena through a micro-macro decomposition and adaptive transition criteria.

Contribution

The work develops a robust multiscale solver with dynamic localization of kinetic effects, combining fluid and kinetic models with a new criterion based on the distribution function.

Findings

The method accurately captures localized non-equilibrium regions.

It demonstrates improved computational efficiency over traditional methods.

Numerical examples validate the dynamic transition approach.

Abstract

This paper collects the efforts done in our previous works [P. Degond, S. Jin, L. Mieussens, A Smooth Transition Between Kinetic and Hydrodynamic Equations, J. Comp. Phys., 209 (2005) 665--694.],[P.Degond, G. Dimarco, L. Mieussens, A Moving Interface Method for Dynamic Kinetic-fluid Coupling, J. Comp. Phys., Vol. 227, pp. 1176-1208, (2007).],[P. Degond, J.G. Liu, L. Mieussens, Macroscopic Fluid Model with Localized Kinetic Upscaling Effects, SIAM Multi. Model. Sim. 5(3), 940--979 (2006)] to build a robust multiscale kinetic-fluid solver. Our scope is to efficiently solve fluid dynamic problems which present non equilibrium localized regions that can move, merge, appear or disappear in time. The main ingredients of the present work are the followings ones: a fluid model is solved in the whole domain together with a localized kinetic upscaling term that corrects the fluid model wherever it is necessary; this multiscale description of the flow is obtained by using a micro-macro decomposition of the distribution function [P. Degond, J.G. Liu, L. Mieussens, Macroscopic Fluid Model with Localized Kinetic Upscaling Effects, SIAM Multi. Model. Sim. 5(3), 940--979 (2006)]; the dynamic transition between fluid and kinetic descriptions is obtained by using a time and space dependent transition function; to efficiently define the breakdown conditions of fluid models we propose a new criterion based on the distribution function itself. Several numerical examples are presented to validate the method and measure its computational efficiency.