A novel Cercignani-Lampis boundary model for discrete velocity methods in predicting rarefied and multi-scale flows

TL;DR

This paper introduces a new Cercignani-Lampis boundary model integrated into discrete velocity and unified gas-kinetic schemes, improving the simulation of rarefied and multi-scale gas flows with realistic boundary conditions.

Contribution

It develops a novel CL boundary model for DVM and UGKS, enabling accurate simulation of complex gas flows with various accommodation coefficients and boundary conditions.

Findings

Validated across a wide range of Knudsen and Mach numbers.

Improved boundary condition modeling for rarefied flows.

Enhanced performance in flow prediction with implicit schemes.

Abstract

To extend the discrete velocity method (DVM) and unified methods to more realistic boundary conditions, a Cercignani-Lampis (CL) boundary with different momentum and thermal energy accommodations is proposed and integrated into the DVM framework. By giving the macroscopic flux from the numerical quadrature of the incident molecular distribution, the reflected macroscopic flux can be obtained for the given accommodation coefficients. Then, an anisotropic Gaussian distribution can be found for the reflected molecules, whose parameters are determined by the calculated reflected macroscopic flux. These macroscopic flux and microscopic Gaussian distribution form a complete physical process for the reflected molecules. Furthermore, the CL boundary is integrated into the unified gas-kinetic scheme (UGKS), making it suitable for the simulation of both monatomic and diatomic gas flows, and it accommodates both the conventional Cartesian velocity space and the recently developed efficient unstructured velocity space. Moreover, this new GSI boundary is suitable for both explicit and implicit schemes, offering better performance for flow prediction. Finally, the performance of the new boundary is validated through a series of numerical tests covering a wide range of Knudsen and Mach numbers.