# Unified Gas-kinetic Wave-Particle Methods II: Multiscale Simulation on   Unstructured Mesh

**Authors:** Yajun Zhu, Chang Liu, Chengwen Zhong, Kun Xu

arXiv: 1903.11861 · 2021-01-26

## TL;DR

This paper introduces a unified gas-kinetic wave-particle (UGKWP) method on unstructured meshes for efficient multiscale flow simulation, seamlessly bridging continuum and rarefied regimes with significant computational savings.

## Contribution

The paper develops a novel UGKWP method that adaptively combines wave and particle descriptions, enabling accurate multiscale flow simulation on unstructured meshes without restrictive time step or mesh size constraints.

## Key findings

- Achieves UGKS-level accuracy across all flow regimes.
- Reduces computational cost and memory usage by several orders of magnitude.
- Successfully validated through multiple numerical test cases.

## Abstract

In this paper, we present a unified gas-kinetic wave-particle (UGKWP) method on unstructured mesh for multiscale simulation of continuum and rarefied flow. Inheriting from the multicale transport in the unified gas-kinetic scheme (UGKS), the integral solution of kinetic model equation is employed in the construction of UGKWP method to model the flow physics in the cell size and time step scales. A novel wave-particle adaptive formulation is introduced in the UGKWP method to describe the flow dynamics in each control volume. The local gas evolution is constructed through the dynamical interaction of the deterministic hydrodynamic wave and the stochastic kinetic particle. Within the resolution of cell size and time step, the decomposition, interaction, and evolution of the hydrodynamic wave and the kinetic particle depend on the ratio of the time step to the local particle collision time. In the rarefied flow regime, the flow physics is mainly recovered by the discrete particles and the UGKWP method performs as a stochastic particle method. In the continuum flow regime, the flow behavior is solely followed by macroscopic variable evolution and the UGKWP method becomes a gas-kinetic hydrodynamic flow solver for the viscous and heat-conducting Navier--Stokes solutions. In different flow regimes, many numerical test cases are computed to validate the UGKWP method on unstructured mesh. The UGKWP method can get the same UGKS solutions in all Knudsen regimes without the requirement of the time step and mesh size being less than than the particle collision time and mean free path. With an automatic wave-particle decomposition, the UGKWP method becomes very efficient. For example, at Mach number 30 and Knudsen number 0.1, in comparison with UGKS several-order-of-magnitude reductions in computational cost and memory requirement have been achieved by UGKWP.

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## References

61 references — full list in the complete paper: https://tomesphere.com/paper/1903.11861/full.md

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Source: https://tomesphere.com/paper/1903.11861