TY  - EJOU
AU  - Jiang, Zhenhua 
AU  - Deng, Xi 
AU  - Zhang, Xin 
AU  - Yan, Chao 
AU  - Xiao, Feng 
AU  - Yu, Jian 

TI  - High-Order DG Schemes with Subcell Limiting Strategies for Simulations of Shocks, Vortices and Sound Waves in Materials Science Problems
T2  - Fluid Dynamics \& Materials Processing

PY  - 2024
VL  - 20
IS  - 10
SN  - 1555-2578

AB  - Shock waves, characterized by abrupt changes in pressure, temperature, and density, play a significant role in various materials science processes involving fluids. These high-energy phenomena are utilized across multiple fields and applications to achieve unique material properties and facilitate advanced manufacturing techniques. Accurate simulations of these phenomena require numerical schemes that can represent shock waves without spurious oscillations and simultaneously capture acoustic waves for a wide range of wavelength scales. This work suggests a high-order discontinuous Galerkin (DG) method with a finite volume (FV) subcell limiting strategies to achieve better subcell resolution and lower numerical diffusion properties. By switching to the FV discretization on an embedded sub-cell grid, the method displays advantages with respect to both DG accuracy and FV shock-capturing ability. The FV scheme utilizes a class of high-fidelity schemes that are built upon the boundary variation diminishing (BVD) reconstruction paradigm. The method is therefore able to resolve discontinuities and multi-scale structures on the subcell level, while preserving the favorable properties of the high-order DG scheme. We have tested the present DG method up to the 6th-order accuracy for both smooth and discontinuous noise problems.
KW  - Discontinuous Galerkin; finite volume; subcell limiting; shock associated noise; computational aeroacoustics

DO  - 10.32604/fdmp.2024.053231