@Article{AAMM-17-3, author = {Li, Jia-Le and Wai-Sun, Don and Wang, Cai-Feng and Wang, Bao-Shan}, title = {Spatial-Temporal Adaptive-Order Positivity-Preserving WENO Finite Difference Scheme with Relaxed CFL Condition for Euler Equations with Extreme Conditions}, journal = {Advances in Applied Mathematics and Mechanics}, year = {2025}, volume = {17}, number = {3}, pages = {804--839}, abstract = {

In extreme scenarios, classical high-order WENO schemes may result in non-physical states. The Positivity-Preserving Limiter (PP-Limiter) is often used to ensure positivity if CFL≤0.5 with a third-order TVD Runge-Kunta (RK3) scheme. This study proposes two novel conservative WENO-Z methods: AT-PP and AO-PP to improve efficiency with 0.5<CFL<1 if desired. The AT-PP method detects negative cells after each RK3 stage posteriori and computes a new solution with the PP-Limiter (CFL<0.5) for that step. The AO-PP method progressively lowers the WENO operator’s order and terminates with the first-order HLLC solver, proven positivity-preserving with CFL<1, only at negative cells at that RK3 stage. A single numerical flux enforces conservation at neighboring interfaces. Extensive 1D and 2D shock-tube problems were conducted to illustrate the performance of AT-PP and AO-PP with CFL=0.9. Both methods outperformed the classical PP-Limiter in accuracy and resolution, while AO-PP performed better computationally in some cases. The AO-PP method is globally conservative and accurate, adaptiveness, and robustness while resolving fine-scale structures in smooth regions, capturing strong shocks and gradients with ENO-property, improving computational efficiency, and preserving the positivity, all without imposing a restrictive limit on the CFL condition.

}, issn = {2075-1354}, doi = {https://doi.org/10.4208/aamm.OA-2023-0306}, url = {https://global-sci.com/article/91706/spatial-temporal-adaptive-order-positivity-preserving-weno-finite-difference-scheme-with-relaxed-cfl-condition-for-euler-equations-with-extreme-conditions} }