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High-order accurate entropy stable finite difference schemes for one- and two-dimensional special relativistic hydrodynamics

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arxiv 1905.06092 v1 pith:RE26EUMK submitted 2019-05-15 math.NA cs.NA

High-order accurate entropy stable finite difference schemes for one- and two-dimensional special relativistic hydrodynamics

classification math.NA cs.NA
keywords entropyschemesconservativehigh-ordersemi-discretestableaccurateflux
verification ladder T0 review T1 audit T2 compute T3 formal T4 reserved
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This paper develops the high-order accurate entropy stable finite difference schemes for one- and two-dimensional special relativistic hydrodynamic equations. The schemes are built on the entropy conservative flux and the weighted essentially non-oscillatory (WENO) technique as well as explicit Runge-Kutta time discretization. The key is to technically construct the affordable entropy conservative flux of the semi-discrete second-order accurate entropy conservative schemes satisfying the semi-discrete entropy equality for the found convex entropy pair. As soon as the entropy conservative flux is derived, the dissipation term can be added to give the semi-discrete entropy stable schemes satisfying the semi-discrete entropy inequality with the given convex entropy function. The WENO reconstruction for the scaled entropy variables and the high-order explicit Runge-Kutta time discretization are implemented to obtain the fully-discrete high-order schemes. Several numerical tests are conducted to validate the accuracy and the ability to capture discontinuities of our entropy stable schemes.

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  1. Admissible Lax-Wendroff Flux Reconstruction Method with Automatic Differentiation on Adaptive Curved Meshes for Relativistic Hydrodynamics

    math.NA 2026-04 unverdicted novelty 7.0

    An admissible Lax-Wendroff flux reconstruction method with automatic differentiation and subcell blending enables robust high-order simulations of relativistic hydrodynamics on adaptive curved meshes.