Finite-rate chemistry in hypersonic shock-wave/turbulent boundary-layer interaction produces a smaller separation bubble, lower wall heat flux, and lower temperatures than perfect-gas models at Me=6.4 and He=16.9 MJ/kg.
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Adaptive high-order and low-order dissipative fluxes augment central-difference schemes to enforce scalar boundedness in multi-component turbulent flows with minimal added dissipation.
GPU port of entropy-stable DG Euler solver with non-conservative buoyancy terms reaches nearly 70% of 64-bit peak on A100 volume kernels, delivers 10x speedup and 13x better energy efficiency versus CPU, and preserves symmetry-based flux savings.
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Effects of thermochemical modelling on a hypersonic shock-wave/turbulent boundary-layer interaction
Finite-rate chemistry in hypersonic shock-wave/turbulent boundary-layer interaction produces a smaller separation bubble, lower wall heat flux, and lower temperatures than perfect-gas models at Me=6.4 and He=16.9 MJ/kg.
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Formulations for scalar boundedness in simulations of turbulent compressible multi-component flows using high-order finite-difference methods
Adaptive high-order and low-order dissipative fluxes augment central-difference schemes to enforce scalar boundedness in multi-component turbulent flows with minimal added dissipation.
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GPU Performance of an Entropy-Stable Discontinuous Galerkin Euler Solver with Non-Conservative Terms
GPU port of entropy-stable DG Euler solver with non-conservative buoyancy terms reaches nearly 70% of 64-bit peak on A100 volume kernels, delivers 10x speedup and 13x better energy efficiency versus CPU, and preserves symmetry-based flux savings.