Formulation of entropy-conservative discretizations for compressible flows of thermally perfect gases
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This study proposes a novel spatial discretization procedure for the compressible Euler equations that guarantees entropy conservation at a discrete level for thermally perfect gases. The procedure is based on a locally conservative formulation, and extends the entropy-conserving schemes to the more realistic case of thermally perfect gases, while still guaranteeing preservation of both linear invariants and kinetic energy. The proposed methodology, which can also be extended to multicomponent gases and to an Asymptotically Entropy-Conservative formulation, shows advantages in terms of accuracy and robustness when compared to existing similar approaches.
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Cited by 2 Pith papers
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Pressure-equilibrium-preserving and fully conservative discretization of compressible flow equations for real and thermally perfect gases
A discretization scheme for the compressible Euler equations that fully conserves linear invariants and exactly preserves pressure equilibrium via EOS-dependent nonlinear fluxes for mass and internal energy.
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Entropy-stable discretizations for the compressible Euler equations using simple adaptive averages
Entropy-stable discretizations for the compressible Euler equations are achieved by adapting averages on density and internal energy using simple symmetric means such as arithmetic or geometric averages.
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