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Entropy conditions for scalar conservation laws with discontinuous flux revisited. (English) Zbl 1343.35158

Summary: We propose new entropy admissibility conditions for multidimensional hyperbolic scalar conservation laws with discontinuous flux which generalize one-dimensional Karlsen-Risebro-Towers entropy conditions. These new conditions are designed, in particular, in order to characterize the limit of vanishing viscosity approximations. On the one hand, they comply quite naturally with a certain class of physical and numerical modeling assumptions; on the other hand, their mathematical assessment turns out to be intricate.
The generalization we propose is not only with respect to the space dimension, but mainly in the sense that the “crossing condition” of K. H. Karlsen et al. [Skr., K. Nor. Vidensk. Selsk. 2003, No. 3, 49 p. (2003; Zbl 1036.35104)] is not mandatory for proving uniqueness with the new definition. We prove uniqueness of solutions and give tools to justify their existence via the vanishing viscosity method, for the multi-dimensional spatially inhomogeneous case with a finite number of Lipschitz regular hypersurfaces of discontinuity for the flux function.

MSC:

35L65 Hyperbolic conservation laws
35L67 Shocks and singularities for hyperbolic equations
35A02 Uniqueness problems for PDEs: global uniqueness, local uniqueness, non-uniqueness

Citations:

Zbl 1036.35104
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References:

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