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Abstract
Riemann problems for the compressible Euler system in two space dimensions are complicated and difficult, but a viable alternative remains missing. The author lists merits of one-dimensional Riemann problems and compares them with those for the current two-dimensional Riemann problems, to illustrate their worthiness. Two-dimensional Riemann problems are approached via the methodology promoted by Andy Majda in the spirits of modern applied mathematics; that is, simplified model is built via asymptotic analysis, numerical simulation and theoretical analysis. A simplified model called the pressure gradient system is derived from the full Euler system via an asymptotic process. State-of-the-art numerical methods in numerical simulations are used to discern smallscale structures of the solutions, e.g., semi-hyperbolic patches. Analytical methods are used to establish the validity of the structure revealed in the numerical simulation. The entire process, used in many of Majda’s programs, is shown here for the two-dimensional Riemann problems for the compressible Euler systems of conservation laws.
Keywords
Characteristic decomposition
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Guderley reflection
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Hodograph transform
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Pressure gradient system
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Self-similar
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Semi-hyperbolic wave
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Triple point paradox
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Riemann problem
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Riemann variable
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Yuxi Zheng.
Two-dimensional Riemann problems for the compressible Euler system.
Chinese Annals of Mathematics, Series B, 2009, 30(6): 845-858 DOI:10.1007/s11401-009-0114-5
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