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Steady transonic shocks and free boundary problems in infinite cylinders for the Euler equations
Author(s) -
Chen GuiQiang,
Feldman Mikhail
Publication year - 2004
Publication title -
communications on pure and applied mathematics
Language(s) - English
Resource type - Journals
SCImago Journal Rank - 3.12
H-Index - 115
eISSN - 1097-0312
pISSN - 0010-3640
DOI - 10.1002/cpa.3042
Subject(s) - transonic , euler equations , free boundary problem , mathematics , mathematical analysis , conservation law , boundary value problem , bernoulli's principle , nonlinear system , boundary (topology) , shock (circulatory) , hyperbolic partial differential equation , physics , mechanics , partial differential equation , aerodynamics , medicine , quantum mechanics , thermodynamics
We establish the existence and stability of multidimensional transonic shocks (hyperbolic‐elliptic shocks) for the Euler equations for steady compressible potential fluids in infinite cylinders. The Euler equations, consisting of the conservation law of mass and the Bernoulli law for velocity, can be written as a second order nonlinear equation of mixed elliptic‐hyperbolic type for the velocity potential. The transonic shock problem in an infinite cylinder can be formulated into the following free boundary problem: The free boundary is the location of the multidimensional transonic shock which divides two regions of C 1,α flow in the infinite cylinder, and the equation is hyperbolic in the upstream region where the C 1,α perturbed flow is supersonic. We develop a nonlinear approach to deal with such a free boundary problem in order to solve the transonic shock problem in unbounded domains. Our results indicate that there exists a solution of the free boundary problem such that the equation is always elliptic in the unbounded downstream region, the uniform velocity state at infinity in the downstream direction is uniquely determined by the given hyperbolic phase, and the free boundary is C 1,α , provided that the hyperbolic phase is close in C 1,α to a uniform flow. We further prove that, if the steady perturbation of the hyperbolic phase is C 2,α , the free boundary is C 2,α and stable under the steady perturbation. © 2003 Wiley Periodicals Inc.