Shock waves for radiative hyperbolic--elliptic systems
Abstract
The present paper deals with the following hyperbolic--elliptic coupled system, modelling dynamics of a gas in presence of radiation, ut+ f(u)x +Lqx=0, -qxx + Rq +G· ux=0, where u∈n, q∈ and R>0, G, L∈n. The flux function f : nn is smooth and such that ∇ f has n distinct real eigenvalues for any u. The problem of existence of admissible radiative shock wave is considered, i.e. existence of a solution of the form (u,q)(x,t):=(U,Q)(x-st), such that (U,Q)(∞)=(u,0), and u∈n, s∈ define a shock wave for the reduced hyperbolic system, obtained by formally putting L=0. It is proved that, if u- is such that ∇λk(u-)· rk(u-)≠ 0,(where λk denotes the k-th eigenvalue of ∇ f and rk a corresponding right eigenvector) and (k(u-)· L) (G· rk(u-)) >0, then there exists a neighborhood U of u- such that for any u+∈ U, s∈ such that the triple (u-,u+;s) defines a shock wave for the reduced hyperbolic system, there exists a (unique up to shift) admissible radiative shock wave for the complete hyperbolic--elliptic system. Additionally, we are able to prove that the profile (U,Q) gains smoothness when the size of the shock |u+-u-| is small enough, as previously proved for the Burgers' flux case. Finally, the general case of nonconvex fluxes is also treated, showing similar results of existence and regularity for the profiles.
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