FINITE TIME EMERGENCE OF A SHOCK WAVE FOR SCALAR CONSERVATION LAWS VIA

doi:10.1007/s10473-019-0107-8

Abstract

Abstract: In this paper, we use Lax-Oleinik formula to study the asymptotic behavior for the initial problem of scalar conservation law u_t + F(u)_x=0. First, we prove a simple but useful property of Lax-Oleinik formula (Lemma 2.7). In fact, denote the Legendre transform of F(u) as L(σ), then we can prove that the quantity F(q)-qF'(q) + L(F'(q)) is a constant independent of q. As a simple application, we first give the solution of Riemann problem without using of Rankine-Hugoniot condition and entropy condition. Then we study the asymptotic behavior of the problem with some special initial data and prove that the solution contains only a single shock for t > T^*. Meanwhile, we can give the equation of the shock and an explicit value of T^*.

Key words: scalar conservation law, Lax-Oleinik formula, Riemann problem, asymptotic behavior

Zejun WANG, Qi ZHANG. FINITE TIME EMERGENCE OF A SHOCK WAVE FOR SCALAR CONSERVATION LAWS VIA[J].Acta mathematica scientia,Series B, 2019, 39(1): 83-93.

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