Global $L^{\infty}$ solutions of the compressible Euler equations with spherical symmetry

Abstract: We study the compressible Euler equations with spherical symmetry surrounding a solid ball. For the spherically symmetric flow, the global existence of L ∞ entropy weak solutions has not yet obtained except a special case. In this paper, we prove the existence of global solutions in the more general case. We construct approximate solutions by using a modified Godunov scheme. The main point is to obtain an L ∞ bound for the approximate solutions.

“…In this paper, we extend the results in [10] to the Cauchy problems (1.1)-(1.2) by using the vanishing viscosity method for general pressure function P(ρ).…”

“…γ +1 , C > 0 was obtained in [10] for the initial-boundary value problems (1.1)-(1.3) for a polytropic gas with 1 < γ < 5 3 by using a modified Godunov scheme. In this paper, we extend the results in [10] to the Cauchy problems (1.1)-(1.2) by using the vanishing viscosity method for general pressure function P(ρ).…”

Global existence of solutions to resonant system of isentropic gas dynamics

“…In this paper, we extend the results in [10] to the Cauchy problems (1.1)-(1.2) by using the vanishing viscosity method for general pressure function P(ρ).…”

“…γ +1 , C > 0 was obtained in [10] for the initial-boundary value problems (1.1)-(1.3) for a polytropic gas with 1 < γ < 5 3 by using a modified Godunov scheme. In this paper, we extend the results in [10] to the Cauchy problems (1.1)-(1.2) by using the vanishing viscosity method for general pressure function P(ρ).…”

Global existence of solutions to resonant system of isentropic gas dynamics

“…The other inequality can be proved similarly. This lemma is the generalization of [21,Appendix C]. In fact, the lemma is the case…”

“…Finally, Tsuge [21] proved global existence of solutions for the spherically symmetric case (that is, A(x) = x 2 in (1.1)).…”

Existence of Global Solutions for Unsteady Isentropic Gas Flow in a Laval Nozzle

“…Without the condition z 0 (x) ≤ 0 or w 0 (x) ≤ 0, many authors tried to prove the same uniform estimate for the spherically, symmetric solutions in the region of x > 1, where a(x) = x 2 . However, as pointed out in the paper [Ts1], there are some defects in the proofs in these papers. Instead of the uniform estimate, a reasonable estimate depending on the variable x : z(x, t) ≤ Cx…”

Resonance for the isothermal system of isentropic gas dynamics