On the global existence and blowup of smooth solutions of 3-D compressible Euler equations with time-depending damping
arXiv:1510.04613 · doi:10.2140/pjm.2018.292.389
Abstract
In this paper, we are concerned with the global existence and blowup of smooth solutions of the 3-D compressible Euler equation with time-depending damping $$ \partial_tÏ+\operatorname{div}(Ïu)=0, \quad \partial_t(Ïu)+\operatorname{div}\left(Ïu\otimes u+p\,I_{3}\right)=-\,\fracμ{(1+t)^λ}\,Ïu, \quad Ï(0,x)=\bar Ï+\varepsilonÏ_0(x),\quad u(0,x)=\varepsilon u_0(x), $$ where $x\in\mathbb R^3$, $μ>0$, $λ\geq 0$, and $\barÏ>0$ are constants, $Ï_0,\, u_0\in C_0^{\infty}(\mathbb R^3)$, $(Ï_0, u_0)\not\equiv 0$, $Ï(0,\cdot)>0$, and $\varepsilon>0$ is sufficiently small. For $0\leqλ\leq1$, we show that there exists a global smooth solution $(Ï, u)$ when $\operatorname{curl} u_0\equiv 0$, while for $λ>1$, in general, the solution $(Ï, u)$ will blow up in finite time. Therefore, $λ=1$ appears to be the critical value for the global existence of small amplitude smooth solutions.
28 pages