On fractional quasilinear parabolic problem with Hardy potential (1703.03299v1)

Abstract: The aim goal of this paper is to treat the following problem \begin{equation*} \left{ \begin{array}{rcll} u_t+(-\D^s_{p}) u &=&\dyle \l \dfrac{u^{p-1}}{|x|^{ps}} & \text{ in } \O_{T}=\Omega \times (0,T), \ u&\ge & 0 & \text{ in }\ren \times (0,T), \ u &=& 0 & \text{ in }(\ren\setminus\O) \times (0,T), \ u(x,0)&=& u_0(x)& \mbox{ in }\O, \end{array}% \right. \end{equation*} where $\Omega$ is a bounded domain containing the origin, $$ (-\D^s_{p})\, u(x,t):=P.V\int_{\ren} \,\dfrac{|u(x,t)-u(y,t)|^{p-2}(u(x,t)-u(y,t))}{|x-y|^{N+ps}} \,dy$$ with $1<p<N, s\in (0,1)$ and $f, u_0$ are non negative functions. The main goal of this work is to discuss the existence of solution according to the values of $p$ and $\l$.