Blow-up and global existence for semilinear parabolic systems with space-time forcing terms

We investigate the local existence, finite time blow-up and global existence of sign-changing solutions to the inhomogeneous parabolic system with space-time forcing terms $$ u_t-\Delta u =|v|^{p}+t^\sigma w_1(x),\,\, v_t-\Delta v =|u|^{q}+t^\gamma w_2(x),\,\, (u(0,x),v(0,x))=(u_0(x),v_0(x)), $$ where $t>0$, $x\in \mathbb{R}^N$, $N\geq 1$, $p,q>1$, $\sigma,\gamma>-1$, $\sigma,\gamma\neq0$, $w_1,w_2\not\equiv0$, and $u_0,v_0\in C_0(\mathbb{R}^N)$. For the finite time blow-up, two cases are discussed under the conditions $w_i\in L^1(\mathbb{R}^N)$ and $\int_{\mathbb{R}^N} w_i(x)\,dx>0$, $i=1,2$. Namely, if $\sigma>0$ or $\gamma>0$, we show that the (mild) solution $(u,v)$ to the considered system blows up in finite time, while if $\sigma,\gamma\in(-1,0)$, then a finite time blow-up occurs when $\frac{N}{2} \frac{\sigma}{\gamma}$ and $q>\frac{\gamma}{\sigma}$, we show that the solution is global for suitable initial values and $w_i$, $i=1,2$.