On the Fujita exponent for a Hardy-H\'enon equation with a spatial-temporal forcing term

Abstract

The purpose of this work is to analyze the wellposedness and the blow-up of solutions of the higher-order parabolic semilinear equation \[ ut+(-)du=|x|α|u|p+ζ(t) w(x) \ for (x,t)∈RN×(0,∞), \] where d∈ (0,1) N, p>1, -α∈(0,(2d,N)) or α≥ 0 and ζ as well as w are suitable given functions. Given p≥ N-2dσ+αN-2dσ-2d and setting pc=N(p-1)2d+α, =N pcN+2(σ+1)d pc, we prove that for any data u0∈ Lpc,∞(RN) and w∈ L,∞(RN) with small norms there exists a unique global-in-time solution under the hypotheses ζ(t)=tσ, σ∈ (-1,0) and N>2d in the space Cb([0,∞);Lpc,∞(RN)). As a by-product, small Lebesgue data global existence follows and in particular, unconditional uniqueness holds in Cb([0,∞);Lpc(RN)) provided p∈ (N+αN-2d,∞). If either m∈ (-∞,0] and p∈ (1,N-2dm+αN-2dm-2d) or m>0 and p>1 where ζ(t)=O(tm), t→∞ (m∈ R), then all solutions blow up under the additional condition ∫RNw(x)\,dx>0. As a consequence, we deduce that the corresponding Fujita critical exponent is a function of σ and reads pF(σ)=N-2dσ+αN-2dσ-2d if -1<σ<0 and infinity otherwise.