Reaction diffusion equations with super-linear absorption: universal bounds, uniqueness for the Cauchy problem, boundedness of stationary solutions

Abstract

Consider classical solutions to the parabolic reaction diffusion equation &ut =Lu+f(x,u), (x,t)∈ Rn×(0,∞); &u(x,0) =g(x)0, x∈ Rn; &u0, where L=Σi,j=1nai,j(x)∂2∂ xi ∂ xj+Σi=1nbi(x)∂∂ xi is a non-degenerate elliptic operator, g∈ C(Rn) and the reaction term f converges to -∞ at a super-linear rate as u∞. We give a sharp minimal growth condition on f, independent of L, in order that there exist a universal, a priori upper bound for all solutions to the above Cauchy problem--that is, in order that there exist a finite function M(x,t) on Rn×(0,∞) such that u(x,t) M(x,t), for all solutions to the Cauchy problem. Assuming now in addition that f(x,0)=0, so that u0 is a solution to the Cauchy problem, we show that under a similar growth condition, an intimate relationship exists between two seemingly disparate phenomena--namely, uniqueness for the Cauchy problem with initial data g=0 and the nonexistence of unbounded, stationary solutions to the corresponding elliptic problem. We also give a generic condition for nonexistence of nontrivial stationary solutions.

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