Heat equations driven by mixed local-nonlocal operators with exponential nonlinearity

Abstract

We investigate the Cauchy problem for a heat equation driven by the mixed local-nonlocal operator L:=-+(-)s, s∈(0,1), with exponential nonlinearity \[ ∂tu(x,t)+Lu(x,t)=f(u(x,t)), (x,t)∈ Rd×(0,∞), \] where f:R exhibits exponential growth at infinity and satisfies f(0)=0. We establish local well-posedness in a suitable Orlicz space in the case where f(u) e|u|p as |u|∞, with p>1. We further prove the existence of global solutions for small initial data under the assumption that f satisfies the growth condition |f(u)| |u|m near the origin. Moreover, we derive large-time decay estimates in Lebesgue spaces, showing that the behavior of the nonlinearity near the origin determines the decay rate of solutions and highlights a unique asymptotic transition that bridges local and non-local diffusion theories.