On solvability of a time-fractional semilinear heat equation, and its quantitative approach to the classical counterpart

Abstract

We are concerned with the following time-fractional semilinear heat equation in the N-dimensional whole space RN with N ≥ 1. \[ (P)α ∂tα u - u = up, t>0,\,\,\, x∈ RN, u(0) = μ in RN, \] where ∂tα denotes the Caputo derivative of order α ∈ (0,1), p>1, and μ is a nonnegative Radon measure on RN. The case α=1 formally gives the Fujita-type equation (P)1 \ ∂tu- u=up. In particular, we mainly focus on the Fujita critical case where p=pF:=1+2/N. It is well known that the Fujita exponent pF separates the ranges of p for the global-in-time solvability of (P)1. In particular, (P)1 with p=pF possesses no global-in-time solutions, and does not locally-in-time solvable in its scale critical space L1(RN). It is also known that the exponent pF plays the same role for the global-in-time solvability for (P)α. However, the problem (P)α with p=pF is globally-in-time solvable, and exhibites local-in-time solvability in its scale critical space L1(RN). The purpose of this paper is to clarify the collapse of the global and local-in-time solvability of (P)α as α approaches 1-0.