Weighted Sobolev space theory for the heat equation and the time-fractional heat equation in non-smooth domains

Abstract

We present a general Lp-solvability framework for both the classical and time-fractional heat equations in non-smooth domains under the zero Dirichlet boundary condition. We consider domains admitting the Hardy inequality: There exists a constant N>0 such that ∫|f(x)d(x,∂)|2\,d x≤ N∫|∇ f|2 \,d x any f∈ Cc∞()\,. To illustrate the boundary behavior of solutions in a general framework, we employ a weight system composed of a superharmonic function and a distance function to the boundary. Further, we investigate applications to various non-smooth domains, including convex domains, domains with exterior cone condition, totally vanishing exterior Reifenberg domains, and domains ⊂Rd for which the Aikawa dimension of c is less than d-2. By using superharmonic functions tailored to the geometric conditions of the domain, we derive weighted Lp-solvability results for various non-smooth domains, with specific weight ranges that differ for each domain condition. In addition, we provide an application to the H\"older continuity of solutions in domains with the volume density condition, as well as pointwise estimates for solutions in Lipschitz cones.

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