Self-improvement of fractional Hardy inequalities in metric measure spaces via hyperbolic fillings

Abstract

In this paper, we prove a self-improvement result for (θ,p)-fractional Hardy inequalities, in both the exponent 1<p<∞ and the regularity parameter 0<θ<1, for bounded domains in doubling metric measure spaces. The key conceptual tool is a Caffarelli-Silvestre-type argument, which relates fractional Sobolev spaces on Z to Newton-Sobolev spaces in the hyperbolic filling X of Z via trace results. Using this insight, it is shown that a fractional Hardy inequality in an open subset of Z is equivalent to a classical Hardy inequality in the filling X. The main result is then obtained by applying a new weighted self-improvement result for p-Hardy inequalities. The exponent p can be self-improved by a classical Koskela-Zhong argument, but a new theory of regularizable weights is developed to obtain the self-improvement in the regularity parameter θ. This generalizes a result of Lehrb\"ack and Koskela on self-improvement of dβ-weighted p-Hardy inequalities by allowing a much broader class of weights. Using the equivalence of fractional Hardy inequalities with Hardy inequalities in the fillings, we also give new examples of domains satisfying fractional Hardy inequalities.

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