Hausdorff dimension of caloric measure

Abstract

We examine caloric measures ω on general domains in Rn+1 = Rn×R (space × time) from the perspective of geometric measure theory. On one hand, we give a direct proof of a consequence of a theorem of Taylor and Watson (1985) that the lower parabolic Hausdorff dimension of ω is at least n and ω Hn. On the other hand, we prove that the upper parabolic Hausdorff dimension of ω is at most n+2-βn, where βn > 0 depends only on n. Analogous bounds for harmonic measures were first shown by Nevanlinna (1934) and Bourgain (1987). Heuristically, we show that the density of obstacles in a cube needed to make it unlikely that a Brownian motion started outside of the cube exits a domain near the center of the cube must be chosen according to the ambient dimension. In the course of the proof, we give a caloric measure analogue of Bourgain's alternative: for any constants 0 < ε n δ < 1/2 and closed set E ⊂ Rn+1, either (i) E Q has relatively large caloric measure in Q E for every pole in F or (ii) E Q* has relatively small -dimensional parabolic Hausdorff content for every n < ≤ n+2, where Q is a cube, F is a subcube of Q aligned at the center of the top time-face, and Q* is a subcube of Q that is close to, but separated backwards-in-time from F: Q = (-1/2,1/2)n × (-1,0), F = [-1/2+δ,1/2-δ]n×[-ε2,0), and Q* = [-1/2+δ,1/2-δ]n×[-3ε2,-2ε2]. Further, we supply a version of the strong Markov property for caloric measures.