On high dimensional maximal functions associated to Gaussians, balls, and spheres

Abstract

We prove that for each p∈ (1,∞), the norms on Lp(Rd) of the maximal functions associated to Gaussians (heat semigroup), balls (Hardy-Littlewood averages), and spheres (spherical averages) converge, as the dimension d ∞, to the same quantity λ(p). This is derived from the fact that the norms on L2(Rd) of the maximal functions corresponding to the differences of Gaussian, ball, and spherical averages converge to zero with the dimension d. The fact is proved with the aid of estimates for Fourier multiplier symbols corresponding to these averages, a general principle that allows us to control the norm of a maximal function corresponding to a Fourier multiplier operator by the norm of the multiplier operator itself, and concentration properties of high dimensional Gaussian random vectors. Moreover, relying on the properties of the d-dimensional maximal function for the heat semigroup Gd, we show that λ(p) satisfies 25pp-1\|G1\|Lp(R)→ Lp(R) λ(p) pp-1. In particular, to obtain the middle inequality we show that the norms on Lp(Rd) of the maximal function for the heat semigroup are non-decreasing in d.