Riesz transform via heat kernel and harmonic functions on non-compact manifolds

Abstract

Let M be a complete non-compact manifold satisfying the volume doubling condition, with doubling index N and reverse doubling index n, n N, both for large balls. Assume a Gaussian upper bound for the heat kernel, and an L2-Poincar\'e inequality outside a compact set. If 2<n, then we show that for p∈ (2,n), (Rp): Lp-boundedness of the Riesz transform, (Gp): Lp-boundedness of the gradient of the heat semigroup, and (RHp): reverse Lp-H\"older inequality for the gradient of harmonic functions, are equivalent to each other. Our characterization implies that for p∈ (2,n), (Rp) has an open ended property and is stable under gluing operations. This substantially extends the well known equivalence of (Rp) and (Gp) from [4] to more general settings, and is optimal in the sense that (Rp) does not hold for any p n>2 on manifolds having at least two Euclidean ends of dimension n. For p∈ (\N,2\,∞), the fact that (Rp), (Gp) and (RHp) are equivalent essentially follows from [22]; moreover, if M is non-parabolic, then any of these conditions implies that M has only one end. For the proof, we develop a new criteria for boundedness of the Riesz transform, which was nontrivially adapted from [4], and make an essential application of results from [22]. Our result allows extensions to non-smooth settings.