Atomic and Maximal Function Characterizations of Musielak-Orlicz-Hardy Spaces Associated to Non-negative Self-adjoint Operators on Spaces of Homogeneous Type

Abstract

Let X be a metric space with doubling measure and L a non-negative self-adjoint operator on L2(X) whose heat kernels satisfy the Gaussian upper bound estimates. Assume that the growth function :\ X×[0,∞) [0,∞) satisfies that (x,·) is an Orlicz function and (·,t)∈ A∞(X) (the class of uniformly Muckenhoupt weights). Let H,\,L(X) be the Musielak-Orlicz-Hardy space defined via the Lusin area function associated with the heat semigroup of L. In this article, the authors characterize the space H,\,L(X) by means of atoms, non-tangential and radial maximal functions associated with L. In particular, when μ(X)<∞, the local non-tangential and radial maximal function characterizations of H,\,L(X) are obtained. As applications, the authors obtain various maximal function and the atomic characterizations of the "geometric" Musielak-Orlicz-Hardy spaces H,\,r() and H,\,z() on the strongly Lipschitz domain in Rn associated with second-order self-adjoint elliptic operators with the Dirichlet and the Neumann boundary conditions; even when (x,t):=t for any x∈Rn and t∈[0,∞), the equivalent characterizations of H,\,z() given in this article improve the known results via removing the assumption that is unbounded.