The Garnett-Jones Theorem on BMO spaces associated with operators and applications

Abstract

Let X be a metric space with doubling measure, and L be a nonnegative self-adjoint operator on L2(X) whose heat kernel satisfies the Gaussian upper bound. Let f be in the space BMOL(X) associated with the operator L and we define its distance from the subspace L∞(X) under the BMOL(X) norm as follows: dist (f, L∞):= ∈fg∈ L∞ \|f -g\| BMOL(X). In this paper we prove that dist (f, L∞) is equivalent to the infimum of the constant in the John-Nirenberg inequality for the space BMOL(X): B μ(\ x∈ B: |f(x)-e-rB2Lf(x)|>λ\) μ(B) ≤ e-λ/\ \ \ \ for\ large\ λ. This extends the well-known result of Garnett and Jones GJ1 for the classical BMO space (introduced by John and Nirenberg). As an application, we show that a BMOL(X) function with compact support can be decomposed as the summation of an L∞-function and the integral of the heat kernel (associated with L) against a finite Carleson measure on X×[0,∞). The key new technique is a geometric construction involving the semigroup e-tL. We also resort to several fundamental tools including the stopping time argument and the random dyadic lattice.