$A_p$ weights and Quantitative Estimates in the Schrödinger Setting

Abstract: Suppose $L=-\Delta+V$ is a Schr\"odinger operator on $\mathbb{R}^n$ with a potential $V$ belonging to certain reverse H\"older class $RH_\sigma$ with $\sigma\geq n/2$. The aim of this paper is to study the $A_p$ weights associated to $L$, denoted by $A_p^L$, which is a larger class than the classical Muckenhoupt $A_p$ weights. We first establish the "exp--log" link between $A_p^L$ and $BMO_L$ (the BMO space associated with $L$), which is the first extension of the classical result to a setting beyond the Laplace operator. Second, we prove the quantitative $A_p^L$ bound for the maximal function and the maximal heat semigroup associated to $L$. Then we further provide the quantitative $A_{p,q}^L$ bound for the fractional integral operator associated to $L$. We point out that all these quantitative bounds are known before in terms of the classical $A_{p,q}$ constant. However, since $A_{p,q}\subset A_{p,q}^L$, the $A_{p,q}^L$ constants are smaller than $A_{p,q}$ constant. Hence, our results here provide a better quantitative constant for maximal functions and fractional integral operators associated to $L$.