Exponential decay estimates for fundamental solutions of Schr\"odinger-type operators

TL;DR

This paper derives sharp exponential decay estimates for the kernels of a broad class of Schr"odinger-type operators, extending previous results from classical Schr"odinger operators to more general, possibly non-self-adjoint cases.

Contribution

It generalizes exponential decay bounds to non-self-adjoint Schr"odinger operators using a Fefferman-Phong type uncertainty principle and Agmon distance, including lower and upper bounds.

Findings

Established sharp exponential decay estimates for operator kernels.

Extended decay bounds to non-self-adjoint Schr"odinger operators.

Demonstrated the bounds' sharpness with scale-invariant Harnack inequality.

Abstract

In the present paper we establish sharp exponential decay estimates for operator and integral kernels of the (not necessarily self-adjoint) operators $L=-(\nabla-i\mathbf{a})^TA(\nabla-i\mathbf{a})+V$. The latter class includes, in particular, the magnetic Schr\"odinger operator $-\left(\nabla-i\mathbf{a}\right)^2+V$ and the generalized electric Schr\"odinger operator $-{\rm div }A\nabla+V$. Our exponential decay bounds rest on a generalization of the Fefferman-Phong uncertainty principle to the present context and are governed by the Agmon distance associated to the corresponding maximal function. In the presence of a scale-invariant Harnack inequality, for instance, for the generalized electric Schr\"odinger operator with real coefficients, we establish both lower and upper estimates for fundamental solutions, thus demonstrating sharpness of our results. The only previously known estimates of this type pertain to the classical Schr\"odinger operator $-\Delta +V$.