# Weak type $(1,1)$ bounds for Schr\"odinger groups

**Authors:** Peng Chen, Xuan Thinh Duong, Ji Li, Liang Song, Lixin Yan

arXiv: 1906.05519 · 2019-06-14

## TL;DR

This paper proves weak type (1,1) bounds for Schr"odinger groups associated with certain operators on spaces of homogeneous type, extending known $L^p$ bounds to the endpoint case $p=1$ with sharpness results.

## Contribution

It establishes the weak type (1,1) boundedness of the operator $(1+L)^{-n/2} e^{itL}$ for a broad class of operators, including Schr"odinger groups, on spaces of homogeneous type.

## Key findings

- Proves weak type (1,1) bounds for Schr"odinger groups.
- Shows the index $n/2$ is sharp in Euclidean space.
- Applicable to elliptic operators, Schr"odinger operators, and Laplacians on various structures.

## Abstract

Let $L$ be a non-negative self-adjoint operator acting on $L^2(X)$ where $X$ is a space of homogeneous type with a dimension $n$. Suppose that the heat kernel of $L$ satisfies a Gaussian upper bound. It is known that the operator $(I+L)^{-s } e^{itL}$ is bounded on $L^p(X)$ for $s> n|{1/ 2}-{1/p}| $ and $ p\in (1, \infty)$ (see for example, \cite{CCO, H, Sj}). The index $s= n|{1/ 2}-{1/p}|$ was only obtained recently in \cite{CDLY, CDLY2}, and this range of $s$ is sharp since it is precisely the range known in the case when $L$ is the Laplace operator $\Delta$ on $X=\mathbb R^n$ (\cite{Mi1}). In this paper we establish that for $p=1,$ the operator $(1+L)^{-n/2}e^{itL}$ is of weak type $(1, 1)$, that is, there is a constant $C$, independent of $t$ and $f$ so that \begin{eqnarray*}   \mu\Big(\Big\{x: \big|(I+L)^{-n/2 }e^{itL} f(x)\big|>\lambda \Big\}\Big) \leq C\lambda^{-1}(1+|t|)^{n/2} {\|f\|_{L^1(X)} }, \ \ \ t\in{\mathbb R} \end{eqnarray*} (for $\lambda > 0$ when $\mu (X) = \infty$ and $\lambda>\mu(X)^{-1}\|f\|_{L^1(X)}$ when $\mu (X) < \infty$). Moreover, we also show the index $n/2$ is sharp when $L$ is the Laplacian on ${\mathbb R^n}$ by providing an example.   Our results are applicable to Schr\"odinger group for large classes of operators including elliptic operators on compact manifolds, Schr\"odinger operators with non-negative potentials and Laplace operators acting on Lie groups of polynomial growth or irregular non-doubling domains of Euclidean spaces.

## Full text

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## References

35 references — full list in the complete paper: https://tomesphere.com/paper/1906.05519/full.md

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Source: https://tomesphere.com/paper/1906.05519