# Quantitative unique continuation for Schr\"odinger operators

**Authors:** Blair Davey

arXiv: 1903.04021 · 2019-03-12

## TL;DR

This paper establishes quantitative bounds on the vanishing order of solutions to Schrödinger equations with singular potentials, providing new estimates that enhance understanding of unique continuation properties for elliptic PDEs.

## Contribution

It introduces a novel $L^p - L^q$ Carleman estimate and applies it to derive maximal order of vanishing and unique continuation at infinity for solutions with potentials in $L^t$ spaces.

## Key findings

- Derived maximal vanishing order estimates for solutions with $V \,\in L^t$, $t > n/2$
- Established a new $L^p - L^q$ Carleman estimate for elliptic equations
- Extended results to equations with first order terms involving $W \cdot \nabla u$

## Abstract

We investigate the quantitative unique continuation properties of solutions to second order elliptic equations with singular lower order terms. The main theorem presents a quantification of the strong unique continuation property for $\Delta + V$. That is, for any non-trivial $u$ that solves $\Delta u + V u = 0$ in some open, connected subset of $\mathbb{R}^n$, we estimate the vanishing order of solutions in terms of the $L^t$-norm of $V$. Our results apply to all $t > \frac n 2$ and $n \ge 3$. With these maximal order of vanishing estimates, we employ a scaling argument to produce quantitative unique continuation at infinity estimates for global solutions to $\Delta u + V u = 0$. To handle $V \in L^t$ for every $t \in (\frac n 2, \infty]$, we prove a novel $L^p - L^q$ Carleman estimate by interpolating a known $L^p - L^2$ estimate with a new endpoint Carleman estimate. This new Carleman estimate may also be used to establish improved order of vanishing estimates for equations with a first order term, those of the form $\Delta u + W \cdot \nabla u + V u = 0$.

## Full text

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## Figures

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## References

15 references — full list in the complete paper: https://tomesphere.com/paper/1903.04021/full.md

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Source: https://tomesphere.com/paper/1903.04021