# A Generalization of Weyl's Asymptotic Formula for the Relative Trace of   Singular Potentials

**Authors:** Jakob Ullmann

arXiv: 1907.10798 · 2020-06-24

## TL;DR

This paper extends Weyl's asymptotic formula to cases where the negative parts of potentials differ in integrability, providing a new way to analyze the relative trace of Schrödinger operators with singular potentials.

## Contribution

It generalizes Weyl's formula to the difference of traces for potentials with non-integrable negative parts, focusing on their relative asymptotic behavior.

## Key findings

- Established asymptotic formula for the difference of traces with singular potentials.
- Extended Weyl's law to cases with non-integrable negative parts of potentials.
- Provided conditions under which the relative trace still follows a Weyl-type asymptotic.

## Abstract

By Weyl's asymptotic formula, for any potential $V$ whose negative part $V_-$ is an $L^{1+d/2}$-function, \begin{align*} \operatorname{Tr} [-h^2 \Delta + V]_- &= L_d^{\mathrm{cl}} h^{-d} \int \mathrm{d} x\,[V]_-^{1+\frac d 2} + \mathrm{o} (h^{-d})_{h \to 0} , \end{align*} with the semiclassical constant $L^{\mathrm{cl}}_d = 2^{-d} \pi^{-d/2} / \Gamma (2 + \frac d 2)$. In this paper, we show that, even if $[V_1]_-, [V_2]_- \notin L^{1+d/2}$, but the difference $[V_1]_-^{1+d/2}-[V_2]_-^{1+d/2}$ is integrable, then we still have the asymptotic formula \[ \operatorname{Tr} [-h^2 \Delta + V_1 ]_- - \operatorname{Tr} [-h^2 \Delta + V_2 ]_- = L^{\mathrm{cl}}_{d} h^{-d} \int \mathrm{d} x\,([V_1]_-^{1+\frac d 2}-[V_2]_-^{1+\frac d 2}) + \mathrm{o} (h^{-d})_{h\to 0} . \] This is a generalization of Weyl's formula in the case that $\operatorname{Tr} [-h^2 \Delta + V_1]_-$ and $\operatorname{Tr} [-h^2\Delta + V_2]_-$ are seperately not of order $\mathrm{O} (h^{-d})$.

## Full text

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## References

8 references — full list in the complete paper: https://tomesphere.com/paper/1907.10798/full.md

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