English

Regularized Potentials of Schr\"odinger Operators and a Local Landscape Function

Analysis of PDEs 2020-03-03 v1 Numerical Analysis Numerical Analysis

Abstract

We study localization properties of low-lying eigenfunctions (Δ+V)ϕ=λϕ\mboxin Ω(-\Delta +V) \phi = \lambda \phi \qquad \mbox{in}~\Omega for rapidly varying potentials VV in bounded domains ΩRd\Omega \subset \mathbb{R}^d. Filoche & Mayboroda introduced the landscape function (Δ+V)u=1(-\Delta + V)u=1 and showed that the function uu has remarkable properties: localized eigenfunctions prefer to localize in the local maxima of uu. Arnold, David, Filoche, Jerison \& Mayboroda showed that 1/u1/u arises naturally as the potential in a related equation. Motivated by these questions, we introduce a one-parameter family of regularized potentials VtV_t that arise from convolving VV with the radial kernel Vt(x)=V(1t0texp(2/(4s))(4πs)d/2ds). V_t(x) = V * \left( \frac{1}{t} \int_0^t \frac{ \exp\left( - \|\cdot\|^2/ (4s) \right)}{(4 \pi s )^{d/2}} ds \right). We prove that for eigenfunctions (Δ+V)ϕ=λϕ(-\Delta +V) \phi = \lambda \phi this regularization VtV_t is, in a precise sense, the canonical effective potential on small scales. The landscape function uu respects the same type of regularization. This allows allows us to derive landscape-type functions out of solutions of the equation (Δ+V)u=f(-\Delta + V)u = f for a general right-hand side f:ΩR>0f:\Omega \rightarrow \mathbb{R}_{>0}.

Cite

@article{arxiv.2003.01091,
  title  = {Regularized Potentials of Schr\"odinger Operators and a Local Landscape Function},
  author = {Stefan Steinerberger},
  journal= {arXiv preprint arXiv:2003.01091},
  year   = {2020}
}
R2 v1 2026-06-23T14:00:53.316Z