Eigenfunction localization and nodal geometry on dumbbell domains

TL;DR

This paper investigates the geometric properties of eigenfunctions and nodal lines on dumbbell-shaped domains, revealing how boundary conditions influence localization and the position of nodal sets, with implications for spectral geometry.

Contribution

It provides new insights into eigenfunction localization and nodal set placement on non-convex dumbbell domains, contrasting with previous convex domain studies.

Findings

Nodal sets of Neumann dumbbells with narrow connectors are near the connectors.

Localization behavior of eigenfunctions depends on boundary conditions.

Optimal obstacle placement affects eigenfunction maxima.

Abstract

In this article, we study the location of the first nodal line and hot spots under different boundary conditions on dumbbell-shaped domains. Apart from its intrinsic interest, dumbbell domains are also geometrically contrasting to the extensively studied convex domains. For dumbbells with Dirichlet boundary, we investigate the location of the supremum level set of the first eigenfunction and discuss the optimal positioning of obstacles. Considering the other end of level sets, the nodal sets, we establish that the first nodal set of a Neumann dumbbell (with sufficiently narrow connectors) lies within a neighborhood of the connectors. The article demonstrates the utilization of the asymptotic $L^2$-localization (or its absence, characterized by either Dirichlet or Neumann boundaries) of dumbbell domains in tackling the aforementioned nodal geometry problems.