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Bibliographic Details
Main Author: Raske, David
Format: Preprint
Published: 2026
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Online Access:https://arxiv.org/abs/2601.11882
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author Raske, David
author_facet Raske, David
contents Let $(M,g)$ be a closed, smooth, Riemannian manifold of dimension $m \geq 1$. Let $η$ be a smooth $(0,1)$-tensor field on $M$. The divergence of $η$ is defined as $\text{div}_g(η):=g^{ij}(\nabla η)_{ij}$. Now let $Δ_g$ be a differential operator on $M$ that is given on functions by $Δ_g u = \text{div}_g \nabla u$. We will call $Δ_g$ the Laplace-Beltrami operator. With this definition in place, it is not difficult to produce an example of a formally self-adjoint elliptic differential operator on $M$ that has a sign-changing eigenfunction that is associated with the operator's lowest eigenvalue. Indeed, let $λ_2$ be the second lowest eigenvalue of $-Δ_g$, and let $L_g$ be a differential operator on $M$ that is given on functions by $L_g u = Δ^2_g u + λ_2 Δu$. Then $L_g$ will possess a sign-changing eigenfunction that is associated with $L_g$'s lowest eigenvalue.. The question that remains is given a smooth, closed manifold $M$ of dimension $m \geq 1$, how rare are formally self-adjoint elliptic differential operators on $M$ that have sign-changing eigenfunctions that are associated with the operators' lowest eigenvalues. In this paper, we will see that if $A = T -λg$, where $T$ is a smooth, symmetric, negative semi-definite $(0,2)$-tensor field on $M$, then $P_g$, the differential operator on $M$ given on functions by $P_gu=,Δ_g^2 - \text{div}_g(A(\nabla u)^\sharp)$, will have the property that it possesses a sign-changing eigenfunction that is associated with the lowest eigenvalue of the operator. This suggests that on any smooth, closed manifold of dimension $m \geq 1$ there exists a lot of formally self-adjoint fourth order elliptic differential operators on the manifold that possess sign-changing eigenfunctions that are associated with the lowest eigenvalues of the operators.
format Preprint
id arxiv_https___arxiv_org_abs_2601_11882
institution arXiv
publishDate 2026
record_format arxiv
spellingShingle Lowest eigenvalues and formally self-adjoint fourth order elliptic differential operators
Raske, David
Analysis of PDEs
35J30 (Primary) 35B99 (Secondary)
Let $(M,g)$ be a closed, smooth, Riemannian manifold of dimension $m \geq 1$. Let $η$ be a smooth $(0,1)$-tensor field on $M$. The divergence of $η$ is defined as $\text{div}_g(η):=g^{ij}(\nabla η)_{ij}$. Now let $Δ_g$ be a differential operator on $M$ that is given on functions by $Δ_g u = \text{div}_g \nabla u$. We will call $Δ_g$ the Laplace-Beltrami operator. With this definition in place, it is not difficult to produce an example of a formally self-adjoint elliptic differential operator on $M$ that has a sign-changing eigenfunction that is associated with the operator's lowest eigenvalue. Indeed, let $λ_2$ be the second lowest eigenvalue of $-Δ_g$, and let $L_g$ be a differential operator on $M$ that is given on functions by $L_g u = Δ^2_g u + λ_2 Δu$. Then $L_g$ will possess a sign-changing eigenfunction that is associated with $L_g$'s lowest eigenvalue.. The question that remains is given a smooth, closed manifold $M$ of dimension $m \geq 1$, how rare are formally self-adjoint elliptic differential operators on $M$ that have sign-changing eigenfunctions that are associated with the operators' lowest eigenvalues. In this paper, we will see that if $A = T -λg$, where $T$ is a smooth, symmetric, negative semi-definite $(0,2)$-tensor field on $M$, then $P_g$, the differential operator on $M$ given on functions by $P_gu=,Δ_g^2 - \text{div}_g(A(\nabla u)^\sharp)$, will have the property that it possesses a sign-changing eigenfunction that is associated with the lowest eigenvalue of the operator. This suggests that on any smooth, closed manifold of dimension $m \geq 1$ there exists a lot of formally self-adjoint fourth order elliptic differential operators on the manifold that possess sign-changing eigenfunctions that are associated with the lowest eigenvalues of the operators.
title Lowest eigenvalues and formally self-adjoint fourth order elliptic differential operators
topic Analysis of PDEs
35J30 (Primary) 35B99 (Secondary)
url https://arxiv.org/abs/2601.11882