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Asymptotic spherical shapes in some spectral optimization problems

Dario Mazzoleni, Benedetta Pellacci, Gianmaria Verzini

2020Virtual Community of Pathological Anatomy (University of Castilla La Mancha)19 citationsDOIOpen Access PDF

Abstract

We study the optimization of the positive principal eigenvalue of an indefinite weighted problem, associated with the Neumann Laplacian in a box Ω⊂RN, which arises in the investigation of the survival threshold in population dynamics. When trying to minimize such eigenvalue with respect to the weight, one is led to consider a shape optimization problem, which is known to admit no spherical optimal shapes (despite some previously stated conjectures). We investigate whether spherical shapes can be recovered in some singular perturbation limit. More precisely we show that, whenever the negative part of the weight diverges, the above shape optimization problem approaches in the limit the so called spectral drop problem, which involves the minimization of the first eigenvalue of the mixed Dirichlet-Neumann Laplacian. Using α-symmetrization techniques on cones, we prove that, for suitable choices of the box Ω, the optimal shapes for this second problem are indeed spherical. Moreover, for general Ω, we show that small volume spectral drops are asymptotically spherical, centered near points of ∂Ω having largest mean curvature.

Topics & Concepts

MathematicsEigenvalues and eigenvectorsLaplace operatorNeumann boundary conditionLimit (mathematics)Mathematical analysisCombinatoricsApplied mathematicsBoundary value problemPhysicsQuantum mechanicsNonlinear Partial Differential EquationsMarkov Chains and Monte Carlo MethodsStochastic processes and statistical mechanics
Asymptotic spherical shapes in some spectral optimization problems | Litcius