Shape Optimization for the Principal Eigenvalue of the Pucci Operator in Three Dimensions

Abstract

We investigate shape optimization for the principal eigenvalue of the Pucci extremal operator \[ \ aligned -M+λ,(D2u)&=μ+1()u &&in ,\\ u &=0 &&on ∂, aligned . \] in dimension three. Since M+λ, is fully nonlinear, in non-divergence form, and non-variational, classical symmetrization and rearrangement methods are not available. We introduce a three-dimensional family of double--pyramidal domains \ωγ,a\ parametrized by an anisotropy factor γ ∈ [1ω,ω] and an affine shear parameter a∈(-π,π), under fixed ellipticity ratio ω=/λ 1. Within this family and under a fixed-volume constraint, we prove that the volume-normalized principal eigenvalue is uniquely minimized at the symmetric unsheared configuration (γ,a)=(1,0) among domains in the family \ωγ,a\. The proof combines an explicit construction of positive eigenfunctions on seven patches with a lower bound under affine shear deformations. Using the homogeneity and orthogonal invariance of the Pucci operator, we identify an involutive symmetry γ γ-1 in the associated volume functional and establish strict monotonicity away from the self-dual point γ=1. In particular, for ω>1, any nontrivial anisotropy or shear strictly increases the normalized principal eigenvalue. This reveals a genuinely three-dimensional rigidity mechanism for a fully nonlinear spectral problem and extends to dimension three the symmetry-minimization phenomenon previously known in the planar case.

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