Generic Metrics on Sn+1 Preclude Linearly Stable Singular Tangent Cones of Area-Minimizing Boundaries

Abstract

We prove that for a residual (and hence dense) subset G of Riemannian metrics on Sn+1 in the C3 topology, no area-minimizing integral n-current that is a boundary admits a singular tangent cone which is linearly stable in the Euclidean sense. The proof proceeds in three stages. First, we develop a perturbation theorem: given any area-minimizer possessing an isolated singularity whose unique tangent cone C is linearly stable, we construct an explicit C3-small metric perturbation that destroys the compatibility conditions required for C to persist as a tangent cone. The construction rests on the Hardt--Simon asymptotic expansion near isolated singularities, the spectral theory of the Jacobi operator on the cross-section of C, and a surjectivity argument showing that the map from compactly supported metric variations to forcing terms in the linearised minimal-surface equation on C has dense range. Second, we establish that the set of metrics admitting no area-minimizer with a prescribed cone type as tangent cone is open, using compactness of integral currents and upper-semicontinuity of the density function. Third, we assemble these ingredients via a Baire category argument, intersecting countably many open dense sets to obtain the residual set G. An extension to non-isolated singularities is outlined using Federer--Almgren dimension reduction.