Minimizing clusters with prescribed asymptotic geometry

Abstract

We construct locally minimizing (1,2)-clusters whose exterior interfaces are asymptotic to various prescribed singular area-minimizing cones. For n+1 ≤ 7, Bronsard & Novack characterized all minimizing (1,2)-clusters as standard lenses, whose exterior interface is planar. For n+1 ∈ [8,2700], the authors together with Bronsard showed the existence of a locally minimizing (1,2)-cluster whose exterior interface blows down to some (unknown, possibly non-unique) singular area-minimizing hypercone. For n+1=8, this was shown independently by Novaga, Paolini & Tortorelli. Here we develop a refined construction using the Hardt-Simon foliation that realizes prescribed cones. For a singular area-minimizing hypercone C that has an isolated singularity or is cylindrical, we show that if C satisfies an explicit energy bound, then there is a locally minimizing (1,2)-cluster whose exterior interface is asymptotic to C with quantitative rates. In fact, if C is an area minimizing Lawson cone satisfying this energy bound, we produce a countably infinite family of distinct locally minimizing clusters asymptotic to C, distinguished by their prescribed asymptotic decay to leading order. We verify this energy bound for the generalized Simons cones Ck,k in every even ambient dimension n+1 = 2k+2≥ 8, and for the cylindrical cone C3,3×R in R9, where C3,3 is the Simons cone, therefore answering the cone realization problem in these cases. This in particular removes the upper bound of 2700 on the ambient dimension when n+1 is even in our preceding work.