The Structure of Isoperimetric Bubbles on Rn and Sn

Abstract

The multi-bubble isoperimetric conjecture in n-dimensional Euclidean and spherical spaces from the 1990's asserts that standard bubbles uniquely minimize total perimeter among all q-1 bubbles enclosing prescribed volume, for any q ≤ n+2. The double-bubble conjecture on R3 was confirmed in 2000 by Hutchings-Morgan-Ritor\'e-Ros, and is nowadays fully resolved for all n ≥ 2. The double-bubble conjecture on S2 and triple-bubble conjecture on R2 have also been resolved, but all other cases are in general open. We confirm the conjecture on Rn and on Sn for all q ≤ (5,n+1), namely: the double-bubble conjectures for n ≥ 2, the triple-bubble conjectures for n ≥ 3 and the quadruple-bubble conjectures for n ≥ 4. In fact, we show that for all q ≤ n+1, a minimizing cluster necessarily has spherical interfaces, and after stereographic projection to Sn, its cells are obtained as the Voronoi cells of q affine-functions, or equivalently, as the intersection with Sn of convex polyhedra in Rn+1. Moreover, the cells (including the unbounded one) are necessarily connected and intersect a common hyperplane of symmetry, resolving a conjecture of Heppes. We also show for all q ≤ n+1 that a minimizer with non-empty interfaces between all pairs of cells is necessarily a standard bubble. The proof makes crucial use of considering Rn and Sn in tandem and of M\"obius geometry and conformal Killing fields; it does not rely on establishing a PDI for the isoperimetric profile as in the Gaussian setting, which seems out of reach in the present one.

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