Plateau Bubbles and the Quintuple Bubble Theorem on Sn

Abstract

Sullivan's multi-bubble isoperimetric conjectures in n-dimensional Euclidean and spherical spaces assert 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 by Hutchings-Morgan-Ritor\'e-Ros (and later extended to Rn). The double-bubble conjecture on Sn (n ≥ 2) and the triple- and quadruple- bubble conjectures on Rn and Sn (for n ≥ 3 and n ≥ 4, respectively) were recently confirmed in our previous work, but the approach employed there does not seem to allow extending these results further. In this work, we confirm the quintuple-bubble conjecture on Sn (n ≥ 5), and as a consequence, by approximation, also the quintuple-bubble conjecture on Rn (n ≥ 5) but without the uniqueness assertion. Moreover, we resolve the conjectures on Sn and on Rn (without uniqueness) for all q ≤ n+1, conditioned on the assumption that the singularities which appear at the meeting locus of several bubbles obey a higher-dimensional analogue of Plateau's laws. Another scenario we can deal with is when the bubbles are full-dimensional ("in general position"), or arrange in some good lower-dimensional configurations. To this end, we develop the spectral theory of the corresponding Jacobi operator (finding analogies with the quantum-graph formalism), and a new method for deforming the bubbles into a favorable configuration. As a by-product, we show that the Jacobi operator on a minimizing configuration always has index precisely q-1 and hence the corresponding isoperimetric profile is concave, answering a question of Heppes. Several compelling conjectures are proposed, which would allow extending our results to all q ≤ n+1 unconditionally.