Rigidity of an overdetermined heat equation and minimal helicoids in space-forms

Abstract

Let M be a Riemannian manifold and a smooth domain of M. We study the following heat diffusion problem: assume that the initial temperature is equal to 1, uniformly on , and is 0 on its complement. Heat will then flow away from to its complement, and we are interested in the temperature on the boundary of at all positive times t>0. In particular we ask: are there domains for which the temperature at the boundary is a constant c, for all positive times t and for all points of the boundary? If they exist, what can we say about their geometry? This is a typical example of overdetermined heat equation. It is readily seen that if c exists it must be 12, and domains with constant boundary temperature will be said to have the 12-property. Previous work by MPS06 and CSU23 show that, on R3, the only such domains (up to congruences) have boundary which is a plane or (a bit surprisingly) the right helicoid. In this paper we first show that, in great generality, the boundary of a 12-domain must be minimal; we then extend (with a different proof) the above classification from R3 to the other 3-dimensional space-forms. We prove that, in S3, 12-domains are bounded by a totally geodesic surface or the Clifford torus, and in the hyperbolic space H3 are bounded by a totally geodesic surface or by an (embedded) minimal hyperbolic helicoid. %(there is a one-parameter family of such surfaces) As a by-product, we extend (with a different proof) a result by Nitsche on uniformly dense domains from R3 to 3-dimensional space-forms.