A gauge theoretical generalization of Bryant's correspondence

Abstract

A classical theorem in the theory of minimal surfaces establishes a correspondence between minimal surfaces in Rn and null holomorphic curves in Cn. A hyperbolic version of this correspondence is due to Bryant: null holomorphic curves in SL(2,C) correspond to CMC-1 surfaces in the hyperbolic space H3. We also have a relativistic Bryant type correspondence: CMC-1 immersions in the hyperbolic space are replaced by space-like CMC-1 immersion in the de Sitter space. We prove a mutual generalisation of all these results: let H be a real Lie group, π:P M a principal H-bundle, A a connection on P and α∈ A1 Ad(P,h) a tensorial 1-form of type Ad which induces isomorphisms A h. Such a pair (α,A) defines an almost complex structure JαA on P, which is integrable if and only (α,A) solves a gauge-invariant first order differential system. A non-degenerate symmetric AdH-invariant bilinear form g on h defines pseudo-Riemannian metrics gαM, gαA on M, respectively P, and a non-degenerate bilinear form ωα,gA:TP×P TP C which is holomorphic when JαA is integrable. Assuming that this is the case, we have a Bryant type correspondence between space-like, ωα,gA-isotropic holomorphic immersions Y P and space-like conformal immersions Y (M,gαM) whose mean curvature vector field is given by a simple explicit formula. In particular, one obtains such a correspondence for any principal bundle of the form G G/H, where G is a complex Lie group, and H is a real form of G endowed with a non-degenerate, AdH-invariant, symmetric bilinear form g on its Lie-algebra h.