Convergence of the self-dual U(1)-Yang-Mills-Higgs energies to the (n-2)-area functional

Abstract

Given a hermitian line bundle L M on a closed Riemannian manifold (Mn,g), the self-dual Yang-Mills-Higgs energies are a natural family of functionals align* &Eε(u,∇):=∫M(|∇ u|2+ε2|F∇|2+(1-|u|2)24ε2) align* defined for couples (u,∇) consisting of a section u∈(L) and a hermitian connection ∇ with curvature F∇. While the critical points of these functionals have been well-studied in dimension two by the gauge theory community, it was shown in previous work of the second- and third-named authors that critical points in higher dimension converge as ε 0 (in an appropriate sense) to minimal submanifolds of codimension two, with strong parallels to the correspondence between the Allen-Cahn equations and minimal hypersurfaces. In this paper, we complement this idea by showing the -convergence of Eε to (2π times) the codimension two area: more precisely, given a family of couples (uε,∇ε) with ε Eε(uε,∇ε)<∞, we prove that a suitable gauge invariant Jacobian J(uε,∇ε) converges to an integral (n-2)-cycle , in the homology class dual to the Euler class c1(L), with mass 2 π M()ε → 0Eε(uε,∇ε). We also obtain a recovery sequence for any integral cycle in this homology class. Finally, we apply these techniques to compare min-max values for the (n-2)-area from the Almgren-Pitts theory with those obtained from the Yang-Mills-Higgs framework, showing that the former values always provide a lower bound for the latter. As an ingredient, we also establish a Huisken-type monotonicity result along the gradient flow of Eε.