Convergence of the Yang-Mills-Higgs flow on gauged holomorphic maps and applications

Abstract: The symplectic vortex equations admit a variational description as global minimum of the Yang-Mills-Higgs functional. We study its negative gradient flow on holomorphic pairs $(A,u)$ where $A$ is a connection on a principal $G$-bundle $P$ over a closed Riemann surface $\Sigma$ and $u: P \rightarrow X$ is an equivariant map into a K\"ahler Hamiltonian $G$-manifold. The connection $A$ induces a holomorphic structure on the K\"ahler fibration $P\times_G X$ and we require that $u$ descends to a holomorphic section of this fibration. We prove a Lojasiewicz type gradient inequality and show uniform convergence of the negative gradient flow in the $W^{1,2}\times W^{2,2}$-topology when $X$ is equivariantly convex at infinity with proper moment map, $X$ is holomorphically aspherical and its K\"ahler metric is analytic. As applications we establish several results inspired by finite dimensional GIT: First, we prove a certain uniqueness property for the critical points of the Yang-Mills-Higgs functional which is the analogue of the Ness uniqueness theorem. Second, we extend Mundet's Kobayashi-Hitchin correspondence to the polystable and semistable case. The arguments for the polystable case lead to a new proof in the stable case. Third, in proving the semistable correspondence, we establish the moment-weight inequality for the vortex equation and prove the analogue of the Kempf existence and uniqueness theorem.