Existence of Multiple Vortices in Supersymmetric Gauge Field Theory

Abstract

Two sharp existence and uniqueness theorems are presented for solutions of multiple vortices arising in a six-dimensional brane-world supersymmetric gauge field theory under the general gauge symmetry group G=U(1)× SU(N) and with N Higgs scalar fields in the fundamental representation of G. Specifically, when the space of extra dimension is compact so that vortices are hosted in a 2-torus of volume ||, the existence of a unique multiple vortex solution representing n1,...,nN respectively prescribed vortices arising in the N species of the Higgs fields is established under the explicitly stated necessary and sufficient condition \[ ni<g2v28π N||+1N(1-1N[ge]2)n, i=1,...,N,] where e and g are the U(1) electromagnetic and SU(N) chromatic coupling constants, v measures the energy scale of broken symmetry, and n=Σi=1N ni is the total vortex number; when the space of extra dimension is the full plane, the existence and uniqueness of an arbitrarily prescribed n-vortex solution of finite energy is always ensured. These vortices are governed by a system of nonlinear elliptic equations, which may be reformulated to allow a variational structure. Proofs of existence are then developed using the methods of calculus of variations.