Instability of a Nielsen-Olesen Vortex Embedded in the Electroweak Theory: I. the Single-Component Higgs Gauge
Abstract
The stability of an abelian (Nielsen-Olesen) vortex embedded in the electroweak theory against W production is investigated in a gauge defined by the condition of a single-component Higgs field. The model is characterized by the parameters β=(MH MZ)2 and γ=2θ w where θ w is the weak mixing angle. It is shown that the equations for W's in the background of the Nielsen-Olesen vortex have no solutions in the linear approximation. A necessary condition for the nonlinear equations to have a solution in the region of parameter space where the abelian vortex is classically unstable is that the W's be produced in a state of angular momentum m such that 0>m>-2n. The integer n is defined by the phase of the Higgs field, (in). Solutions for a set of values of the parameters β and γ in this region were obtained numerically for the case -m=n=1. The possibility of existence of a stationary state for n=1 with W's in the state m=-1 was investigated. The boundary conditions for the Euler-Lagrange equations required to make the energy finite cannot be satisfied at r=0. For these values of n and m the possibility of a finite-energy stationary state defined in terms of distributions is discussed.
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