Article ID | Journal | Published Year | Pages | File Type |
---|---|---|---|---|
8255344 | Journal of Geometry and Physics | 2018 | 15 Pages |
Abstract
Existence of Maxwell-Chern-Simons-Higgs (MCSH) vortices in a hermitian line bundle L over a general compact Riemann surface Σ is proved by a continuation method. The solutions are proved to be smooth both spatially and as functions of the Chern-Simons deformation parameter κ, and exist for all |κ|<κâ, where κâ depends, in principle, on the geometry of Σ, the degree n of L, which may be interpreted as the vortex number, and the vortex positions. A simple upper bound on κâ, depending only on n
and the volume of Σ, is found. Further, it is proved that a positive lower bound on κâ, depending on Σ and n, but independent of vortex positions, exists. A detailed numerical study of rotationally equivariant vortices on round two-spheres is performed. We find that κâ in general does depend on vortex positions, and, for fixed n
and radius, tends to be larger the more evenly vortices are distributed between the North and South poles. A generalization of the MCSH model to compact Kähler domains Σ of complex dimension kâ¥1 is formulated. The Chern-Simons term is replaced by the integral over spacetime of Aâ§Fâ§Ïkâ1, where Ï is the Kähler form on Σ. A topological lower bound on energy is found, attained by solutions of a deformed version of the usual vortex equations on Σ. Existence, uniqueness and smoothness of vortex solutions of these generalized equations is proved, for |κ|<κâ, and an upper bound on κâ depending only on the Kähler class of Σ
and the first Chern class of L is obtained.
Related Topics
Physical Sciences and Engineering
Mathematics
Mathematical Physics
Authors
S.P. Flood, J.M. Speight,