String-wall composites winding around a torus knot vacuum in an axionlike model

Abstract

We study a simple axionlike model with a charged scalar φ and a double-charged scalar ζ of global U(1) symmetry. A particular feature of our model is that a vacuum manifold is a torus knot. We consider a hierarchical symmetry-breaking scenario where ζ first condenses, giving rise to cosmic ζ-strings, and the subsequent condensation of φ leads to domain-wall formation spanning the ζ-strings. We find that the formation of the walls undergoes two different regimes depending on the magnitude of an explicit breaking term of the relative U(1) between ζ and φ. One is the weakly interacting regime where the walls are accompanied by another cosmic φ strings. The other is the strongly interacting regime where no additional strings appear. In both regimes, neither a ζ-string, a φ-string nor a wall alone is topological, but the composite of an appropriate number of strings and walls as a whole is topologically stable, characterized by the fundamental homotopy group of the torus knot. We confirm the formation and the structure of the string-wall system by first-principle cosmological two-dimensional simulations. We find stable string-wall composites at equilibrium, where the repulsive force between ζ-strings and the tension of walls balances, and a novel reconnection of the string-wall composites.