X-type and Y-type junction stability in domain wall networks

Abstract

We develop an analytic formalism that allows one to quantify the stability properties of X-type and Y-type junctions in domain wall networks in two dimensions. A similar approach might be applicable to more general defect systems involving junctions that appear in a range of physical situations, for example, in the context of F- and D-type strings in string theory. We apply this formalism to a particular field theory, Carter's pentavac model, where the strength of the symmetry breaking is governed by the parameter |ε|< 1. We find that for low values of the symmetry breaking parameter X-type junctions will be stable, whereas for higher values an X-type junction will separate into two Y-type junctions. The critical angle separating the two regimes is given by αc = 293|ε| and this is confirmed using simple numerical experiments. We go on to simulate the pentavac model from random initial conditions and we find that the dominant junction is of for |ε| ≥ 0.02 and is of for |ε| ≤ 0.02. We also find that for small ε the evolution of the number of domain walls Ndw in Minkowski space does not follow the standard t-1 scaling law with the deviation from the standard lore being more pronounced as ε is decreased. The presence of dissipation appears to restore the t-1$ lore.