Symmetry breaking and restoration in the Ginzburg-Landau model of nematic liquid crystals

Abstract

In this paper we study qualitative properties of global minimizers of the Ginzburg-Landau energy which describes light-matter interaction in the theory of nematic liquid crystals near the Friedrichs transition. This model is depends on two parameters: ε>0 which is small and represents the coherence scale of the system and a≥ 0 which represents the intensity of the applied laser light. In particular we are interested in the phenomenon of symmetry breaking as a and ε vary. We show that when a=0 the global minimizer is radially symmetric and unique and that its symmetry is instantly broken as a>0 and then restored for sufficiently large values of a. Symmetry breaking is associated with the presence of a new type of topological defect which we named the shadow vortex. The symmetry breaking scenario is a rigorous confirmation of experimental and numerical results obtained in our earlier work.