Topology Controlled Potts Coarsening

Abstract

We uncover unusual topological features in the long-time relaxation of the q-state kinetic Potts ferromagnet on the triangular lattice that is instantaneously quenched to zero temperature from a zero-magnetization initial state. For q=3, the final state is either: the ground state (frequency ≈ 0.75), a frozen three-hexagon state (frequency ≈ 0.16), a two-stripe state (frequency ≈ 0.09), or a three-stripe state (frequency <2× 10-4). Other final state topologies, such as states with more than 3 hexagons, occur with probability 10-5 or smaller, for q=3. The relaxation to the frozen three-hexagon state is governed by a time that scales as L2 L. We provide a heuristic argument for this anomalous scaling and present additional new features of Potts coarsening on the triangular lattice for q=3 and for q>3.