Topological px+ipy Superfluid Phase of a Dipolar Fermi Gas in a 2D Optical Lattice

Abstract

In a dipolar Fermi gas, the anisotropic interaction between electric dipoles can be turned into an effectively attractive interaction in the presence of a rotating electric field. We show that the topological px+ipy superfluid phase can be realized in a single-component dipolar Fermi gas trapped in a 2D square optical lattice with this attractive interaction at low temperatures. The px+ipy superfluid state has potential applications for topological quantum computing. We obtain the phase diagram of this system at zero temperature. In the weak-coupling limit, the p-wave superfluid phase is stable for all filling factors. As the interaction strength increases, it is stable close to filling factors n=0 or n=1, and phase separation takes place in between. When the interaction strength is above a threshold, the system is phase separated for any 0<n<1. The transition temperature of the px+ipy superfluid state is estimated and the implication for experiments is discussed.