Supersolidity of cold-atom Bose-Fermi mixtures in optical lattices

TL;DR

This paper explores supersolid phases in cold Bose-Fermi mixtures on optical lattices, revealing exotic crystalline orders, phase competition, and potential experimental observation in specific atomic mixtures.

Contribution

It introduces a comprehensive theoretical framework for supersolidity in Bose-Fermi mixtures, identifying novel crystalline orders and phase behaviors on various lattice geometries.

Findings

Exotic Kagome-type supersolid phase at 3/4 fermionic band-filling.

Striped supersolid phases on square and triangular lattices.

Supersolidity observable in Rb-K-Na-Li mixtures within accessible temperatures.

Abstract

We investigate a cold atomic mixture of spinless bosons and fermions in two-dimensional optical lattices. In the presence of a nested Fermi surface, the bosons may develop a fascinating supersolid behavior characterized by a finite superfluid density as well as a spatial density wave order. Focusing on the triangular lattice geometry and combining a general Landau-Ginzburg-Wilson approach with microscopically derived mean-field theory, we find an exotic supersolid phase at a fermionic band-filling of $n_f = 3/4$ with a Kagome-type crystalline order. We also address the case of anisotropic hopping amplitudes, and show that striped supersolid phases emerge on the square and triangular lattices. For weak interactions, the supersolid competes with phase separation. For strong intra- and inter-species interactions, with the total number of fermions and bosons corresponding to one particle per site, the bosons form an alternating Mott insulator ground state. Finally, for a mixture of $^{87}\text{Rb}^{40}\text{K}$ and $^{23}\text{Na}^6\text{Li}$, we show that supersolidity can be observed in the range of accessible temperatures in the square lattice geometry.