Emergence of topological Mott insulators in proximity of quadratic band touching points

Abstract

Recently, the field of strongly correlated electrons has begun an intense search for a correlation induced topological insulating phase. An example is the quadratic band touching point which arises in a checkerboard lattice at half-filling, and in the presence of interactions gives rise to topological Mott insulators. In this work, we perform a mean-field theory computation to show that such a system shows instability to topological insulating phases even away from half-filling (chemical potential μ = 0 ). The interaction parameters consist of on-site repulsion ( U ), nearest-neighbour repulsion ( V ), and a next-nearest-neighbour correlated hopping ( tc ). The tc interaction originates from strong Coulomb repulsion. By tuning the values of these parameters, we obtain a desired topological phase that spans the area around (V = 0 , μ = 0), extending to regions with (V>0,μ=0) and (V>0,μ>0). This extends the realm of current experimental efforts to find these topological phases.