Double commutator method for a two band Bose-Einstein condensate: superfluid density of a flat band superfluid
Abstract
In this work, we propose a double commutator method for a general two-band bosonic superfluid. First and foremost, we prove that the sum of the superfluid and normal densities is equal to the weight of the f-sum rule. This weight can be easily determined by analyzing the ground state wave function. Once we have determined the excitation gap of the upper band, we can calculate the normal density by evaluating the average value of a double commutator between the velocity operator and the Hamiltonian. As an application of this method, we investigate the superfluid density of a flat band Bose-Einstein condensate (BEC). Using the Bogoliubov method, we calculate the sound velocity and excitation gap, which allows us to obtain the normal and superfluid densities explicitly. Our findings indicate that the superfluid density is directly proportional to the product of the square of the sound velocity and the compressibility. Furthermore, the existence of a non-vanishing superfluid density depends on the form of the interaction. For example, in the case of U(2) invariant interactions, the superfluid density is zero. Additionally, we have observed that for small interactions, the superfluid density is directly proportional to the product of the interaction parameter and the quantum metric. The double commutator method indicates that the correction of the excitation gap by interactions is the origin of the non-vanishing superfluid density of a flat band BEC. Up to the linear order of the interaction parameters, all the results for the excitation gap, the normal and superfluid densities in a flat band BEC can also be obtained through a simple perturbation theory. Our work provides another unique perspective on the superfluid behavior of a flat band BEC.
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