The mobility of dual vortices in honeycomb, square, triangular, Kagome and dice lattices

Abstract

It was known that by a duality transformation, interaction bosons at filling factor f=p/q hopping on a lattice can be mapped to interacting vortices hopping on the dual lattice subject to a fluctuating dual " magnetic field" whose average strength through a dual plaquette is equal to the boson density f=p/q .So the kinetic term of the vortices is the same as the Hofstadter problem of electrons moving in a lattice in the presence of f=p/q flux per plaquette. Motivated by this mapping, we study the Hofstadter bands of vortices hopping in the presence of magnetic flux f=p/q per plaquette on 5 most common bi-partisian and frustrated lattices such as square, honeycomb, triangular, dice and Kagome lattices. We also determine the number of minima and their locations in the lowest band. We numerically calculate the bandwidths of the lowest Hofstadter bands in these lattices and find that except the Kagome lattice at odd q , they all satisfy the exponential decay law W = A e-cq even at the smallest q . We determine (A, c) for the 5 different lattices. When q=2 , we find that the lowest Hofstadter band is completely flat for both Kagome and dice lattices. This indicates that the boson ground state at half filling with nearest neighbor hopping on Kagome and dice lattice is always a superfluid state,in contrast to the triangular lattice where the boson ground state was shown previously to undergo a transition from superfluid to supersolid state.

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