Superfluid Insulator Transitions of Hard-Core Bosons on the Checkerboard Lattice
Abstract
We study hard-core bosons on the checkerboard lattice with nearest neighbour unfrustrated hopping t and `tetrahedral' plaquette charging energy U. Analytical arguments and Quantum Monte Carlo simulations lead us to the conclusion that the system undergoes a zero temperature (T) quantum phase transition from a superfluid phase at small U/t to a large U/t Mott insulator phase with = 1/4 for a range of values of the chemical potential μ. Further, the quarter-filled insulator breaks lattice translation symmetry in a characteristic four-fold ordering pattern, and occupies a lobe of finite extent in the μ-U/t phase diagram. A Quantum Monte-Carlo study slightly away from the tip of the lobe provides evidence for a direct weakly first-order superfluid-insulator transition away from the tip of the lobe. While analytical arguments leads us to conclude that the transition at the tip of the lobe belongs to a different landau-forbidden second-order universality class, an extrapolation of our numerical results suggests that the size of the first-order jump does not go to zero even at the tip of the lobe.
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