Quantum phases of hardcore bosons with repulsive dipolar density-density interactions on two-dimensional lattices

TL;DR

This paper investigates the quantum phase diagram of hardcore bosons with long-range dipolar interactions on various 2D lattices, revealing a rich interplay of solid, supersolid, and superfluid phases through a classical mean-field approach.

Contribution

It introduces a classical spin mean-field method that accurately captures long-range interactions without truncation across different lattice geometries.

Findings

Solid phases form a devil's staircase at zero hopping.

Gapped phases persist at finite hopping, transitioning to supersolids.

Superfluid phases dominate at large hopping amplitudes.

Abstract

We analyse the ground-state quantum phase diagram of hardcore Bosons interacting with repulsive dipolar potentials. The bosons dynamics is described by the extended-Bose-Hubbard Hamiltonian on a two-dimensional lattice. The ground state results from the interplay between the lattice geometry and the long-range interactions, which we account for by means of a classical spin mean-field approach limited by the size of the considered unit cells. This extended classical spin mean-field theory accounts for the long-range density-density interaction without truncation. We consider three different lattice geometries: square, honeycomb, and triangular. In the limit of zero hopping the ground state is always a devil's staircase of solid (gapped) phases. Such crystalline phases with broken translational symmetry are robust with respect to finite hopping amplitudes. At intermediate hopping amplitudes, these gapped phases melt, giving rise to various lattice supersolid phases, which can have exotic features with multiple sublattice densities. At sufficiently large hoppings the ground state is a superfluid. The stability of phases predicted by our approach is gauged by comparison to the known quantum phase diagrams of the Bose-Hubbard model with nearest-neighbour interactions as well as quantum Monte Carlo simulations for the dipolar case on the square and triangular lattice. Our results are of immediate relevance for experimental realisations of self-organised crystalline ordering patterns in analogue quantum simulators, e.g., with ultracold dipolar atoms in an optical lattice.