Exploring the grand-canonical phase diagram of interacting bosons in optical lattices by trap squeezing

TL;DR

This paper proposes a method using trap squeezing in cold atom experiments to explore the phase diagram of the Bose-Hubbard model, linking global chemical potential control to local measurements of density and coherence.

Contribution

It introduces a scaling relation for the chemical potential in trapped bosons, enabling experimental access to the bulk phase diagram through trap manipulation and local measurements.

Findings

Scaling relation accurately links global chemical potential to Hamiltonian parameters.

Trap squeezing allows experimental control of chemical potential independently.

Density and coherence measurements distinguish different quantum phases.

Abstract

In this paper we theoretically discuss how quantum simulators based on trapped cold bosons in optical lattices can explore the grand-canonical phase diagram of homogeneous lattice boson models, via control of the trapping potential independently of all other experimental parameters (trap squeezing). Based on quantum Monte Carlo, we establish the general scaling relation linking the global chemical potential to the Hamiltonian parameters of the Bose-Hubbard model in a parabolic trap, describing cold bosons in optical lattices; we find that this scaling relation is well captured by a modified Thomas-Fermi scaling behavior - corrected for quantum fluctuations - in the case of high enough density and/or weak enough interactions, and by a mean-field Gutzwiller Ansatz over a much larger parameter range. The above scaling relation allows to control experimentally the chemical potential, independently of all other Hamiltonian parameters, via trap squeezing; given that the global chemical potential coincides with the local chemical potential in the trap center, measurements of the central density as a function of the chemical potential gives access to the information on the bulk compressibility of the Bose-Hubbard model. Supplemented with time-of-flight measurements of the coherence properties, the measurement of compressibility enables one to discern among the various possible phases realized by bosons in an optical lattice with or without external (periodic or random) potentials -- e.g. superfluid, Mott insulator, band insulator, and Bose glass. We theoretically demonstrate the trap-squeezing investigation of the above phases in the case of bosons in a one-dimensional optical lattice, and in a one-dimensional incommensurate superlattice.