Strong-coupling RPA theory of a Bose gas near the superfluid--Mott-insulator transition: universal thermodynamics and two-body contact

Abstract

We present a strong-coupling expansion of the Bose-Hubbard model based on a mean-field treatment of the hopping term, while onsite fluctuations are taken into account exactly. This random phase approximation (RPA) describes the universal features of the generic Mott-insulator--superfluid transition (induced by a density change) and the superfluid state near the phase transition. The critical quasi-particles at the quantum critical point have a quadratic dispersion with an effective mass m* and their mutual interaction is described by an effective s-wave scattering length a*. The singular part of the pressure takes the same form as in a dilute Bose gas, provided we replace the boson mass m and the scattering length in vacuum a by m* and a*, and the density n by the excess density |n-n MI| of particles (or holes) with respect to the Mott insulator. We define a ``universal'' two-body contact C univ that controls the high-momentum tail 1/| k|4 of the singular part n sing k of the momentum distribution. We also apply the strong-coupling RPA to a lattice model of hard-core bosons and find that the high-momentum distribution is controlled by a universal contact, in complete agreement with the Bose-Hubbard model. Finally, we discuss a continuum model of bosons in an optical lattice and define two additional two-body contacts: a short-distance ``universal'' contact C univ sd which controls the high-momentum tail of n sing k at scales larger than the inverse lattice spacing, and a ``full'' contact C which controls the high-momentum tail of the full momentum distribution n k.