Two-body contact of a Bose gas near the superfluid--Mott-insulator transition

The two-body contact is a fundamental quantity of a dilute Bose gas which relates the thermodynamics to the short-distance two-body correlations. For a Bose gas in an optical lattice, near the superfluid--Mott-insulator transition, a ``universal'' contact $C_{\rm univ}$ can be defined from the singular part $P-P_{\rm MI}$ of the pressure ($P_{\rm MI}$ is the pressure of the Mott insulator). Its expression $C_{\rm univ}=C_{\rm DBG}(|n-n_{\rm MI}|,a^*)$ coincides with that of a dilute Bose gas provided we consider the effective ``scattering length'' $a^*$ of the quasi-particles at the quantum critical point (QCP) rather than the scattering length in vacuum, and the excess density $|n-n_{\rm MI}|$ of particles (or holes) with respect to the Mott insulator. Sufficiently close to the transition, there is a broad momentum range in the Brillouin zone where the singular part $n^{\rm sing}_{\bf k}=n_{\bf k}-n^{\rm MI}_{\bf k}$ of the momentum distribution exhibits the high-momentum tail $Z_{\rm QP} C_{\rm univ}/|{\bf k}|^4$, where $Z_{\rm QP}$ the quasi-particle weight of the elementary excitations at the QCP. We argue that the contact $C_{\rm univ}$ can be measured in state-of-the-art experiments on Bose gases in optical lattices, and in magnetic insulators.
Comment: 6 pages, 4 figures; see also the companion paper submitted to arXiv on the same day