Abstract
The Bose glass (BG) phase is the Griffiths region of the disordered Bose–Hubbard model (BHM), characterized by finite, quasi-superfluid clusters within a Mott insulating background. We propose to utilize this characterization to identify the complete zero-temperature phase diagram of the disordered BHM in d ⩾ 2 dimensions by analysing the geometric properties of what we call superfluid (SF) clusters, which are defined to be clusters of sites with non-integer expectation values for the local boson occupation number. The Mott insulator phase then is the region in the phase diagram where no SF clusters exist, and the SF phase the region where SF clusters percolate—the BG phase is inbetween: SF clusters exist, but do not percolate. This definition is particularly useful in the context of local mean field (LMF) or Gutzwiller–Ansatz calculations, where we show that an identification of the phases on the basis of global quantities such as the averaged SF order parameter and the compressibility is misleading. We apply the SF cluster analysis to the LMF ground states of the two-dimensional disordered BHM to produce its phase diagram and find (a) an excellent agreement with the phase diagram predicted on the basis of quantum Monte Carlo simulations for the commensurate density n = 1 and (b) large differences to stochastic mean field and other mean field predictions for fixed disorder strength. The relation of the percolation transition of the SF clusters with the onset of non-vanishing SF stiffness indicating the BG to SF transition is discussed.
Highlights
The experimental proof of the Mott insulator (MI) to superfluid (SF) transition in ultracold atomic systems [1] opened a wide field of interesting research in this field
In this paper we have introduced a new criterion to identify the different phases of the disordered Bose Hubbard model (BHM) in d ≥ 2 on the basis of the complete set of local boson occupation numbers {ni} of each sample and applied it to the ground states calculated using the local mean field (LMF) approximation
In the MI phase all ni are integer, in the Bose glass (BG) phase some of them are non-integer and form SF clusters in a MI background and in the SF phase at least one of these clusters percolates
Summary
The experimental proof of the Mott insulator (MI) to superfluid (SF) transition in ultracold atomic systems [1] opened a wide field of interesting research in this field. The phase diagram and transitions for bosons in a disordered potential was analysed and the existence of a Bose glass (BG) phase was predicted. Studies of the excitation spectrum of the disordered system in dependence of the disorder strength and time-of-flight measurements confirmed the predicted BG phase experimentally [6]. A new view on the properties of ultra cold bosonic gases opened up as high resolution techniques allowed access to single-site detection recently [9, 10]. This progress yields a direct view on the population numbers within the different phases and the in-situ hopping dynamics of the bosons in their optical potential
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