Nonlocal Correlation and Entanglement of Ultracold Bosons in the 2D Bose–Hubbard Lattice at Finite Temperature

The temperature‐dependent behavior emerging in the vicinity of the superfluid (SF) to Mott‐insulator (MI) transition of interacting bosons in a 2D optical lattice, described by the Bose–Hubbard model is investigated. The equilibrium phase diagram at finite‐temperature is computed using the cluster m...

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Bibliographic Details
Published in:Annalen der Physik 2022-05, Vol.534 (5), p.n/a
Main Authors: Pohl, Ulli, Ray, Sayak, Kroha, Johann
Format: Article
Language:English
Subjects:
Acoustic velocity
Bose–Hubbard model
Bosons
cluster mean‐field theory
Clusters
cold gases, optical lattices
Compressibility
Critical point
Entropy
Fluids
Optical lattices
Phase diagrams
Superfluidity
superfluids
Temperature
Temperature dependence
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Summary:The temperature‐dependent behavior emerging in the vicinity of the superfluid (SF) to Mott‐insulator (MI) transition of interacting bosons in a 2D optical lattice, described by the Bose–Hubbard model is investigated. The equilibrium phase diagram at finite‐temperature is computed using the cluster mean‐field (CMF) theory including a finite‐cluster‐size‐scaling. The SF, MI, and normal fluid (NF) phases are characterized as well as the transition or crossover temperatures between them are estimated by computing physical quantities such as the superfluid fraction, compressibility and sound velocity using the CMF method. It is found that the nonlocal correlations included in a finite cluster, when extrapolated to infinite size, leads to quantitative agreement of the phase boundaries with quantum Monte Carlo (QMC) results as well as with experiments. Moreover, it is shown that the von Neumann entanglement entropy within a cluster corresponds to the system's entropy density and that it is enhanced near the SF–MI quantum critical point (QCP) and at the SF–NF boundary. The behavior of the transition lines near this QCP, at and away from the particle‐hole (p–h) symmetric point located at the Mott‐tip, is also discussed. The results obtained by using the CMF theory can be tested experimentally using the quantum gas microscopy method. A temperature‐dependent behavior, emerging in the vicinity of superfluid to Mott‐insulator transition of interacting bosons in a two‐dimensional Bose‐Hubbard lattice at finite temperature, is investigated using a numerically inexpensive cluster‐mean‐field theory. Nonlocal correlations included within clusters, after an appropriate cluster‐size scaling, leads to quantitative agreement of the phase boundaries and their critical exponents with quantum Monte‐Carlo results and with experiments.
ISSN:0003-3804
1521-3889
DOI:10.1002/andp.202100581