Journal article

Characterizing the phase diagram of finite-size dipolar Bose-Hubbard systems

Abstract:: We use state-of-the-art density matrix renormalization group calculations in the canonical ensemble to determine the phase diagram of the dipolar Bose-Hubbard model on a finite cylinder. We consider several observables that are accessible in typical optical lattice setups and assess how well these quantities perform as order parameters. We find that, especially for small systems, the occupation imbalance is less susceptible to boundary effects than the structure factor in uncovering the presence of a periodic density modulation. By analyzing the nonlocal correlations, we find that the appearance of supersolid order is very sensitive to boundary effects, which may render it difficult to observe in quantum gas lattice experiments with a few tens of particles. Finally, we show that density measurements readily obtainable on a quantum gas microscope allow distinguishing between superfluid and solid phases using unsupervised machine-learning techniques.

Publication status:: Published

Peer review status:: Peer reviewed

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APA Style

Rosson, P., Kiffner, M., Mur-Petit, J., & Jaksch, D. (2020). Characterizing the phase diagram of finite-size dipolar Bose-Hubbard systems. Physical Review A, 101(1).

MLA Style

Rosson, P., et al. “Characterizing the Phase Diagram of Finite-Size Dipolar Bose-Hubbard Systems.” Physical Review A, vol. 101, no. 1, American Physical Society, 2020.

Chicago Style

Rosson, P, M Kiffner, J Mur-Petit, and D Jaksch. 2020. “Characterizing the Phase Diagram of Finite-Size Dipolar Bose-Hubbard Systems.” Physical Review A 101 (1).
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Files:: PhysRevA.101.013616.pdf

(Preview, Version of record, pdf, 1.5MB, Terms of use)

Publisher copy:: 10.1103/PhysRevA.101.013616

Authors

+ Rosson, P More by this author

Role:: Author

+ Kiffner, M More by this author

Role:: Author

+ Mur-Petit, J More by this author

Institution:: University of Oxford
Division:: MPLS
Department:: Physics
Sub department:: Atomic & Laser Physics
Role:: Author

+ Jaksch, D More by this author

Role:: Author

+ European Research Council More from this funder

Grant:: 319286

+ Engineering and Physical Sciences Research Council More from this funder

Grant:: EP/M013243/1

Publisher:: American Physical Society
Journal:: Physical Review A More from this journal
Volume:: 101
Issue:: 1
Article number:: 013616
Publication date:: 2020-01-13
Acceptance date:: 2019-12-20
DOI:: 10.1103/PhysRevA.101.013616
EISSN:: 2469-9934
ISSN:: 2469-9926

Language:: English
Keywords:: quantum simulation

quantum many-body physics

tensor network methods

dipolar systems

Bose-Hubbard model

density matrix renormalization group

long-range interactions
Pubs id:: pubs:1078531
UUID:: uuid:c5c73d18-2de6-4989-82c5-e39c5f6a9b9f
Local pid:: pubs:1078531
Source identifiers:: 1078531
Deposit date:: 2019-12-20

Terms of use

Copyright holder:: American Physical Societ
Copyright date:: 2020
Notes:: Copyright © 2020 American Physical Society.

Licence:: Terms and Conditions of Use for Oxford University Research Archive

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