Self-organized bosonic domain walls

Xingchuan Zhu; Shiying Dong; Yang Lin; Rubem Mondaini; Huaiming Guo; Shiping Feng; Richard T. Scalettar

doi:10.1103/PhysRevResearch.2.013085

Self-organized bosonic domain walls

Xingchuan Zhu
, Shiying Dong
, Yang Lin
, Rubem Mondaini
, Huaiming Guo
, Shiping Feng
, Richard T. Scalettar

School of Physics

Research output: Contribution to journal › Article › peer-review

4 Scopus citations

Abstract

Hard-core bosons on honeycomb lattice ribbons with zigzag edges are studied using exact numerical simulations. We map out the phase diagrams of ribbons with different widths, which contain superfluid and insulator phases at various fillings. We show that charge domain walls are energetically favorable, in sharp contrast to the more typical occupation of a set of sites on a single sublattice of the bipartite geometry at ρ=12 filling. This "self-organized domain wall"separates two charge-density-wave regions with opposite Berry curvatures. Associated with the change of topological properties, superfluid transport occurs down the domain wall. Our results provide a concrete context to observe bosonic topological phenomena and can be simulated experimentally using bosonic cold atoms trapped in designed optical lattices.

Original language	English
Article number	013085
Journal	Physical Review Research
Volume	2
Issue number	1
DOIs	https://doi.org/10.1103/PhysRevResearch.2.013085
State	Published - Jan 2020

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10.1103/PhysRevResearch.2.013085

Cite this

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title = "Self-organized bosonic domain walls",

abstract = "Hard-core bosons on honeycomb lattice ribbons with zigzag edges are studied using exact numerical simulations. We map out the phase diagrams of ribbons with different widths, which contain superfluid and insulator phases at various fillings. We show that charge domain walls are energetically favorable, in sharp contrast to the more typical occupation of a set of sites on a single sublattice of the bipartite geometry at ρ=12 filling. This {"}self-organized domain wall{"}separates two charge-density-wave regions with opposite Berry curvatures. Associated with the change of topological properties, superfluid transport occurs down the domain wall. Our results provide a concrete context to observe bosonic topological phenomena and can be simulated experimentally using bosonic cold atoms trapped in designed optical lattices.",

author = "Xingchuan Zhu and Shiying Dong and Yang Lin and Rubem Mondaini and Huaiming Guo and Shiping Feng and Scalettar, \{Richard T.\}",

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doi = "10.1103/PhysRevResearch.2.013085",

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AU - Zhu, Xingchuan

AU - Dong, Shiying

AU - Lin, Yang

AU - Mondaini, Rubem

AU - Guo, Huaiming

AU - Feng, Shiping

AU - Scalettar, Richard T.

N1 - Publisher Copyright: © 2020 authors. Published by the American Physical Society. Published by the American Physical Society under the terms of the Creative Commons Attribution 4.0 International license. Further distribution of this work must maintain attribution to the author(s) and the published article's title, journal citation, and DOI.

PY - 2020/1

Y1 - 2020/1

N2 - Hard-core bosons on honeycomb lattice ribbons with zigzag edges are studied using exact numerical simulations. We map out the phase diagrams of ribbons with different widths, which contain superfluid and insulator phases at various fillings. We show that charge domain walls are energetically favorable, in sharp contrast to the more typical occupation of a set of sites on a single sublattice of the bipartite geometry at ρ=12 filling. This "self-organized domain wall"separates two charge-density-wave regions with opposite Berry curvatures. Associated with the change of topological properties, superfluid transport occurs down the domain wall. Our results provide a concrete context to observe bosonic topological phenomena and can be simulated experimentally using bosonic cold atoms trapped in designed optical lattices.

AB - Hard-core bosons on honeycomb lattice ribbons with zigzag edges are studied using exact numerical simulations. We map out the phase diagrams of ribbons with different widths, which contain superfluid and insulator phases at various fillings. We show that charge domain walls are energetically favorable, in sharp contrast to the more typical occupation of a set of sites on a single sublattice of the bipartite geometry at ρ=12 filling. This "self-organized domain wall"separates two charge-density-wave regions with opposite Berry curvatures. Associated with the change of topological properties, superfluid transport occurs down the domain wall. Our results provide a concrete context to observe bosonic topological phenomena and can be simulated experimentally using bosonic cold atoms trapped in designed optical lattices.

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Self-organized bosonic domain walls

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