Exploring Interacting Topological Insulators with Ultracold Atoms: The Synthetic Creutz-Hubbard Model

Exploring Interacting Topological Insulators with Ultracold Atoms: The Synthetic Creutz-Hubbard Model

Understanding the robustness of topological phases of matter in the presence of strong interactions and synthesizing novel strongly correlated topological materials lie among the most important and difficult challenges of modern theoretical and experimental physics. In this work, we present a comple...

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Main Authors: J. Jünemann, A. Piga, S.-J. Ran, M. Lewenstein, M. Rizzi, A. Bermudez
Format: Article
Language:English
Published: American Physical Society 2017-09-01
Series:Physical Review X
Online Access:http://doi.org/10.1103/PhysRevX.7.031057
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spelling doaj-7e37f47a23dd4c70952e2b709b151c7f2020-11-25T01:32:09ZengAmerican Physical SocietyPhysical Review X2160-33082017-09-017303105710.1103/PhysRevX.7.031057Exploring Interacting Topological Insulators with Ultracold Atoms: The Synthetic Creutz-Hubbard ModelJ. JünemannA. PigaS.-J. RanM. LewensteinM. RizziA. BermudezUnderstanding the robustness of topological phases of matter in the presence of strong interactions and synthesizing novel strongly correlated topological materials lie among the most important and difficult challenges of modern theoretical and experimental physics. In this work, we present a complete theoretical analysis of the synthetic Creutz-Hubbard ladder, which is a paradigmatic model that provides a neat playground to address these challenges. We give special attention to the competition of correlated topological phases and orbital quantum magnetism in the regime of strong interactions. These results are, furthermore, confirmed and extended by extensive numerical simulations. Moreover, we propose how to experimentally realize this model in a synthetic ladder made of two internal states of ultracold fermionic atoms in a one-dimensional optical lattice. Our work paves the way towards quantum simulators of interacting topological insulators with cold atoms.http://doi.org/10.1103/PhysRevX.7.031057
collection DOAJ
language English
format Article
sources DOAJ
author J. Jünemann
A. Piga
S.-J. Ran
M. Lewenstein
M. Rizzi
A. Bermudez
spellingShingle J. Jünemann
A. Piga
S.-J. Ran
M. Lewenstein
M. Rizzi
A. Bermudez
Exploring Interacting Topological Insulators with Ultracold Atoms: The Synthetic Creutz-Hubbard Model
Physical Review X
author_facet J. Jünemann
A. Piga
S.-J. Ran
M. Lewenstein
M. Rizzi
A. Bermudez
author_sort J. Jünemann
title Exploring Interacting Topological Insulators with Ultracold Atoms: The Synthetic Creutz-Hubbard Model
title_short Exploring Interacting Topological Insulators with Ultracold Atoms: The Synthetic Creutz-Hubbard Model
title_full Exploring Interacting Topological Insulators with Ultracold Atoms: The Synthetic Creutz-Hubbard Model
title_fullStr Exploring Interacting Topological Insulators with Ultracold Atoms: The Synthetic Creutz-Hubbard Model
title_full_unstemmed Exploring Interacting Topological Insulators with Ultracold Atoms: The Synthetic Creutz-Hubbard Model
title_sort exploring interacting topological insulators with ultracold atoms: the synthetic creutz-hubbard model
publisher American Physical Society
series Physical Review X
issn 2160-3308
publishDate 2017-09-01
description Understanding the robustness of topological phases of matter in the presence of strong interactions and synthesizing novel strongly correlated topological materials lie among the most important and difficult challenges of modern theoretical and experimental physics. In this work, we present a complete theoretical analysis of the synthetic Creutz-Hubbard ladder, which is a paradigmatic model that provides a neat playground to address these challenges. We give special attention to the competition of correlated topological phases and orbital quantum magnetism in the regime of strong interactions. These results are, furthermore, confirmed and extended by extensive numerical simulations. Moreover, we propose how to experimentally realize this model in a synthetic ladder made of two internal states of ultracold fermionic atoms in a one-dimensional optical lattice. Our work paves the way towards quantum simulators of interacting topological insulators with cold atoms.
url http://doi.org/10.1103/PhysRevX.7.031057
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