Merging of Dirac points through uniaxial modulation on an optical lattice

A. López; B. Montañes; E. Medina

doi:10.5488/CMP.26.13503

Merging of Dirac points through uniaxial modulation on an optical lattice

A. López
, B. Montañes
, E. Medina

Física

Escuela Superior Politécnica del Litoral
Instituto Venezolano de Investigaciones Científicas

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

Abstract

We analyze the scenario of modulating the potential strength of bound atoms in an optical honeycomb lattice patterned by an electric field to emulate uniaxial strain. This modulation can be achieved by a combination of the strength of the patterned electric field and gauge vector effects using the Floquet approach. We show that such a modulation allows one to follow through a topological transition between a semi-metal and a band insulator, when two non-equivalent K points merge as a function of the electric field strength. We explicitly compute the wavefunctions for the moving K points and the Chern numbers up to the transition.

Original language	English
Article number	13503
Journal	Condensed Matter Physics
Volume	26
Issue number	1
DOIs	https://doi.org/10.5488/CMP.26.13503
State	Published - 4 Jan 2023

Keywords

Bloch-Floquet theorem
cold gases in optical lattices
graphene
topological phase transition

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abstract = "We analyze the scenario of modulating the potential strength of bound atoms in an optical honeycomb lattice patterned by an electric field to emulate uniaxial strain. This modulation can be achieved by a combination of the strength of the patterned electric field and gauge vector effects using the Floquet approach. We show that such a modulation allows one to follow through a topological transition between a semi-metal and a band insulator, when two non-equivalent K points merge as a function of the electric field strength. We explicitly compute the wavefunctions for the moving K points and the Chern numbers up to the transition.",

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AU - López, A.

AU - Montañes, B.

AU - Medina, E.

N1 - Publisher Copyright: © This work is licensed under a 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 - 2023/1/4

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N2 - We analyze the scenario of modulating the potential strength of bound atoms in an optical honeycomb lattice patterned by an electric field to emulate uniaxial strain. This modulation can be achieved by a combination of the strength of the patterned electric field and gauge vector effects using the Floquet approach. We show that such a modulation allows one to follow through a topological transition between a semi-metal and a band insulator, when two non-equivalent K points merge as a function of the electric field strength. We explicitly compute the wavefunctions for the moving K points and the Chern numbers up to the transition.

AB - We analyze the scenario of modulating the potential strength of bound atoms in an optical honeycomb lattice patterned by an electric field to emulate uniaxial strain. This modulation can be achieved by a combination of the strength of the patterned electric field and gauge vector effects using the Floquet approach. We show that such a modulation allows one to follow through a topological transition between a semi-metal and a band insulator, when two non-equivalent K points merge as a function of the electric field strength. We explicitly compute the wavefunctions for the moving K points and the Chern numbers up to the transition.

KW - Bloch-Floquet theorem

KW - cold gases in optical lattices

KW - graphene

KW - topological phase transition

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DO - 10.5488/CMP.26.13503

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VL - 26

JO - Condensed Matter Physics

JF - Condensed Matter Physics

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ER -

Merging of Dirac points through uniaxial modulation on an optical lattice

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Keywords

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