Topologically protected edge states in small Rydberg systems

Sebastian Weber; Sylvain De Léséleuc; Vincent Lienhard; Daniel Barredo; Thierry Lahaye; Antoine Browaeys; Hans Peter Büchler

doi:10.1088/2058-9565/aaca47

Topologically protected edge states in small Rydberg systems

Sebastian Weber
, Sylvain De Léséleuc
, Vincent Lienhard
, Daniel Barredo
, Thierry Lahaye
, Antoine Browaeys
, Hans Peter Büchler

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

Abstract

We propose a simple setup of Rydberg atoms in a honeycomb lattice which gives rise to topologically protected edge states. The proposal is based on the combination of dipolar exchange interaction, which couples the internal angular momentum and the orbital degree of freedom of a Rydberg excitation, and a static magnetic field breaking time reversal symmetry. We demonstrate that for realistic experimental parameters, signatures of topologically protected edge states are present in small systems with as few as 10 atoms. Our analysis paves the way for the experimental realization of Rydberg systems characterized by a topological invariant, providing a promising setup for future application in quantum information.

Original language	English
Article number	044001
Journal	Quantum Science and Technology
Volume	3
Issue number	4
DOIs	https://doi.org/10.1088/2058-9565/aaca47
Publication status	Published - 2 Jul 2018
Externally published	Yes

Keywords

Rydberg atoms
dipolar interaction
edge states
topological insulator

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10.1088/2058-9565/aaca47

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title = "Topologically protected edge states in small Rydberg systems",

abstract = "We propose a simple setup of Rydberg atoms in a honeycomb lattice which gives rise to topologically protected edge states. The proposal is based on the combination of dipolar exchange interaction, which couples the internal angular momentum and the orbital degree of freedom of a Rydberg excitation, and a static magnetic field breaking time reversal symmetry. We demonstrate that for realistic experimental parameters, signatures of topologically protected edge states are present in small systems with as few as 10 atoms. Our analysis paves the way for the experimental realization of Rydberg systems characterized by a topological invariant, providing a promising setup for future application in quantum information.",

keywords = "Rydberg atoms, dipolar interaction, edge states, topological insulator",

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T1 - Topologically protected edge states in small Rydberg systems

AU - Weber, Sebastian

AU - Léséleuc, Sylvain De

AU - Lienhard, Vincent

AU - Barredo, Daniel

AU - Lahaye, Thierry

AU - Browaeys, Antoine

AU - Büchler, Hans Peter

PY - 2018/7/2

Y1 - 2018/7/2

N2 - We propose a simple setup of Rydberg atoms in a honeycomb lattice which gives rise to topologically protected edge states. The proposal is based on the combination of dipolar exchange interaction, which couples the internal angular momentum and the orbital degree of freedom of a Rydberg excitation, and a static magnetic field breaking time reversal symmetry. We demonstrate that for realistic experimental parameters, signatures of topologically protected edge states are present in small systems with as few as 10 atoms. Our analysis paves the way for the experimental realization of Rydberg systems characterized by a topological invariant, providing a promising setup for future application in quantum information.

AB - We propose a simple setup of Rydberg atoms in a honeycomb lattice which gives rise to topologically protected edge states. The proposal is based on the combination of dipolar exchange interaction, which couples the internal angular momentum and the orbital degree of freedom of a Rydberg excitation, and a static magnetic field breaking time reversal symmetry. We demonstrate that for realistic experimental parameters, signatures of topologically protected edge states are present in small systems with as few as 10 atoms. Our analysis paves the way for the experimental realization of Rydberg systems characterized by a topological invariant, providing a promising setup for future application in quantum information.

KW - Rydberg atoms

KW - dipolar interaction

KW - edge states

KW - topological insulator

UR - https://www.scopus.com/pages/publications/85052995869

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DO - 10.1088/2058-9565/aaca47

M3 - Article

AN - SCOPUS:85052995869

SN - 2058-9565

VL - 3

JO - Quantum Science and Technology

JF - Quantum Science and Technology

IS - 4

M1 - 044001

ER -

Topologically protected edge states in small Rydberg systems

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Keywords

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