Single-atom addressing in microtraps for quantum-state engineering using Rydberg atoms

Henning Labuhn; Sylvain Ravets; Daniel Barredo; Lucas Béguin; Florence Nogrette; Thierry Lahaye; Antoine Browaeys

doi:10.1103/PhysRevA.90.023415

Single-atom addressing in microtraps for quantum-state engineering using Rydberg atoms

Henning Labuhn
, Sylvain Ravets
, Daniel Barredo
, Lucas Béguin
, Florence Nogrette
, Thierry Lahaye
, Antoine Browaeys

Laboratoire Charles Fabry

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

Abstract

We report on the selective addressing of an individual atom in a pair of single-atom microtraps separated by 3μm. Using a tunable light shift, we render the selected atom off-resonant with a global Rydberg excitation laser which is resonant with the other atom, making it possible to selectively block this atom from being excited to the Rydberg state. Furthermore we demonstrate the controlled manipulation of a two-atom entangled state by using the addressing beam to induce a phase shift onto one component of the wave function of the system, transferring it to a dark state for the Rydberg excitation light. Our results are an important step towards implementing quantum information processing and quantum simulation with large arrays of Rydberg atoms.

Original language	English
Article number	023415
Journal	Physical Review A - Atomic, Molecular, and Optical Physics
Volume	90
Issue number	2
DOIs	https://doi.org/10.1103/PhysRevA.90.023415
Publication status	Published - 22 Aug 2014
Externally published	Yes

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10.1103/PhysRevA.90.023415

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title = "Single-atom addressing in microtraps for quantum-state engineering using Rydberg atoms",

abstract = "We report on the selective addressing of an individual atom in a pair of single-atom microtraps separated by 3μm. Using a tunable light shift, we render the selected atom off-resonant with a global Rydberg excitation laser which is resonant with the other atom, making it possible to selectively block this atom from being excited to the Rydberg state. Furthermore we demonstrate the controlled manipulation of a two-atom entangled state by using the addressing beam to induce a phase shift onto one component of the wave function of the system, transferring it to a dark state for the Rydberg excitation light. Our results are an important step towards implementing quantum information processing and quantum simulation with large arrays of Rydberg atoms.",

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AU - Labuhn, Henning

AU - Ravets, Sylvain

AU - Barredo, Daniel

AU - Béguin, Lucas

AU - Nogrette, Florence

AU - Lahaye, Thierry

AU - Browaeys, Antoine

PY - 2014/8/22

Y1 - 2014/8/22

N2 - We report on the selective addressing of an individual atom in a pair of single-atom microtraps separated by 3μm. Using a tunable light shift, we render the selected atom off-resonant with a global Rydberg excitation laser which is resonant with the other atom, making it possible to selectively block this atom from being excited to the Rydberg state. Furthermore we demonstrate the controlled manipulation of a two-atom entangled state by using the addressing beam to induce a phase shift onto one component of the wave function of the system, transferring it to a dark state for the Rydberg excitation light. Our results are an important step towards implementing quantum information processing and quantum simulation with large arrays of Rydberg atoms.

AB - We report on the selective addressing of an individual atom in a pair of single-atom microtraps separated by 3μm. Using a tunable light shift, we render the selected atom off-resonant with a global Rydberg excitation laser which is resonant with the other atom, making it possible to selectively block this atom from being excited to the Rydberg state. Furthermore we demonstrate the controlled manipulation of a two-atom entangled state by using the addressing beam to induce a phase shift onto one component of the wave function of the system, transferring it to a dark state for the Rydberg excitation light. Our results are an important step towards implementing quantum information processing and quantum simulation with large arrays of Rydberg atoms.

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JO - Physical Review A - Atomic, Molecular, and Optical Physics

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IS - 2

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ER -

Single-atom addressing in microtraps for quantum-state engineering using Rydberg atoms

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