Single-atom trapping in holographic 2D arrays of microtraps with arbitrary geometries

F. Nogrette; H. Labuhn; S. Ravets; D. Barredo; L. Béguin; A. Vernier; T. Lahaye; A. Browaeys

doi:10.1103/PhysRevX.4.021034

Single-atom trapping in holographic 2D arrays of microtraps with arbitrary geometries

F. Nogrette, H. Labuhn, S. Ravets, D. Barredo, L. Béguin, A. Vernier, T. Lahaye, A. Browaeys

Laboratoire Charles Fabry

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

Abstract

We demonstrate single-atom trapping in two-dimensional arrays of microtraps with arbitrary geometries. We generate the arrays using a spatial light modulator, with which we imprint an appropriate phase pattern on an optical dipole-trap beam prior to focusing.We trap single ⁸⁷Rb atoms in the sites of arrays containing up to approximately 100 microtraps separated by distances as small as 3 μm, with complex structures such as triangular, honeycomb, or kagome lattices. Using a closed-loop optimization of the uniformity of the trap depths ensures that all trapping sites are equivalent. This versatile system opens appealing applications in quantum-information processing and quantum simulation, e.g., for simulating frustrated quantum magnetism using Rydberg atoms.Published by the American Physical Society.

Original language	English
Article number	021034
Journal	Physical Review X
Volume	4
Issue number	2
DOIs	https://doi.org/10.1103/PhysRevX.4.021034
Publication status	Published - 1 Jan 2014
Externally published	Yes

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title = "Single-atom trapping in holographic 2D arrays of microtraps with arbitrary geometries",

abstract = "We demonstrate single-atom trapping in two-dimensional arrays of microtraps with arbitrary geometries. We generate the arrays using a spatial light modulator, with which we imprint an appropriate phase pattern on an optical dipole-trap beam prior to focusing.We trap single 87Rb atoms in the sites of arrays containing up to approximately 100 microtraps separated by distances as small as 3 μm, with complex structures such as triangular, honeycomb, or kagome lattices. Using a closed-loop optimization of the uniformity of the trap depths ensures that all trapping sites are equivalent. This versatile system opens appealing applications in quantum-information processing and quantum simulation, e.g., for simulating frustrated quantum magnetism using Rydberg atoms.Published by the American Physical Society.",

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AU - Nogrette, F.

AU - Labuhn, H.

AU - Ravets, S.

AU - Barredo, D.

AU - Béguin, L.

AU - Vernier, A.

AU - Lahaye, T.

AU - Browaeys, A.

PY - 2014/1/1

Y1 - 2014/1/1

N2 - We demonstrate single-atom trapping in two-dimensional arrays of microtraps with arbitrary geometries. We generate the arrays using a spatial light modulator, with which we imprint an appropriate phase pattern on an optical dipole-trap beam prior to focusing.We trap single 87Rb atoms in the sites of arrays containing up to approximately 100 microtraps separated by distances as small as 3 μm, with complex structures such as triangular, honeycomb, or kagome lattices. Using a closed-loop optimization of the uniformity of the trap depths ensures that all trapping sites are equivalent. This versatile system opens appealing applications in quantum-information processing and quantum simulation, e.g., for simulating frustrated quantum magnetism using Rydberg atoms.Published by the American Physical Society.

AB - We demonstrate single-atom trapping in two-dimensional arrays of microtraps with arbitrary geometries. We generate the arrays using a spatial light modulator, with which we imprint an appropriate phase pattern on an optical dipole-trap beam prior to focusing.We trap single 87Rb atoms in the sites of arrays containing up to approximately 100 microtraps separated by distances as small as 3 μm, with complex structures such as triangular, honeycomb, or kagome lattices. Using a closed-loop optimization of the uniformity of the trap depths ensures that all trapping sites are equivalent. This versatile system opens appealing applications in quantum-information processing and quantum simulation, e.g., for simulating frustrated quantum magnetism using Rydberg atoms.Published by the American Physical Society.

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JO - Physical Review X

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Single-atom trapping in holographic 2D arrays of microtraps with arbitrary geometries

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