Three-Dimensional Trapping of Individual Rydberg Atoms in Ponderomotive Bottle Beam Traps

D. Barredo; V. Lienhard; P. Scholl; S. De Léséleuc; T. Boulier; A. Browaeys; T. Lahaye

doi:10.1103/PhysRevLett.124.023201

Three-Dimensional Trapping of Individual Rydberg Atoms in Ponderomotive Bottle Beam Traps

D. Barredo
, V. Lienhard
, P. Scholl
, S. De Léséleuc
, T. Boulier
, A. Browaeys
, T. Lahaye

Université Paris-Saclay

Résultats de recherche: Contribution à un journal › Article › Revue par des pairs

Résumé

We demonstrate three-dimensional trapping of individual Rydberg atoms in holographic optical bottle beam traps. Starting with cold, ground-state Rb87 atoms held in standard optical tweezers, we excite them to nS1/2, nP1/2, or nD3/2 Rydberg states and transfer them to a hollow trap at 850 nm. For principal quantum numbers 60≤n≤90, the measured trapping time coincides with the Rydberg state lifetime in a 300 K environment. We show that these traps are compatible with quantum information and simulation tasks by performing single qubit microwave Rabi flopping, as well as by measuring the interaction-induced, coherent spin-exchange dynamics between two trapped Rydberg atoms separated by 40 μm. These results will find applications in the realization of high-fidelity quantum simulations and quantum logic operations with Rydberg atoms.

langue originale	Anglais
Numéro d'article	023201
journal	Physical Review Letters
Volume	124
Numéro de publication	2
Les DOIs	https://doi.org/10.1103/PhysRevLett.124.023201
état	Publié - 16 janv. 2020
Modification externe	Oui

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10.1103/PhysRevLett.124.023201

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title = "Three-Dimensional Trapping of Individual Rydberg Atoms in Ponderomotive Bottle Beam Traps",

abstract = "We demonstrate three-dimensional trapping of individual Rydberg atoms in holographic optical bottle beam traps. Starting with cold, ground-state Rb87 atoms held in standard optical tweezers, we excite them to nS1/2, nP1/2, or nD3/2 Rydberg states and transfer them to a hollow trap at 850 nm. For principal quantum numbers 60≤n≤90, the measured trapping time coincides with the Rydberg state lifetime in a 300 K environment. We show that these traps are compatible with quantum information and simulation tasks by performing single qubit microwave Rabi flopping, as well as by measuring the interaction-induced, coherent spin-exchange dynamics between two trapped Rydberg atoms separated by 40 μm. These results will find applications in the realization of high-fidelity quantum simulations and quantum logic operations with Rydberg atoms.",

author = "D. Barredo and V. Lienhard and P. Scholl and \{De L{\'e}s{\'e}leuc\}, S. and T. Boulier and A. Browaeys and T. Lahaye",

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doi = "10.1103/PhysRevLett.124.023201",

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T1 - Three-Dimensional Trapping of Individual Rydberg Atoms in Ponderomotive Bottle Beam Traps

AU - Barredo, D.

AU - Lienhard, V.

AU - Scholl, P.

AU - De Léséleuc, S.

AU - Boulier, T.

AU - Browaeys, A.

AU - Lahaye, T.

PY - 2020/1/16

Y1 - 2020/1/16

N2 - We demonstrate three-dimensional trapping of individual Rydberg atoms in holographic optical bottle beam traps. Starting with cold, ground-state Rb87 atoms held in standard optical tweezers, we excite them to nS1/2, nP1/2, or nD3/2 Rydberg states and transfer them to a hollow trap at 850 nm. For principal quantum numbers 60≤n≤90, the measured trapping time coincides with the Rydberg state lifetime in a 300 K environment. We show that these traps are compatible with quantum information and simulation tasks by performing single qubit microwave Rabi flopping, as well as by measuring the interaction-induced, coherent spin-exchange dynamics between two trapped Rydberg atoms separated by 40 μm. These results will find applications in the realization of high-fidelity quantum simulations and quantum logic operations with Rydberg atoms.

AB - We demonstrate three-dimensional trapping of individual Rydberg atoms in holographic optical bottle beam traps. Starting with cold, ground-state Rb87 atoms held in standard optical tweezers, we excite them to nS1/2, nP1/2, or nD3/2 Rydberg states and transfer them to a hollow trap at 850 nm. For principal quantum numbers 60≤n≤90, the measured trapping time coincides with the Rydberg state lifetime in a 300 K environment. We show that these traps are compatible with quantum information and simulation tasks by performing single qubit microwave Rabi flopping, as well as by measuring the interaction-induced, coherent spin-exchange dynamics between two trapped Rydberg atoms separated by 40 μm. These results will find applications in the realization of high-fidelity quantum simulations and quantum logic operations with Rydberg atoms.

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Three-Dimensional Trapping of Individual Rydberg Atoms in Ponderomotive Bottle Beam Traps

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