2007
DOI: 10.1038/nphys698
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Two-dimensional transport and transfer of a single atomic qubit in optical tweezers

Abstract: Quantum computers have the capability of out-performing their classical counterparts for certain computational problems 1 . Several scalable quantum-computing architectures have been proposed. An attractive architecture is a large set of physically independent qubits arranged in three spatial regions where (1) the initialized qubits are stored in a register, (2) two qubits are brought together to realize a gate and (3) the readout of the qubits is carried out 2,3 . For a neutral-atom-based architecture, a natu… Show more

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Cited by 156 publications
(129 citation statements)
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“…Using optical tweezers, long-range interactions between neutral atoms have been harnessed via Rydberg blockade [3-5], and it is now possible to observe controlled interactions and interference between bosonic and fermionic atoms placed individually in their motional ground state [6][7][8]. While optical tweezer traps can be scaled to arrays [9][10][11][12], realizing an ordered array with a single atom per trap is difficult and is a problem of long-standing interest [13][14][15][16].…”
mentioning
confidence: 99%
See 1 more Smart Citation
“…Using optical tweezers, long-range interactions between neutral atoms have been harnessed via Rydberg blockade [3-5], and it is now possible to observe controlled interactions and interference between bosonic and fermionic atoms placed individually in their motional ground state [6][7][8]. While optical tweezer traps can be scaled to arrays [9][10][11][12], realizing an ordered array with a single atom per trap is difficult and is a problem of long-standing interest [13][14][15][16].…”
mentioning
confidence: 99%
“…Using optical tweezers, long-range interactions between neutral atoms have been harnessed via Rydberg blockade [3-5], and it is now possible to observe controlled interactions and interference between bosonic and fermionic atoms placed individually in their motional ground state [6][7][8]. While optical tweezer traps can be scaled to arrays [9][10][11][12], realizing an ordered array with a single atom per trap is difficult and is a problem of long-standing interest [13][14][15][16].Early experiments with optical tweezers demonstrated sub-Poissonian atom-number statistics using light-assisted collisions that rapidly expel pairs of atoms, a process known as collisional blockade [17][18][19][20]. This has become a reliable method to isolate single atoms, as well as the basis for parity imaging in quantum-gas microscopes [1,2,17].…”
mentioning
confidence: 99%
“…where Ω is the oscillation frequency of the atom, the mass is m, and the extension of the ground state wave function is σ [31,32]. For our experimental parameters, kHz rotation rate of atoms could be obtained with this method.…”
Section: Rotating the Single Atomsmentioning
confidence: 99%
“…We assume that we can adiabatically shift the two state-dependent potentials which confine the register atoms by 2.5 μm, as this can be efficiently done with no significant heating or atom losses, while preserving the qubit state with a high fidelity, as shown in Refs. [19] and [21]. This enables splitting of the atom wave function vertically by a distance δz, and a δφ = mgδzt/ phase difference is induced by letting the probe evolve for a time t.…”
Section: A Gravity Measurementsmentioning
confidence: 99%