Experimental demonstration of a robust, high-fidelity geometric two ion-qubit phase gate

Leibfried, D.; DeMarco, Brian; Meyer, V.; Lucas, David M.; Barrett, M. D.; Britton, J.; Itano, Wayne M.; Jelenković, Branislav; Langer, C.; Rosenband, T.; Wineland, David J.

doi:10.1038/nature01492

Cited by 1,071 publications

(1,141 citation statements)

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“…Starting with two-qubit gate operations [2,3], long lived two-qubit entanglement [4,5,6], teleportation experiments [7,8], and different sorts of multi-qubit entangled states [9,10,4,11], the record for qubit-entanglement is currently presented in a 6-qubit cat state and a 8-qubit W-state [12,13]. Future improvement is expected using the technique of segmented linear Paul traps which allow to shuttle ions from a "processor" unit to a "memory" section [14].…”

Section: Introductionmentioning

confidence: 99%

Optimization of segmented linear Paul traps and transport of stored particles

Schulz

Poschinger

Singer³

et al. 2006

Fortschritte der Physik

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Single ions held in linear Paul traps are promising candidates for a future quantum computer. Here, we discuss a two-layer microstructured segmented linear ion trap. The radial and axial potentials are obtained from numeric field simulations and the geometry of the trap is optimized. As the trap electrodes are segmented in the axial direction, the trap allows the transport of ions between different spatial regions. Starting with realistic numerically obtained axial potentials, we optimize the transport of an ion such that the motional degrees of freedom are not excited, even though the transport speed far exceeds the adiabatic regime. In our optimization we achieve a transport within roughly two oscillation periods in the axial trap potential compared to typical adiabatic transports that take of the order 10 2 oscillations. Furthermore heating due to quantum mechanical effects is estimated and suppression strategies are proposed.

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Section: Introductionmentioning

confidence: 99%

Optimization of segmented linear Paul traps and transport of stored particles

Schulz

Poschinger

Singer³

et al. 2006

Fortschritte der Physik

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“…We have numerically obtained the characteristic function and the energy distribution for some particular values of the parameters for the general case, where the energy distribution function has four singularities, but in the small initial energy limit their number reduces to two, indeed. The results obtained can be useful in the context of geometric ion trap quantum computations [2,3] where the particular implementation of the investigated model of the time-dependent harmonic oscillator with external forcing plays the crucial role. More details can be found in [7,18].…”

Section: Discussionmentioning

confidence: 92%

“…The particular implementation of the quantized time-dependent harmonic oscillator with the external forcing is the key model exploited in geometrical ion trap quantum computations [2,3].…”

Section: Introductionmentioning

confidence: 99%

Energy evolution in the time-dependent harmonic oscillator with arbitrary external forcing

Kuzminav

Robnik

2007

Reports on Mathematical Physics

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Abstract. The classical Hamiltonian system of time-dependent harmonic oscillator driven by the arbitrary external time-dependent force is considered. Exact analytical solution of the corresponding equations of motion is constructed in the framework of the technique (Robnik M, Romanovski V G, J. Phys. A: Math. Gen. 33 (2000) 5093) based on WKB approach. Energy evolution for the ensemble of uniformly distributed w.r.t. the canonical angle initial conditions on the initial invariant torus is studied. Exact expressions for the energy moments of arbitrary order taken at arbitrary time moment are analytically derived. Corresponding characteristic function is analytically constructed in the form of infinite series and numerically evaluated for certain values of the system parameters. Energy distribution function is numerically obtained in some particular cases. In the limit of small initial ensemble's energy the relevant formula for the energy distribution function is analytically derived.

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“…Numerous advances have been achieved in this system, including realization of faithful quantum gates [1][2][3][4][5][6][7], preparation of many-body quantum states [8][9][10][11][12][13][14][15], and quantum teleportation [16,17]. There are also developments to scale up this system, based on either ion shuttling [18][19][20] or quantum networks [21][22][23][24][25][26]).…”

Section: Introductionmentioning

confidence: 99%

Sympathetic cooling in a large ion crystal

Lin

Duan

2015

Quantum Inf Process

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We analyze the dynamics and steady state of a linear ion array when some of the ions are continuously laser cooled. We calculate the ions' local temperature measured by its position fluctuation under various trapping and cooling configurations, taking into account background heating due to the noisy environment. For a large system, we demonstrate that by arranging the cooling ions evenly in the array, one can suppress the overall heating considerably. We also investigate the effect of different cooling rates and find that the optimal cooling efficiency is achieved by an intermediate cooling rate. We discuss the relaxation time for the ions to approach the steady state, and show that with periodic arrangement of the cooling ions, the cooling efficiency does not scale down with the system size.

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Experimental demonstration of a robust, high-fidelity geometric two ion-qubit phase gate

Cited by 1,071 publications

References 20 publications

Optimization of segmented linear Paul traps and transport of stored particles

Optimization of segmented linear Paul traps and transport of stored particles

Energy evolution in the time-dependent harmonic oscillator with arbitrary external forcing

Sympathetic cooling in a large ion crystal

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