Microwave quantum logic gates for trapped ions

Ospelkaus, C.; Warring, U.; Colombe, Yves; Brown, Kenneth R.; Amini, Jason M.; Leibfried, D.; Wineland, D. J.

doi:10.1038/nature10290

Cited by 324 publications

(400 citation statements)

References 33 publications

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“…Jt, 33.80.Gj, 34.50.Lf, Crystals of laser-cooled atomic ions form the basis of many experimental realizations of quantum logic gates [1][2][3] and simulations of quantum many-body physics [4][5][6]. In room-temperature vacuum systems, collisions with neutral background gas molecules limit quantum coherences and quantum logic operations [7].…”

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confidence: 99%

Reversing hydride-ion formation in quantum-information experiments withBe+

et al. 2015

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We demonstrate photodissociation of BeH + ions within a Coulomb crystal of thousands of 9 Be + ions confined in a Penning trap. Because BeH + ions are created via exothermic reactions between trapped, laser-cooled Be + ( 2 P 3/2 ) and background H2 within the vacuum chamber, they represent a major contaminant species responsible for infidelities in large-scale trapped-ion quantum information experiments. The rotational-state-insensitive dissociation scheme described here makes use of 157 nm photons to produce Be + and H as products, thereby restoring Be + ions without the need for reloading. This technique facilitates longer experiment runtimes at a given background H2 pressure, and may be adapted for removal of MgH + and AlH + impurities.PACS numbers: 52.27. Jt, 33.80.Gj, 34.50.Lf, Crystals of laser-cooled atomic ions form the basis of many experimental realizations of quantum logic gates [1][2][3] and simulations of quantum many-body physics [4][5][6]. In room-temperature vacuum systems, collisions with neutral background gas molecules limit quantum coherences and quantum logic operations [7]. Here we focus on inelastic (i.e. reactive) collisions where exothermic chemical reactions with background gas molecules can generate, in both Penning and rf traps, co-trapped molecular ions over a wide range of trapping conditions and crystal geometries [6][7][8][9]. These contaminants alter ion-crystal eigenfrequencies and can complicate quantum logic interactions [10]. Impurities may be resonantly ejected from both radiofrequency and Penning traps, but this technique is least efficient when the impurities are similar in mass to the qubit ion [11]. The rate of impurity ion formation increases linearly with the number of ion qubits in the register, and the time required for loading new ions and recalibrating the register increases with the size of the system. Therefore, experimental techniques to prevent or reverse qubit-ion chemistry will be a key tool for many-ion quantum information platforms. [18]. Given the difficulty of detecting scattered photons from dilute molecular-ion samples, rotational-state-selective PD has emerged as a critical tool for molecular ion spectroscopy [15,19] and precision measurements [16,20], while rotationally-insensitive dissociation schemes provide valuable tests of molecular * Electronic address: brian.sawyer@boulder.nist.gov ) after 9000 pulses of 157 nm photodissociation light at 1.6 mJ/pulse. We measure an increase in the Be + fraction from 81% to 97% of the constant total ion number in the crystal. Each image is 1.2 mm × 1.2 mm.

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Reversing hydride-ion formation in quantum-information experiments withBe+

et al. 2015

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“…As the wavelength of the spin-flip transition for the (anti-)proton is rather long compared to the spatial extent of its motion, special measures need to be taken in order to be able to jointly (de-)excite motional and internal degrees of freedom of the particle. Similar protocols have been implemented with atomic ions in the context of quantum logic operations using microwave radiation [16,17] and have been adapted for the cylindrical Penning trap geometry of the present project.…”

Section: Trap Setupmentioning

confidence: 99%

Towards Quantum Logic Inspired Cooling and Detection for Single (Anti-)Protons

Meiners¹,

Niemann²,

Paschke³

et al. 2017

Proceedings of the 12th International Conference on Low Energy Antiproton Physics (LEAP2016)

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“…A promising tool for the control and manipulation of cold molecules is the molecule chip [12][13][14], the molecular analog of the atom chip [15][16][17][18] or ion chip [19,20]. Using the molecule chip, we have recently demonstrated the integrated on-chip time-resolved spatial imaging of cold molecules in a manner that is both quantum state selective and generally applicable [14].…”

Section: Introductionmentioning

confidence: 99%

Measuring and manipulating the temperature of cold molecules trapped on a chip

et al. 2015

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Following Marx et al. [Phys. Rev. Lett. 111, 243007 (2013)], we discuss the measurement and manipulation of the temperature of cold CO molecules in a microchip environment. In particular, we present a model to explain the observed and calculated velocity distributions. We also show that a translational temperature can be extracted directly from the measurements. Finally, we discuss the conditions needed for an effective adiabatic cooling of the molecular ensemble trapped on the microchip.

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Microwave quantum logic gates for trapped ions

Cited by 324 publications

References 33 publications

Reversing hydride-ion formation in quantum-information experiments withBe+

Reversing hydride-ion formation in quantum-information experiments withBe+

Towards Quantum Logic Inspired Cooling and Detection for Single (Anti-)Protons

Measuring and manipulating the temperature of cold molecules trapped on a chip

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