Controlling trapping potentials and stray electric fields in a microfabricated ion trap through design and compensation

Doret, S. Charles; Amini, Jason M.; Wright, Kenneth; Volin, Curtis; Killian, Tyler N.; Ozakin, Arkadas; Denison, Douglas R.; Hayden, Harley; Pai, C. S.; Slusher, R. E.; Harter, Alexa W.

doi:10.1088/1367-2630/14/7/073012

Cited by 67 publications

(38 citation statements)

References 35 publications

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“…This agrees well given the assumptions of the motional decoherence model. At our ion-surface distance (∼70 μm), this heating rate, which corresponds to a noise spectral density ωS ∼ 1.2 × 10 −3 V 2 /m 2 , is comparable to other surface-electrode traps at room temperature without surface cleaning and an order of magnitude worse than the best reported heating rates [11].…”

Section: A Stationary Heatingsupporting

confidence: 58%

“…For radial motion parallel to the trap surface, we measure micromotion using the rf photon correlation method [35] and by detecting resolved micromotion sidebands on the 397-nm transition [11,21]. For motion perpendicular to the trap surface, we measure the micromotion sidebands of the 4s 2 S 1/2 →3d 2 D 5/2 transition [21].…”

Section: Trap Operation and Compensationmentioning

confidence: 99%

“…This architecture requires an array of electrodes capable of trapping ions at arbitrary locations, shuttling ions through two-dimensional junctions, and merging and splitting ion chains. Surface-electrode ion traps [2][3][4][5][6][7][8][9][10][11][12] are well suited to all of these operations and precise microfabrication allows for complicated and scalable trap electrode geometries. These traps support higher secular frequencies than macroscopic traps and can be outfitted with additional features such as integrated near-side or on-chip optics [13][14][15][16] and microwave control lines [17][18][19].…”

Section: Introductionmentioning

confidence: 99%

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Heating rates and ion-motion control in aY-junction surface-electrode trap

et al. 2014

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We measure ion heating following transport throughout a Y-junction surface-electrode ion trap. By carefully selecting the trap voltage update rate during adiabatic transport along a trap arm, we observe minimal heating relative to the anomalous heating background. Transport through the junction results in an induced heating between 37 and 150 quanta in the axial direction per traverse. To reliably measure heating in this range, we compare the experimental sideband envelope, including up to fourth-order sidebands, to a theoretical model. The sideband envelope method allows us to cover the intermediate heating range inaccessible to the first-order sideband and Doppler recooling methods. We conclude that quantum information processing in this ion trap will likely require sympathetic cooling in order to support high fidelity gates after junction transport. measurements for a stationary ion, ion motion in the linear region, and ion motion through the junction. In Sec. V, we conclude with a discussion of trap robustness and potential future directions.

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Section: A Stationary Heatingsupporting

confidence: 58%

Section: Trap Operation and Compensationmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

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Heating rates and ion-motion control in aY-junction surface-electrode trap

et al. 2014

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“…In Fig. 5 summarize ω S E versus the closest ion-electrode distance, for a number of trap noise measurements reported in the literature [5,19,20,22,25,[38][39][40][41][42][43]. To compare between ion traps with different dimensions, one scales the noise with ion distance from the surface, d, as S E ∼ d −4 .…”

Section: Discussionmentioning

confidence: 99%

Surface noise analysis using a single-ion sensor

et al. 2014

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We use a single-ion electric-field noise sensor in combination with in situ surface treatment and analysis tools, to investigate the relationship between electric-field noise from metal surfaces in vacuum and the composition of the surface. These experiments are performed in a setup that integrates ion trapping capabilities with surface analysis tools. We find that treatment of an aluminum-copper surface with energetic argon ions significantly reduces the level of room-temperature electric-field noise, but the surface does not need to be atomically clean to show noise levels comparable to those of the best cryogenic traps. The noise levels after treatment are low enough to allow fault-tolerant trapped-ion quantum information processing on a microfabricated surface trap at room temperature.

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“…The trap conforms to a symmetric five-wire surface-electrode Paul trap geometry [23] fabricated on a 11 × 11 mm 2 silicon die (figure 1(a)) similar to the designs reported in [24][25][26]. Electrodes etched into three sputtered aluminum layers are separated by insulating silicon dioxide films.…”

Section: Trapping Structuresmentioning

confidence: 94%

Spatially uniform single-qubit gate operations with near-field microwaves and composite pulse compensation

et al. 2013

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We present a microfabricated surface-electrode ion trap with a pair of integrated waveguides that generate a standing microwave field resonant with the 171 Yb + hyperfine qubit. The waveguides are engineered to position the wave antinode near the center of the trap, resulting in maximum field amplitude and uniformity along the trap axis. By calibrating the relative amplitudes and phases of the waveguide currents, we can control the polarization of the microwave field to reduce off-resonant coupling to undesired Zeeman sublevels. We demonstrate single-qubit π -rotations as fast as 1 µs with less than 6% variation in Rabi frequency over an 800 µm microwave interaction region. Fully compensating pulse sequences further improve the uniformity of X -gates across this interaction region.

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Controlling trapping potentials and stray electric fields in a microfabricated ion trap through design and compensation

Cited by 67 publications

References 35 publications

Heating rates and ion-motion control in aY-junction surface-electrode trap

Heating rates and ion-motion control in aY-junction surface-electrode trap

Surface noise analysis using a single-ion sensor

Spatially uniform single-qubit gate operations with near-field microwaves and composite pulse compensation

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