Warring, U.
, Ospelkaus, C.
, Colombe, Y.
, Brown, K.
, Amini, J.
, Carsjens, M.
, Leibfried, D.
and Wineland, D.
(2013),
Techniques for microwave near-field quantum control of trapped ions, Physical Review A, [online], https://tsapps.nist.gov/publication/get_pdf.cfm?pub_id=912579
(Accessed December 26, 2024)
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Techniques for microwave near-field quantum control of trapped ions
Published
Author(s)
, C. Ospelkaus, , , , M Carsjens, ,
Abstract
In Ospelkaus et al. [Nature 476, 181 (2011)] a microwave near-field quantum control of spin and motional degrees of freedom of one and two 25Mg+ ions enabled two-ion entanglement. In this report, we extend on the description of the experimental setup and calibration procedures for preparing these experiments. In particular, we discuss the design and characteristics of the surface-electrode trap and the microwave system that enabled the near-field control. We compare experimental findings of the microwave near-fields with numerical simulations. Moreover, we present a method utilizing oscillating-field gradients to compensate micromotion induced by the ponderomotive radio frequency potential in (linear) surface-electrode traps. Finally, we discuss the current limitations of the microwave-driven two-ion entangling gates.Citation
Physical Review A
Volume
87
Pub Type
Journals
Download Paper
Keywords
ion cooling, ion trapping, mechanical effects of light on ions, quantum computation architectures and implementations, zeeman and Stark effects
Citation
Issues
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Created January 31, 2013, Updated February 19, 2017