Versatile laser-free trapped-ion entangling gates

R T Sutherland; R Srinivas; S C Burd; D Leibfried; A C Wilson; D J Wineland; D T C Allcock; D H Slichter; S B Libby

doi:10.1088/1367-2630/ab0be5

Versatile laser-free trapped-ion entangling gates

New J Phys. 2019:21:10.1088/1367-2630/ab0be5. doi: 10.1088/1367-2630/ab0be5.

Authors

R T Sutherland¹, R Srinivas^{2

3}, S C Burd^{2

3}, D Leibfried², A C Wilson², D J Wineland^{2

3

4}, D T C Allcock^{2

3

4}, D H Slichter², S B Libby¹

Affiliations

¹ Physics Division, Physical and Life Sciences, Lawrence Livermore National Laboratory, Livermore, CA 94550, United States of America.
² Time and Frequency Division, National Institute of Standards and Technology, Boulder, CO 80305, United States of America.
³ Department of Physics, University of Colorado, Boulder, CO 80309, United States of America.
⁴ Department of Physics, University of Oregon, Eugene, OR 97403, United States of America.

Abstract

We present a general theory for laser-free entangling gates with trapped-ion hyperfine qubits, using either static or oscillating magnetic-field gradients combined with a pair of uniform microwave fields symmetrically detuned about the qubit frequency. By transforming into a 'bichromatic' interaction picture, we show that either ${\hat{σ}}_{ϕ} \otimes {\hat{σ}}_{ϕ}$ or ${\hat{σ}}_{z} \otimes {\hat{σ}}_{z}$ geometric phase gates can be performed. The gate basis is determined by selecting the microwave detuning. The driving parameters can be tuned to provide intrinsic dynamical decoupling from qubit frequency fluctuations. The ${\hat{σ}}_{z} \otimes {\hat{σ}}_{z}$ gates can be implemented in a novel manner which eases experimental constraints. We present numerical simulations of gate fidelities assuming realistic parameters.

Keywords: atomic physics; geometric phase gates; quantum computing; quantum gates; quantum logic; quantum physics; trapped-ions.

Grants and funding

9999-NIST/Intramural NIST DOC/United States