Related papers: High-tolerance antiblockade SWAP gates using optimal pulse drivings

High-tolerance antiblockade SWAP gates using optimal pulse drivings

URL: http://arxiv.org/abs/2309.06013v2
Date: Wed, 13 Dec 2023 01:51:20 GMT
Title: High-tolerance antiblockade SWAP gates using optimal pulse drivings
Authors: Wan-Xia Li, Jin-Lei Wu, Shi-Lei Su, and Jing Qian
Abstract summary: We report progress towards a high-tolerance antiblockade-based Rydberg SWAP gate enabled by the use of it modified antiblockade condition combined with carefully-optimized laser pulses. Our work paves the way to the experimental demonstration of Rydberg antiblockade gates in the near future.
Score: 8.74727097776481
License: http://arxiv.org/licenses/nonexclusive-distrib/1.0/
Abstract: Position error is treated as the leading obstacle that prevents Rydberg antiblockade gates from being experimentally realizable, because of the inevitable fluctuations in the relative motion between two atoms invalidating the antiblockade condition. In this work we report progress towards a high-tolerance antiblockade-based Rydberg SWAP gate enabled by the use of {\it modified} antiblockade condition combined with carefully-optimized laser pulses. Depending on the optimization of diverse pulse shapes our protocol shows that the amount of time-spent in the double Rydberg state can be shortened by more than $70\%$ with respect to the case using {\it perfect} antiblockade condition, which significantly reduces this position error. Moreover, we benchmark the robustness of the gate via taking account of the technical noises, such as the Doppler dephasing due to atomic thermal motion, the fluctuations in laser intensity and laser phase and the intensity inhomogeneity. As compared to other existing antiblockade-gate schemes the predicted gate fidelity is able to maintain at above 0.91 after a very conservative estimation of various experimental imperfections, especially considered for realistic interaction deviation of $\delta V/V\approx 5.92\%$ at $T\sim20$ $\mu$K. Our work paves the way to the experimental demonstration of Rydberg antiblockade gates in the near future.

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