Related papers: Comparing the performance of practical two-qubit gates for individual ${}^{171}$Yb ions in yttrium orthovanadate

Comparing the performance of practical two-qubit gates for individual ${}^{171}$Yb ions in yttrium orthovanadate

URL: http://arxiv.org/abs/2410.23613v1
Date: Thu, 31 Oct 2024 03:55:08 GMT
Title: Comparing the performance of practical two-qubit gates for individual ${}^{171}$Yb ions in yttrium orthovanadate
Authors: Mahsa Karimi, Faezeh Kimiaee Asadi, Stephen C. Wein, Christoph Simon,
Abstract summary: We investigate three schemes for implementing Controlled-NOT (CNOT) gates between individual ytterbium (Yb) rare-earth ions. We compute the gate fidelity of each scheme to evaluate the feasibility of their experimental implementation. We conclude that the probabilistic photon interference-based scheme offers the best fidelity scaling with cooperativity.
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Abstract: In this paper, we investigate three schemes for implementing Controlled-NOT (CNOT) gates between individual ytterbium (Yb) rare-earth ions doped into yttrium orthovanadate (YVO$_4$ or YVO). Specifically, we investigate the CNOT gates based on magnetic dipolar interactions between Yb ions, photon scattering off a cavity, and a photon interference-based protocol, with and without an optical cavity. We introduce a theoretical framework for precise computations of gate infidelity, accounting for noise effects. We then compute the gate fidelity of each scheme to evaluate the feasibility of their experimental implementation. Based on these results, we compare the performance of the gate schemes and discuss their respective advantages and disadvantages. We conclude that the probabilistic photon interference-based scheme offers the best fidelity scaling with cooperativity and is superior with the current technology of Yb values, while photon scattering is nearly deterministic but slower with less favourable fidelity scaling as a function of cooperativity. The cavityless magnetic dipolar scheme provides a fast, deterministic gate with high fidelity if close ion localization can be realized.

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