Proposal for practical Rydberg quantum gates using a native two-photon excitation

Rydberg quantum gate serving as an indispensable computing unit for neutral-atom quantum computation, has attracted intense research efforts for the last decade. However, the state-of-the-art experiments have not reached the high gate fidelity as predicted by most theories due to the unexpected large loss remaining in Rydberg and intermediate states. In this paper, we report our findings in constructing a native two-qubit controlled-NOT gate based on pulse optimization. We focus on the method of commonly-used two-photon Rydberg excitation with smooth Gaussian-shaped pulses which is straightforward for experimental demonstration. By utilizing optimized pulse shapes the scheme reveals a remarkable reduction in the decays from Rydberg and intermediate states, as well as a high-tolerance to the residual thermal motion of atoms. We extract a conservative lower bound for the gate fidelity >0.9921 after taking into account the experimental imperfections. Our results not only reduce the gap between experimental and theoretical prediction because of the optimal control, but also facilitate the connectivity of distant atomic qubits in a larger atom array by reducing the requirement of strong blockade, which is promising for developing multiqubit quantum computation in large-scale atomic arrays.

Automated summary

In this paper, we report our findings on constructing a native two-qubit controlled-NOT gate based on pulse optimization. The scheme utilizes optimized pulse shapes to reduce decays and tolerate residual thermal motion of atoms. The gate fidelity is estimated to be >0.9921, considering experimental imperfections. These results bridge the gap between experimental and theoretical predictions and facilitate the development of multiqubit quantum computation in large-scale atomic arrays by reducing the requirement of strong blockade.