Provable Optimality of the Square-Tooth Atomic Frequency Comb Quantum Memory

• URL: http://arxiv.org/abs/2406.01769v2
• Date: Sat, 05 Oct 2024 23:20:28 GMT
• Title: Provable Optimality of the Square-Tooth Atomic Frequency Comb Quantum Memory
• Authors: Allen Zang, Martin Suchara, Tian Zhong,
• Abstract summary: Atomic frequency comb (AFC) quantum memories are a promising technology for quantum repeater networks. We show that the optimized square-tooth AFC provides the highest retrieval efficiency among all possible comb tooth shapes. Our proof provides experimentalists with rigorous arguments how to create optimal AFC under realistic experimental conditions.
• Score: 1.0869257688521987
• License:
• Abstract: Atomic frequency comb (AFC) quantum memories are a promising technology for quantum repeater networks because they enable multi-mode, high-fidelity storage of photons with on-demand retrieval. The optimization of the retrieval efficiency of an AFC memory is important because it strongly impacts the entanglement generation rate in quantum networks. Despite initial theoretical analyses and recent experimental demonstrations, a rigorous proof of the universally optimal configuration for the highest AFC retrieval efficiency has not been presented. In this paper we offer a simple analytical proof which shows that the optimized square-tooth AFC provides the highest retrieval efficiency among all possible comb tooth shapes, under the physical constraint of maximal optical depth of an atomic ensemble. The optimality still holds even when the non-zero background absorption and the finite optical linewidth of atoms are considered. Our proof provides experimentalists with rigorous arguments how to create optimal AFC under realistic experimental conditions. Finally, we also identify other functional optimization problems where our proof technique is applicable, thus proving the optimality of the square function in more general scenarios.

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