Related papers: Proof-of-principle demonstration of temporally multiplexed quantum repeater link based on atomic ensemble

Proof-of-principle demonstration of temporally multiplexed quantum repeater link based on atomic ensemble

URL: http://arxiv.org/abs/2308.14587v1
Date: Mon, 28 Aug 2023 13:52:04 GMT
Title: Proof-of-principle demonstration of temporally multiplexed quantum repeater link based on atomic ensemble
Authors: Minjie Wang, Haole Jiao, Jiajin Lu, Wenxin Fan, Zhifang Yang, Mengqi Xi, Shujing Li, Hai Wang
Abstract summary: We demonstrate a proof-of-principle multiplexed quantum repeater link by entangling two temporally multiplexed quantum memory. Compared with a single-mode link, the successful preparation rate of the multiplexed link is increased by one order of magnitude. The realization of temporally multiplexed quantum repeater link with high retrieval efficiency lays a foundation for the development of practical quantum networks.
Score: 4.85157340214785
License: http://creativecommons.org/licenses/by/4.0/
Abstract: Duan-Lukin-Cirac-Zoller quantum repeater protocol provides a feasible scheme to implement long-distance quantum communication and large-scale quantum networks. The elementary link, namely the entanglement between two atomic ensembles, is a fundamental component of quantum repeater. For practical quantum repeater, it is required that the elementary link can be prepared with high yield and the spin waves stored in atoms can be efficiently converted into photons on demand. However, so far, such quantum repeater link has not been demonstrated in experiments. Here, we demonstrate a proof-of-principle multiplexed quantum repeater link by entangling two temporally multiplexed quantum memory. Compared with a single-mode link, the successful preparation rate of the multiplexed link is increased by one order of magnitude. By using the cavity-enhanced scheme, the on-demand retrieval efficiency of atomic spin waves is improved to 70%, which is beneficial for the subsequent entanglement swapping between adjacent links. The realization of temporally multiplexed quantum repeater link with high retrieval efficiency lays a foundation for the development of practical quantum networks.

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