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Paper detail

Quantum key distribution with dissipative Kerr soliton generated by on-chip microresonators

Quantum key distribution (QKD) can distribute symmetric key bits between remote legitimate users with the guarantee of quantum mechanics principles. For practical applications, the compact and robust photonic components for QKD are essential, and there are increasing attention to integrate the source, detector and modulators on a photonic chip. However, the massive and parallel QKD based on wavelength multiplexing are still challenge, due to the limited coherent light sources on the chip. Here, we introduce the Kerr dissipative soliton in a microresonator, which provides the locked coherent frequency comb with 49GHz frequency spacing, for QKD. We demonstrate the parallel QKD by demulplexing the coherent comb lines form the soliton, and showing the potential of Gbps secret key rate if the hundreds of channels covering C and L bands are fully exploited. The demonstrated soliton based QKD architecture are compatible with the efforts of quantum photonic integrated circuits, which are compact, robust and low-cost, and provides a competitive platform of practical QKD chip.

preprint2020arXivOpen access
Fang-Xiang WangWeiqiang WangRui NiuXinyu WangChang-Ling ZouChun-Hua DongBrent E. LittleSai T. ChuHang LiuPenglei HaoShufeng LiuShuang WangZhen-Qiang YinDe-Yong HeWenfu ZhangWei ZhaoZheng-Fu HanGuang-Can GuoWei Chen
quant-ph
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Fang-Xiang WangWeiqiang WangRui NiuXinyu WangChang-Ling ZouChun-Hua DongBrent E. LittleSai T. ChuHang LiuPenglei HaoShufeng LiuShuang WangZhen-Qiang YinDe-Yong HeWenfu ZhangWei ZhaoZheng-Fu HanGuang-Can GuoWei Chen

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