在集成式碳化硅平台中产生纠缠光子对

IF 20.6 Q1 OPTICS Light-Science & Applications Pub Date : 2024-05-09 DOI:10.1038/s41377-024-01443-z
Anouar Rahmouni, Ruixuan Wang, Jingwei Li, Xiao Tang, Thomas Gerrits, Oliver Slattery, Qing Li, Lijun Ma
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引用次数: 0

摘要

纠缠在量子信息处理中起着至关重要的作用。由于其独特的材料特性,碳化硅最近成为了可扩展地实现先进量子信息处理能力的理想候选材料。然而,迄今为止,在碳化硅中只报道了核自旋的纠缠,而纠缠光子源,无论是基于块体还是芯片级技术,都仍然遥不可及。在这里,我们首次报告了在集成碳化硅平台中展示纠缠光子源的情况。具体来说,通过在 4H 碳化硅-绝缘体平台的紧凑型微波谐振器中实施自发四波混合,在电信 C 波段有效地产生了强相关光子对。在泵浦功率为 0.17 mW 时,最大巧合-偶然比超过 600,对应的光对生成率为 (9 ± 1) × 103 对/秒。能量-时间纠缠的产生并验证了这种信号-闲置光子对,双光子干涉条纹的可见度大于 99%。此外,还测量了预示单光子特性,预示 g(2)(0) 为 10-3 量级,这表明 SiC 平台有望成为用于量子应用的全集成互补金属氧化物半导体兼容单光子源。
本文章由计算机程序翻译,如有差异,请以英文原文为准。

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Entangled photon pair generation in an integrated SiC platform

Entanglement plays a vital role in quantum information processing. Owing to its unique material properties, silicon carbide recently emerged as a promising candidate for the scalable implementation of advanced quantum information processing capabilities. To date, however, only entanglement of nuclear spins has been reported in silicon carbide, while an entangled photon source, whether it is based on bulk or chip-scale technologies, has remained elusive. Here, we report the demonstration of an entangled photon source in an integrated silicon carbide platform for the first time. Specifically, strongly correlated photon pairs are efficiently generated at the telecom C-band wavelength through implementing spontaneous four-wave mixing in a compact microring resonator in the 4H-silicon-carbide-on-insulator platform. The maximum coincidence-to-accidental ratio exceeds 600 at a pump power of 0.17 mW, corresponding to a pair generation rate of (9 ± 1) × 103 pairs/s. Energy-time entanglement is created and verified for such signal-idler photon pairs, with the two-photon interference fringes exhibiting a visibility larger than 99%. The heralded single-photon properties are also measured, with the heralded g(2)(0) on the order of 10−3, demonstrating the SiC platform as a prospective fully integrated, complementary metal-oxide-semiconductor compatible single-photon source for quantum applications.

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来源期刊
Light-Science & Applications
Light-Science & Applications 数理科学, 物理学I, 光学, 凝聚态物性 II :电子结构、电学、磁学和光学性质, 无机非金属材料, 无机非金属类光电信息与功能材料, 工程与材料, 信息科学, 光学和光电子学, 光学和光电子材料, 非线性光学与量子光学
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803
审稿时长
2.1 months
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