Polarization-entangled photon-pair source with van der Waals 3R-WS2 crystal

IF 27.2 Q1 OPTICS eLight Pub Date : 2024-08-23 DOI:10.1186/s43593-024-00074-6
Jiangang Feng, Yun-Kun Wu, Ruihuan Duan, Jun Wang, Weijin Chen, Jiazhang Qin, Zheng Liu, Guang-Can Guo, Xi-Feng Ren, Cheng-Wei Qiu
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Abstract

Ultracompact entangled photon sources are pivotal to miniaturized quantum photonic devices. Van der Waals (vdW) nonlinear crystals promise efficient photon-pair generation and on-chip monolithic integration with nanophotonic circuitry. However, it remains challenging to generate maximally entangled Bell states of photon pairs with high purity, generation rate, and fidelity required for practical applications. Here, we realize a polarization-entangled photon-pair source based on spontaneous parametric down conversion in an ultrathin rhombohedral tungsten disulfide (3R-WS2) crystal. This vdW entangled photonic source exhibits a high photon-pair purity with a coincidence-to-accidental ratio of above 800, a generation rate of 31 Hz, and two maximally polarization-entangled Bell states with fidelities exceeding 0.93 and entanglement degree over 0.97. These results stem from scalable optical nonlinearity, enhanced second-order susceptibility by electronic transitions, and a well-defined symmetry-enabled selection rule inherent in 3R-WS2. Our polarization entangled photon source can be integrated with photonic structures for generating more complex entangled states, thus paving an avenue for advanced quantum photonic systems toward computation and metrology.

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使用范德华 3R-WS2 晶体的偏振纠缠光子对源
超小型纠缠光子源是微型量子光子设备的关键。范德华(vdW)非线性晶体有望高效生成光子对,并与纳米光子电路实现片上单片集成。然而,要生成实际应用所需的高纯度、高生成率和高保真度的最大纠缠贝尔态光子对,仍然具有挑战性。在这里,我们在超薄斜方二硫化钨(3R-WS2)晶体中实现了基于自发参量向下转换的偏振纠缠光子对源。这种 vdW 纠缠光子源具有很高的光子对纯度,巧合与偶然之比高达 800 以上,生成率为 31 Hz,并且具有两个最大偏振纠缠贝尔态,保真度超过 0.93,纠缠度超过 0.97。这些结果源于可扩展的光学非线性、电子跃迁增强的二阶易感性以及 3R-WS2 固有的定义明确的对称选择规则。我们的偏振纠缠光子源可与光子结构集成,生成更复杂的纠缠态,从而为先进的量子光子系统铺平了一条通往计算和计量的道路。
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