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With the rapid development of quantum information technology, fully connected multi-user quantum entanglement distribution networks have received increasing attention. Among these, multi-wavelength quantum light sources are key devices for establishing connections between multiple users. Despite recent impressive advances, there are still challenges in increasing the wavelength number of photon pairs due to limitations in the design and fabrication of nonlinear optical devices. The potentials of silicon nitride (Si3N4) microring resonators (MRRs), as scalable platforms for multi-wavelength quantum light sources, are explored in this work. The key design parameters of the Si3N4 MRRs, including waveguide dimension, resonator dispersion, and coupling condition, are comprehensively analyzed to optimize photon-pair generation. Based on these parameters, a Si3N4 MRR with a free spectral range of 20 GHz and an average quality factor of 1.6 million is designed and fabricated. This small free spectral range can generate more channels of correlated photon pairs by using the same wavelength resources. The high-quality resonator contributes to the enhancement of the rate of generating high photon pairs , which are critical for quantum entanglement distribution. With a continuous-wave pump laser, correlated photon pairs across a wide spectral range are generated through the spontaneous four-wave mixing (SFWM). The coincidence-to-accidental ratio (CAR) measurements verify the strong quantum correlation between photon pairs, highlighting the reliability of the system for entanglement distribution. Furthermore, the generation and output characteristics of quantum-correlated photon pairs are experimentally investigated with a tunable bandpass filter. The results demonstrate that 71 wavelength-correlated photon pairs within a 25.6 nm spectral range are successively generated as shown in the Fig. A. Our results pave the way for developing the multi-wavelength quantum light sources with Si3N4 platform, thereby advancing the multi-user quantum networks. -
Keywords:
- microring resonator /
- quantum light source /
- quantum correlation /
- quantum entanglement key
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图 1 氮化硅微环器件 (a) 理论设计的氮化硅波导的截面尺寸; (b) 氮化硅微环器件的显微图片; (c) 尾纤耦合和温控封装后的器件实物图
Figure 1. Si3N4 microring device: (a) Designed cross-sectional dimensions of the Si3N4 waveguide; (b) image of the Si3N4 microring device; (c) picture of the Si3N4 device after fiber pigtail coupling and temperature control packaging.
图 5 自发四波混频过程[18] (a) 三阶非线性光学材料中的自发四波混频过程; (b) 能量守恒条件; (c) 动量守恒条件
Figure 5. Spontaneous four-wave mixing process: (a) Spontaneous four-wave mixing process in the third order nonlinear optical materials; (b) energy conservation condition; (c) momentum conservation condition.
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