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    • Design Study for an Efficient Semiconductor Quantum Light Source Operating in the Telecom C-band Based on an Electrically-Driven Circular Bragg Grating.

    Andrea Barbiero,Jan Huwer, Joanna Skiba-Szymanska,Tina Muller,R. Mark Stevenson,Andrew J. Shields

    Optics Express(2022)

    Toshiba Europe Ltd

    Cited 22|Views22
    Abstract
    The development of efficient sources of single photons and entangled photon pairs emitting in the low-loss wavelength region around 1550 nm is crucial for long-distance quantum communication. Moreover, direct fiber coupling and electrical carrier injection are highly desirable for deployment in compact and user-friendly systems integrated with the existing fiber infrastructure. Here we present a detailed design study of circular Bragg gratings fabricated in InP slabs and operating in the telecom C-band. These devices enable the simultaneous enhancement of the X and XX spectral lines, with collection efficiency in numerical aperture 0.65 close to 90% for the wavelength range 1520 - 1580 nm and Purcell factor up to 15. We also investigate the coupling into a single mode fiber, which exceeds 70% in UHNA4. Finally, we propose a modified device design directly compatible with electrical carrier injection, reporting Purcell factors up to 20 and collection efficiency in numerical aperture 0.65 close to 70% for the whole telecom C-band.
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    要点】:本研究详细设计了在电信C波段工作的基于电驱动圆形布喇格光栅的高效半导体量子光源,其创新点在于同时增强X和XX光谱线,并具有较高的收集效率和 Purcell 因子。
    

    方法】:采用了在InP板材中制作的圆形布喇格光栅,通过优化设计实现对特定光谱线的增强。
    

    实验】:实验使用了UHNA4单模光纤耦合,并提出了改进的设备设计,兼容电荷注入,实现了整个电信C波段的高Purcell因子和收集效率。
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