聚合物亚微柱结构的单光子分裂

IF 4.2 Q2 QUANTUM SCIENCE & TECHNOLOGY AVS quantum science Pub Date : 2023-03-01 DOI:10.1116/5.0135915
Gia Long Ngo, J. Hermier, N. D. Lai
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引用次数: 2

摘要

光分路器是未来光量子计算机光芯片中最重要的互连器件之一。在这里,我们介绍了一种基于聚合物亚微柱的新型量子光子分裂器,它将胶体量子点(QD)产生的单光子信号分裂成多个输出,可以通过传统的共聚焦扫描光学系统轻松访问。使用低吸收波长的单连续波激光器,我们能够首先确定地将单光子发射器(SPE)放置在其中一个亚微柱中,然后表征制造结构的单光子引导效应。利用倏逝波耦合效应,亚微柱作为单模定向耦合器既引导激光激发又引导单光子发射,通过数值模拟对亚微柱的尺寸和位置进行了综合优化。通过一步制作,我们可以从原始SPE创建一个分布良好的“假想”SPE数组。我们的方法在基于固态量子发射体的集成器件中开辟了各种应用。
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Single-photon splitting by polymeric submicropillars structures
Optical splitters are one of the most important interconnects in the optical chips of future optical quantum computers. Here, we introduce novel quantum photonic splitters based on polymeric submicropillars that split the single-photon signal generated by a colloidal quantum dot (QD) into multiple outputs, which can be easily accessed through a conventional confocal scanning optical system. Using a single continuous-wave laser with a low absorption wavelength for both polymer material and QDs, we were able to first deterministically place a single-photon emitter (SPE) within one of the submicropillars and then characterize the single-photon guiding effect of the fabricated structures. The submicropillars, with their size and position which are comprehensively optimized by numerical simulations, act as single-mode directional coupler guiding both the laser excitation and the single-photon emission thanks to the evanescent wave coupling effect. With one-step fabrication, we can create a well-distributed array of “imaginary” SPEs from an original SPE. Our method opens various applications in integrated devices based on solid-state quantum emitters.
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CiteScore
9.90
自引率
0.00%
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