Triangular quantum photonic devices with integrated detectors in silicon carbide

Materials for Quantum Technology Pub Date : 2022-08-10 DOI:10.1088/2633-4356/acc302

S. Majety, S. Strohauer, Pranta Saha, F. Wietschorke, J. Finley, K. Mueller, M. Radulaski

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引用次数: 6

Abstract

Triangular cross-section SiC photonic devices have been studied as an efficient and scalable route for integration of color centers into quantum hardware. In this work, we explore efficient collection and detection of color center emission in a triangular cross-section SiC waveguide by introducing a photonic crystal mirror on its one side and a superconducting nanowire single photon detector (SNSPD) on the other. Our modeled triangular cross-section devices with a randomly positioned emitter have a maximum coupling efficiency of 89 % into the desired optical mode and a high coupling efficiency (> 75 %) in more than half of the configurations. For the first time, NbTiN thin films were sputtered on 4H-SiC and the electrical and optical properties of the thin films were measured. We found that the transport properties are similar to the case of NbTiN on SiO2 substrates, while the extinction coefficient is up to 50 % higher for 1680 nm wavelength. Finally, we performed Finite-Difference Time-Domain simulations of triangular cross-section waveguide integrated with an SNSPD to identify optimal nanowire geometries for efficient detection of light from TE and TM polarized modes.

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碳化硅中集成探测器的三角形量子光子器件

三角形截面碳化硅光子器件作为一种有效的、可扩展的将色心集成到量子硬件中的途径被研究。在这项工作中，我们通过在三角形截面SiC波导的一侧引入光子晶体反射镜和在另一侧引入超导纳米线单光子探测器(SNSPD)，探索了在三角形截面SiC波导中有效收集和检测色心发射的方法。我们的模型三角形截面器件具有随机定位的发射器，在期望的光学模式中具有89%的最大耦合效率，并且在超过一半的配置中具有高耦合效率(> 75%)。首次在4H-SiC上溅射NbTiN薄膜，并测量了薄膜的电学和光学性能。结果表明，NbTiN在SiO2衬底上的输运性质与NbTiN相似，但在1680nm波长下的消光系数提高了50%。最后，我们对集成了SNSPD的三角形截面波导进行了时域有限差分模拟，以确定有效检测TE和TM偏振模式光的最佳纳米线几何形状。

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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Materials for Quantum Technology

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