High-performance photon number resolving detectors for 850–950 nm wavelength range

APL Photonics Pub Date : 2024-06-01 DOI:10.1063/5.0204340
J. W. N. Los, Mariia Sidorova, Bruno Lopez-Rodriguez, Patrick Qualm, Jin Chang, S. Steinhauer, V. Zwiller, I. Zadeh
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引用次数: 1

Abstract

Since their first demonstration in 2001 [Gol’tsman et al., Appl. Phys. Lett. 79, 705–707 (2001)], superconducting-nanowire single-photon detectors (SNSPDs) have witnessed two decades of great developments. SNSPDs are the detector of choice in most modern quantum optics experiments and are slowly finding their way into other photon-starved fields of optics. Until now, however, in nearly all experiments, SNSPDs were used as “binary” detectors, meaning that they could only distinguish between 0 and >=1 photons, and photon number information was lost. Recent research has demonstrated proof-of-principle photon-number resolution (PNR) SNSPDs counting 2–5 photons. The photon-number-resolving capability is highly demanded in various quantum-optics experiments, including Hong–Ou–Mandel interference, photonic quantum computing, quantum communication, and non-Gaussian quantum state preparation. In particular, PNR detectors at the wavelength range of 850–950 nm are of great interest due to the availability of high-quality semiconductor quantum dots (QDs) [Heindel et al., Adv. Opt. Photonics 15, 613–738 (2023)] and high-performance cesium-based quantum memories [Ma et al., J. Opt. 19, 043001 (2017)]. In this paper, we demonstrate NbTiN-based SNSPDs with >94% system detection efficiency, sub-11 ps timing jitter for one photon, and sub-7 ps for 2 photons. More importantly, our detectors resolve up to 7 photons using conventional cryogenic electric readout circuitry. Through theoretical analysis, we show that the PNR performance of demonstrated detectors can be further improved by enhancing the signal-to-noise ratio and bandwidth of our readout circuitry. Our results are promising for the future of optical quantum computing and quantum communication.
用于 850-950 纳米波长范围的高性能光子数分辨探测器
超导纳米线单光子探测器(SNSPD)自 2001 年首次展示以来[Gol'tsman 等人,Appl. Phys. Lett.超导纳米线单光子探测器是大多数现代量子光学实验的首选探测器,并正在慢慢进入其他光子匮乏的光学领域。然而,到目前为止,在几乎所有实验中,SNSPD 都是作为 "二进制 "探测器使用的,这意味着它们只能区分 0 和 >=1 的光子,光子数信息会丢失。最近的研究表明,原理验证型光子数分辨(PNR)SNSPD 可对 2-5 光子进行计数。各种量子光学实验,包括虹欧-曼德尔干涉、光子量子计算、量子通信和非高斯量子态制备,都对光子数分辨能力有很高的要求。由于高质量半导体量子点(QDs)[Heindel 等,Adv. Opt. Photonics 15, 613-738 (2023)]和高性能铯基量子存储器[Ma 等,J. Opt. 19, 043001 (2017)]的可用性,波长范围在 850-950 nm 的 PNR 探测器尤其备受关注。在本文中,我们展示了基于 NbTiN 的 SNSPD,其系统探测效率大于 94%,一个光子的定时抖动小于 11 ps,两个光子的定时抖动小于 7 ps。更重要的是,我们的探测器可以使用传统的低温电读出电路分辨多达 7 个光子。我们通过理论分析表明,通过提高读出电路的信噪比和带宽,可以进一步改善所展示探测器的 PNR 性能。我们的成果为未来的光量子计算和量子通信带来了希望。
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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