Superconducting Nanostrip Photon-Number-Resolving Detector as an Unbiased Random Number Generator

IEEE Transactions on Quantum Engineering Pub Date : 2024-07-22 DOI:10.1109/TQE.2024.3432070

Pasquale Ercolano;Mikkel Ejrnaes;Ciro Bruscino;Syed Muhammad Junaid Bukhari;Daniela Salvoni;Chengjun Zhang;Jia Huang;Hao Li;Lixing You;Loredana Parlato;Giovanni Piero Pepe

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Abstract

Detectors capable of resolving the number of photons are essential in many applications, ranging from classic photonics to quantum optics and quantum communication. In particular, photon-number-resolving detectors based on arrays of superconducting nanostrips can offer a high detection efficiency, a low dark count rate, and a recovery time of a few nanoseconds. In this work, we use a detector of this kind for the unbiased generation of random numbers by following two different methods based on the detection of photons. In the former, we exploit the property that the light is equally distributed on each strip of the entire detector, whereas in the latter, we exploit the fact that, for a high average number of photons, the parity of the Poisson distribution of the number of photons emitted by the laser tends to be zero. In addition, since these two methods are independent, it is possible to use them at the same time.

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作为无偏随机数发生器的超导纳米带光子数字解析探测器

从传统光子学到量子光学和量子通信，能够分辨光子数量的探测器在许多应用中都是必不可少的。特别是基于超导纳米条阵列的光子数量分辨探测器，可以提供高探测效率、低暗计数率和几纳秒的恢复时间。在这项工作中，我们利用这种探测器，通过两种不同的光子探测方法，无偏地生成随机数。在前者中，我们利用了光在整个探测器的每个条带上平均分布的特性，而在后者中，我们利用了这样一个事实，即对于高平均光子数，激光发射的光子数的泊松分布的奇偶性趋向于零。此外，由于这两种方法是独立的，因此可以同时使用。

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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来源期刊

IEEE Transactions on Quantum Engineering

CiteScore

8.00

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0.00%

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