End-to-End Entanglement Generation Strategies: Capacity Bounds and Impact on Quantum Key Distribution

Q2 Physics and Astronomy Quantum Reports Pub Date : 2022-07-29 DOI:10.3390/quantum4030017
A. Manzalini, M. Amoretti
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引用次数: 6

Abstract

A first quantum revolution has already brought quantum technologies into our everyday life for decades: in fact, electronics and optics are based on the quantum mechanical principles. Today, a second quantum revolution is underway, leveraging the quantum principles of superposition, entanglement and measurement, which were not fully exploited yet. International innovation activities and standardization bodies have identified four main application areas for quantum technologies and services: quantum secure communications, quantum computing, quantum simulation, and quantum sensing and metrology. This paper focuses on quantum secure communications by addressing the evolution of Quantum Key Distribution (QKD) networks (under early exploitation today) towards the Quantum-ready networks and the Quantum Internet based also on entanglement distribution. Assuming that management and control of quantum nodes is a key challenge under definition, today, a main obstacle in exploiting long-range QKD and Quantum-ready networks concerns the inherent losses due to the optical transmission channels. Currently, it is assumed that a most promising way for overcoming this limitation, while avoiding the presence of costly trusted nodes, it is to distribute entangled states by means of Quantum Repeaters. In this respect, the paper provides an overview of current methods and systems for end-to-end entanglement generation, with some simulations and a discussion of capacity upper bounds and their impact of secret key rate in QKD systems.
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端到端纠缠生成策略:容量边界及其对量子密钥分发的影响
几十年来,第一场量子革命已经将量子技术带入了我们的日常生活:事实上,电子和光学都是基于量子力学原理的。今天,第二次量子革命正在进行,利用了叠加、纠缠和测量的量子原理,这些原理尚未得到充分利用。国际创新活动和标准化机构已经确定了量子技术和服务的四个主要应用领域:量子安全通信、量子计算、量子模拟以及量子传感和计量。本文通过讨论量子密钥分发(QKD)网络(目前处于早期开发阶段)向量子就绪网络和同样基于纠缠分发的量子互联网的演变,重点关注量子安全通信。假设量子节点的管理和控制是定义中的一个关键挑战,那么今天,开发远程QKD和量子就绪网络的一个主要障碍是由于光传输信道造成的固有损耗。目前,人们认为,克服这一限制的最有前途的方法是通过量子中继器来分布纠缠态,同时避免昂贵的可信节点的存在。在这方面,本文概述了当前端到端纠缠生成的方法和系统,并对QKD系统中的容量上限及其对密钥速率的影响进行了一些模拟和讨论。
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
Quantum Reports
Quantum Reports Physics and Astronomy-Physics and Astronomy (miscellaneous)
CiteScore
3.30
自引率
0.00%
发文量
33
审稿时长
10 weeks
期刊最新文献
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