A new quantum key distribution protocol to reduce afterpulse and dark counts effects

Q3 Physics and Astronomy Results in Optics Pub Date : 2024-07-01 DOI:10.1016/j.rio.2024.100718

Mahdi Rahmanpour, Alireza Erfanian, Ahmad Afifi, Mahdi Khaje, Mohammad Hossein Fahimifar

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Abstract

The most important goal of quantum communication is to distribute the encryption key between the transmitter and the receiver. The optimal situation in Quantum Key Distribution (QKD) between transmitter and receiver is to increase the key distribution rate per second, increase the transmission distance, and reduce the error in key distribution. Several protocols used for QKD. The most important of QKD protocols is the BB84. One of the challenges leading to errors in quantum protocols is generating error pulses in single-photon detectors. These pulses caused by the inherent effects of quantum devices. They can cause wrong detection in the receiver. Many measures have been taken in the design and construction of single-photon detectors to reduce this error pulses, but it is not possible to eliminate all of them. Afterpulse and dark counts are two types of unwanted pulses that occur with single-photon detectors. In this paper, a new QKD protocol is proposed. It is an upgrade of the BB84 protocol and can reduce the effects of unwanted pulses such as afterpulse and dark counts in QKD avalanche detectors.

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减少后脉冲和暗计数效应的新量子密钥分发协议

量子通信最重要的目标是在发射器和接收器之间分发加密密钥。发送器和接收器之间的量子密钥分发（QKD）的最佳情况是提高每秒的密钥分发率、增加传输距离并减少密钥分发中的误差。用于 QKD 的协议有多种。QKD 协议中最重要的是 BB84。量子协议中导致错误的挑战之一是在单光子探测器中产生错误脉冲。这些脉冲由量子设备的固有效应引起。它们会导致接收器的错误检测。在设计和制造单光子探测器时，我们采取了许多措施来减少这种误差脉冲，但不可能消除所有误差脉冲。后脉冲和暗计数是单光子探测器出现的两类无用脉冲。本文提出了一种新的 QKD 协议。它是 BB84 协议的升级版，可以减少 QKD 雪崩探测器中余脉和暗计数等无用脉冲的影响。

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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