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Main Authors: da Costa, Beatriz Lopes, Bolaños, Matías R., Chaves, Ricardo, Narduzzi, Claudio, Avesani, Marco, Marangon, Davide Giacomo, Stanco, Andrea, Vallone, Giuseppe, Villoresi, Paolo, Omar, Yasser
Format: Preprint
Published: 2025
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Online Access:https://arxiv.org/abs/2503.11767
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author da Costa, Beatriz Lopes
Bolaños, Matías R.
Chaves, Ricardo
Narduzzi, Claudio
Avesani, Marco
Marangon, Davide Giacomo
Stanco, Andrea
Vallone, Giuseppe
Villoresi, Paolo
Omar, Yasser
author_facet da Costa, Beatriz Lopes
Bolaños, Matías R.
Chaves, Ricardo
Narduzzi, Claudio
Avesani, Marco
Marangon, Davide Giacomo
Stanco, Andrea
Vallone, Giuseppe
Villoresi, Paolo
Omar, Yasser
contents Over the last decades, Quantum Key Distribution (QKD) has risen as a promising solution for secure communications. However, like all cryptographic protocols, QKD implementations can open security vulnerabilities. Until now, the study of physical vulnerabilities in QKD setups has primarily focused on the optical channel. In classical cryptoanalysis, power and electromagnetic side-channel analysis are powerful techniques used to access unwanted information about the encryption key in symmetric-key algorithms. In QKD they have rarely been used, since they require an eavesdropper to have access to Alice or Bob's setups. However, security proofs of QKD protocols generally assume that these setups are secure, making it crucial to understand the necessary security measures to ensure this protection. In this work, we propose and implement a power side-channel analysis to a QKD system, by exploiting the power consumption of the electronic driver controlling the electro-optical components of the QKD transmitter. QKD modules typically require very precise electronic drivers, such as Field Programmable Gate Arrays (FPGAs). Here, we show that the FPGA's power consumption can leak information about the QKD operation, and consequently the transmitted key. The analysis was performed on the QKD transmitter at the University of Padua. Our results are consistent and show critical information leakage, having reached a maximum accuracy of 73.35% in predicting transmitted qubits at a 100 MHz repetition frequency.
format Preprint
id arxiv_https___arxiv_org_abs_2503_11767
institution arXiv
publishDate 2025
record_format arxiv
spellingShingle Power-consumption Backdoor in Quantum Key Distribution
da Costa, Beatriz Lopes
Bolaños, Matías R.
Chaves, Ricardo
Narduzzi, Claudio
Avesani, Marco
Marangon, Davide Giacomo
Stanco, Andrea
Vallone, Giuseppe
Villoresi, Paolo
Omar, Yasser
Quantum Physics
Over the last decades, Quantum Key Distribution (QKD) has risen as a promising solution for secure communications. However, like all cryptographic protocols, QKD implementations can open security vulnerabilities. Until now, the study of physical vulnerabilities in QKD setups has primarily focused on the optical channel. In classical cryptoanalysis, power and electromagnetic side-channel analysis are powerful techniques used to access unwanted information about the encryption key in symmetric-key algorithms. In QKD they have rarely been used, since they require an eavesdropper to have access to Alice or Bob's setups. However, security proofs of QKD protocols generally assume that these setups are secure, making it crucial to understand the necessary security measures to ensure this protection. In this work, we propose and implement a power side-channel analysis to a QKD system, by exploiting the power consumption of the electronic driver controlling the electro-optical components of the QKD transmitter. QKD modules typically require very precise electronic drivers, such as Field Programmable Gate Arrays (FPGAs). Here, we show that the FPGA's power consumption can leak information about the QKD operation, and consequently the transmitted key. The analysis was performed on the QKD transmitter at the University of Padua. Our results are consistent and show critical information leakage, having reached a maximum accuracy of 73.35% in predicting transmitted qubits at a 100 MHz repetition frequency.
title Power-consumption Backdoor in Quantum Key Distribution
topic Quantum Physics
url https://arxiv.org/abs/2503.11767