Related papers: On the Implementation Security of Twin-Field Quantum Key Distribution using Optical Injection Locking

On the Implementation Security of Twin-Field Quantum Key Distribution using Optical Injection Locking

URL: http://arxiv.org/abs/2508.21763v1
Date: Fri, 29 Aug 2025 16:38:18 GMT
Title: On the Implementation Security of Twin-Field Quantum Key Distribution using Optical Injection Locking
Authors: Sergio Juárez, Alessandro Marcomini, Mikhail Petrov, Robert I. Woodward, Toby J. Dowling, R. Mark Stevenson, Marcos Curty, Davide Rusca,
Abstract summary: Twin-Field Quantum Key Distribution (TF-QKD) has emerged as a leading quantum communication protocol.<n>We analyse potential side-channels in OIL-based TF-QKD that can be introduced through the various optical degrees of freedom of the externally injected reference laser.<n>We propose straightforward and highly effective countermeasures including high-speed photodiodes for real-time power monitoring and targeted spectral filtering to detect and suppress out-of-band signals.
Score: 32.505127447635864
License: http://arxiv.org/licenses/nonexclusive-distrib/1.0/
Abstract: Twin-Field Quantum Key Distribution (TF-QKD) has emerged as a leading quantum communication protocol, enabling secure key distribution over unprecedented distances by utilising coherent interference of quantum states. Optical Injection Locking (OIL) architectures have been used to simplify the precise phase and frequency stabilisation required by TF-QKD. In this work, we systematically analyse potential side-channels in OIL-based TF-QKD that can be introduced through the various optical degrees of freedom of the externally injected reference laser. We experimentally demonstrate two realistic attack scenarios: rapid intensity modulation of the reference laser and Trojan-horse signals exploiting wavelengths undetectable by conventional monitoring techniques. To counter these vulnerabilities, we propose straightforward and highly effective countermeasures including high-speed photodiodes for real-time power monitoring and targeted spectral filtering to detect and suppress out-of-band signals. Our experimental results confirm that these practical solutions substantially reinforce the security of TF-QKD systems without significant additional complexity or performance degradation. More broadly, our analysis highlights the critical importance of comprehensive optical monitoring to ensure the robust practical deployment of TF-QKD in real-world quantum communication networks.

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