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Twin-Field Quantum Key Distribution with Fully Discrete Phase Randomization

Guillermo Currás-Lorenzo, Lewis Wooltorton, Mohsen Razavi

2021Physical Review Applied26 citationsDOIOpen Access PDF

Abstract

Twin-field (TF) quantum key distribution (QKD) can overcome fundamental secret-key-rate bounds on point-to-point QKD links, allowing us to reach longer distances than ever before. Since its introduction, several TFQKD variants have been proposed, and some of them have already been implemented experimentally. Most of them assume that the users can emit weak coherent pulses with a continuous random phase. In practice, this assumption is often not satisfied, which could open up security loopholes in their implementations. To close this loophole, we propose and prove the security of a TFQKD variant that relies exclusively on discrete phase randomization. Remarkably, our results show that it can also provide higher secret-key rates than an equivalent continuous-phase-randomized protocol.

Topics & Concepts

Quantum key distributionComputer scienceKey (lock)QuantumTopology (electrical circuits)Distribution (mathematics)Phase (matter)Statistical physicsContinuous phase modulationEncoding (memory)Theoretical computer scienceQuantum cryptographyAlgorithmPhysicsQuantum networkMathematicsQuantum information processingDiscrete mathematicsCoherent statesProbability distributionQuantum algorithmDiscrete time and continuous timeCryptographyKey generationQuantum mechanicsContinuous variableQuantum channelQuantum computerQuantum Information and CryptographyQuantum Mechanics and ApplicationsAdvanced Statistical Modeling Techniques
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