Francesco Picciariello scite author profile

Entanglement is a fundamental resource for quantum information science. However, bipartite entanglement is destroyed when one particle is sharply measured, which occurs in most applications.Here we experimentally show that, if instead of sharp measurements, one performs many sequential unsharp measurements on one particle which are suitably chosen depending on the previous outcomes, then entanglement is preserved and can reveal quantum correlations through measurements on the second particle. Specifically, we observe that pairs of photons entangled in polarization maintain their entanglement and their ability to violate Bell inequalities when one particle undergoes three sequential measurements. This proof-of-principle experiment demonstrates the possibility of repeatedly harnessing a quantum resource.

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Resource-effective quantum key distribution: a field trial in Padua city center

Avesani

Calderaro

Foletto

et al. 2021

Opt. Lett.

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Field-trials are of key importance for novel technologies seeking commercialization and wide-spread adoption. This is certainly also the case for Quantum Key Distribution (QKD), which allows distant parties to distill a secret key with unconditional security. Typically, QKD demonstrations over urban infrastructures require complex stabilization and synchronization systems to maintain a low Quantum Bit Error (QBER) and high secret key rates over time. Here we present a field-trial which exploits a low-complexity self-stabilized hardware and a novel synchronization technique, to perform QKD over optical fibers deployed in the city center of Padua, Italy. In particular, two techniques recently introduced by our research group are evaluated in a real-world environment: the iPOGNAC polarization encoder was used for the preparation of the quantum states, while the temporal synchronization was performed using the Qubit4Sync algorithm. The results here presented demonstrate the validity and robustness of our resource-effective QKD system, that can be easily and rapidly installed in an existing telecommunication infrastructure, thus representing an important step towards mature, efficient and low-cost QKD systems.

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Deployment-Ready Quantum Key Distribution Over a Classical Network Infrastructure in Padua

Avesani

Foletto

Padovan

et al. 2022

J. Lightwave Technol.

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Security bounds for decoy-state quantum key distribution with arbitrary photon-number statistics

et al. 2022

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Optimal design and performance evaluation of free-space quantum key distribution systems

Scriminich¹,

Foletto²,

Picciariello³

et al. 2022

Quantum Sci. Technol.

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Free-space ground-to-ground links will be an integral part of future quantum communication networks. The implementation of free-space and ﬁber links in daylight inter-modal conﬁgurations is however still hard to achieve, due to the impact of atmospheric turbulence, which strongly decreases the coupling eﬃciency into the ﬁber. In this work, we present a comprehensive model of the performance of a free-space ground-to-ground quantum key distribution (QKD) system based on the eﬃcient-BB84 protocol with active decoy states. Our model takes into account the atmospheric channel contribution, the transmitter and receiver telescope design constraints, the parameters of the quantum source and detectors, and the ﬁnite-key analysis to produce a set of requirements and optimal design choices for a QKD system operating under speciﬁc channel conditions. The channel attenuation is calculated considering all eﬀects deriving from the atmospheric propagation (absorption, beam broadening, beam wandering, scintillation, and wavefront distortions), as well as the eﬀect of ﬁber-coupling in the presence of a partial adaptive optics correction with ﬁnite control bandwidth. We ﬁnd that the channel ﬂuctuation statistics must be considered to correctly estimate the eﬀect of the saturation rate of the single-photon detectors, which may otherwise lead to an overestimation of the secret key rate. We further present strategies to minimize the impact of diﬀuse atmospheric background in daylight operation by means of spectral and temporal ﬁltering.

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