Yoann Pelet scite author profile

The ability to know and verifiably demonstrate the origins of messages can often be as important as encrypting the message itself. Here we present an experimental demonstration of an unconditionally secure digital signature (USS) protocol implemented for the first time, to the best of our knowledge, on a fully connected quantum network without trusted nodes. Our USS protocol is secure against forging, repudiation and messages are transferrable. We show the feasibility of unconditionally secure signatures using only bi-partite entangled states distributed throughout the network and experimentally evaluate the performance of the protocol in real world scenarios with varying message lengths.

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Operational entanglement-based quantum key distribution over 50 km of real-field optical fibres

Pelet¹,

Sauder²,

Cohen³

et al. 2022

Preprint

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We present a real field quantum key distribution link based on energy-time entanglement. Three nodes are connected over the city of Nice by means of optical fibers with a total distance of 50 km. We have implemented a high-quality source of energy-time entangled photon pairs and actively stabilized analysers to project the quantum states, associated with an innovative remote synchronization method of the end stations' clocks which does not require any dedicated channel. The system is compatible with the ITU 100 GHz standard telecomgrid, through which a raw key rate of 40 kbps per pair of channels is obtained. A post-treatment software performs all the necessary post-processing procedures enabling to establish secret keys in real time. All of those embedded systems and achieved performance make this network the first fully operational entanglement based metropolitan quantum network to be implemented in real field.

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Operational entanglement-based quantum key distribution in real-field

Pelet¹,

Martin²,

Sauder³

et al. 2022

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Unconditionally secure digital signatures implemented in an 8-user quantum network

Pelet¹,

Puthoor²,

Natarajan³

et al. 2022

Preprint

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Yoann Pelet

Dynamic arrest during the spreading of a yield stress fluid drop

Unconditionally secure digital signatures implemented in an eight-user quantum network*

Operational entanglement-based quantum key distribution over 50 km of real-field optical fibres

Operational entanglement-based quantum key distribution in real-field

Unconditionally secure digital signatures implemented in an 8-user quantum network

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