Henry Semenenko scite author profile

Photonic integrated circuits have facilitated a drastic increase in the complexity of quantum information processing, from which near-term quantum networks can benefit. Here, we report monolithically fabricated indium phosphide transmitters capable of performing measurement-deviceindependent quantum key distribution. We demonstrate an estimated 1 kbps key rate at 100 km, with predicted distances over 350 km possible. The scheme removes detector vulnerabilities through a centralised and untrusted resource, enabling quantum-secured communication with cost-effective, mass-manufacturable devices.

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Interference between independent photonic integrated devices for quantum key distribution

Semenenko

Sibson

Thompson

et al. 2019

Opt. Lett.

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Advances in quantum computing are a rapidly growing threat towards modern cryptography. Quantum key distribution (QKD) provides long-term security without assuming the computational power of an adversary. However, inconsistencies between theory and experiment have raised questions in terms of real-world security, while large and power-hungry commercial systems have slowed wide-scale adoption. Measurement-device-independent QKD (MDI-QKD) provides a method of sharing secret keys that removes all possible detector side-channel attacks which drastically improves security claims. In this letter, we experimentally demonstrate a key step required to perform MDI-QKD with scalable integrated devices. We show Hong-Ou-Mandel interference between weak coherent states carved from two independent indium phosphide transmitters at 431 MHz with a visibility of 46.5 ± 0.8%. This work demonstrates the feasibility of using integrated devices to lower a major barrier towards adoption of QKD in metropolitan networks.

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Implementing the Deutsch-Jozsa algorithm with macroscopic ensembles

Semenenko

Byrnes

2016

Phys. Rev. A

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General rightsThis document is made available in accordance with publisher policies. Please cite only the published version using the reference above. Full terms of use are available: http://www.bristol.ac.uk/pure/about/ebr-terms PHYSICAL REVIEW A 93, 052302 (2016) Implementing the Deutsch-Jozsa algorithm with macroscopic ensembles Quantum computing implementations under consideration today typically deal with systems with microscopic degrees of freedom such as photons, ions, cold atoms, and superconducting circuits. The quantum information is stored typically in low-dimensional Hilbert spaces such as qubits, as quantum effects are strongest in such systems. It has, however, been demonstrated that quantum effects can be observed in mesoscopic and macroscopic systems, such as nanomechanical systems and gas ensembles. While few-qubit quantum information demonstrations have been performed with such macroscopic systems, a quantum algorithm showing exponential speedup over classical algorithms is yet to be shown. Here, we show that the Deutsch-Jozsa algorithm can be implemented with macroscopic ensembles. The encoding that we use avoids the detrimental effects of decoherence that normally plagues macroscopic implementations. We discuss two mapping procedures which can be chosen depending upon the constraints of the oracle and the experiment. Both methods have an exponential speedup over the classical case, and only require control of the ensembles at the level of the total spin of the ensembles. It is shown that both approaches reproduce the qubit Deutsch-Jozsa algorithm, and are robust under decoherence.

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Measurements towards providing security assurance for a chip-scale QKD system

Vaquiero-Stainer

Hart

Kirkwood

et al. 2018

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Henry Semenenko

Chip-based measurement-device-independent quantum key distribution

Interference between independent photonic integrated devices for quantum key distribution

Implementing the Deutsch-Jozsa algorithm with macroscopic ensembles

Measurements towards providing security assurance for a chip-scale QKD system

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