Certified random-number generation from quantum steering

Dominick J. Joch; Sergei Slussarenko; Yuanlong Wang; Alex Pepper; Shouyi Xie; Bin Bin Xu; Ian R. Berkman; Sven Rogge; Geoff J. Pryde

doi:10.1103/PhysRevA.106.L050401

Certified random-number generation from quantum steering

Dominick J. Joch, Sergei Slussarenko, Yuanlong Wang, Alex Pepper, Shouyi Xie, Bin Bin Xu, Ian R. Berkman, Sven Rogge, Geoff J. Pryde

School of Optics and Photonics

Research output: Contribution to journal › Article › peer-review

5 Citations (Scopus)

Abstract

The use of simple quantum processes promises to provide numbers that no physical observer could predict, but in practice, unwanted noise and imperfect devices can compromise fundamental randomness and protocol security. The ultimate random number generators take advantage of quantum nonlocality to certify unpredictability - including to an adversary - even in the absence of trust in devices. We demonstrate a generator of public or private randomness based on the quantum steering task. We use polarization-entangled photon pairs to certify and extract randomness in a one-sided device-independent framework, with the detection loophole closed. Our work enables nonlocality-based certified randomness generation in environmental regimes where fully-device-independent protocols are not feasible.

Original language	English
Article number	L050401
Journal	Physical Review A
Volume	106
Issue number	5
DOIs	https://doi.org/10.1103/PhysRevA.106.L050401
Publication status	Published - Nov 2022

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10.1103/PhysRevA.106.L050401

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abstract = "The use of simple quantum processes promises to provide numbers that no physical observer could predict, but in practice, unwanted noise and imperfect devices can compromise fundamental randomness and protocol security. The ultimate random number generators take advantage of quantum nonlocality to certify unpredictability - including to an adversary - even in the absence of trust in devices. We demonstrate a generator of public or private randomness based on the quantum steering task. We use polarization-entangled photon pairs to certify and extract randomness in a one-sided device-independent framework, with the detection loophole closed. Our work enables nonlocality-based certified randomness generation in environmental regimes where fully-device-independent protocols are not feasible.",

author = "Joch, {Dominick J.} and Sergei Slussarenko and Yuanlong Wang and Alex Pepper and Shouyi Xie and Xu, {Bin Bin} and Berkman, {Ian R.} and Sven Rogge and Pryde, {Geoff J.}",

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AU - Joch, Dominick J.

AU - Slussarenko, Sergei

AU - Wang, Yuanlong

AU - Pepper, Alex

AU - Xie, Shouyi

AU - Xu, Bin Bin

AU - Berkman, Ian R.

AU - Rogge, Sven

AU - Pryde, Geoff J.

PY - 2022/11

Y1 - 2022/11

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AB - The use of simple quantum processes promises to provide numbers that no physical observer could predict, but in practice, unwanted noise and imperfect devices can compromise fundamental randomness and protocol security. The ultimate random number generators take advantage of quantum nonlocality to certify unpredictability - including to an adversary - even in the absence of trust in devices. We demonstrate a generator of public or private randomness based on the quantum steering task. We use polarization-entangled photon pairs to certify and extract randomness in a one-sided device-independent framework, with the detection loophole closed. Our work enables nonlocality-based certified randomness generation in environmental regimes where fully-device-independent protocols are not feasible.

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JO - Physical Review A

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Certified random-number generation from quantum steering

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