Overcoming Noise in Entanglement Distribution

Sebastian Ecker; Frédéric Bouchard; Lukas Bulla; Florian Brandt; Oskar Kohout; Fabian Steinlechner; Robert Fickler; Mehul Malik; Yelena Guryanova; Rupert Ursin; Marcus Huber

doi:10.1103/PhysRevX.9.041042

Overcoming Noise in Entanglement Distribution

Sebastian Ecker
, Frédéric Bouchard
, Lukas Bulla
, Florian Brandt
, Oskar Kohout
, Fabian Steinlechner
, Robert Fickler
, Mehul Malik
, Yelena Guryanova
, Rupert Ursin
, Marcus Huber

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

254 Citations (Scopus)

44 Downloads (Pure)

Abstract

Noise can be considered the natural enemy of quantum information. An often implied benefit of high-dimensional entanglement is its increased resilience to noise. However, manifesting this potential in an experimentally meaningful fashion is challenging and has never been done before. In infinite dimensional spaces, discretization is inevitable and renders the effective dimension of quantum states a tunable parameter. Owing to advances in experimental techniques and theoretical tools, we demonstrate an increased resistance to noise by identifying two pathways to exploit high-dimensional entangled states. Our study is based on two separate experiments utilizing canonical spatiotemporal properties of entangled photon pairs. Following these different pathways to noise resilience, we are able to certify entanglement in the photonic orbital-angular-momentum and energy-time degrees of freedom up to noise conditions corresponding to a noise fraction of 72% and 92%, respectively. Our work paves the way toward practical quantum communication systems that are able to surpass current noise and distance limitations, while not compromising on potential device independence.

Original language	English
Article number	041042
Journal	Physical Review X
Volume	9
Issue number	4
DOIs	https://doi.org/10.1103/PhysRevX.9.041042
Publication status	Published - 26 Nov 2019
Publication type	A1 Journal article-refereed

Publication forum classification

Publication forum level 3

ASJC Scopus subject areas

General Physics and Astronomy

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10.1103/PhysRevX.9.041042Licence: CC BY

PhysRevX.9.041042
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http://urn.fi/URN:NBN:fi:tuni-202001201403Licence: CC BY

Cite this

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abstract = "Noise can be considered the natural enemy of quantum information. An often implied benefit of high-dimensional entanglement is its increased resilience to noise. However, manifesting this potential in an experimentally meaningful fashion is challenging and has never been done before. In infinite dimensional spaces, discretization is inevitable and renders the effective dimension of quantum states a tunable parameter. Owing to advances in experimental techniques and theoretical tools, we demonstrate an increased resistance to noise by identifying two pathways to exploit high-dimensional entangled states. Our study is based on two separate experiments utilizing canonical spatiotemporal properties of entangled photon pairs. Following these different pathways to noise resilience, we are able to certify entanglement in the photonic orbital-angular-momentum and energy-time degrees of freedom up to noise conditions corresponding to a noise fraction of 72\% and 92\%, respectively. Our work paves the way toward practical quantum communication systems that are able to surpass current noise and distance limitations, while not compromising on potential device independence.",

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AU - Bulla, Lukas

AU - Brandt, Florian

AU - Kohout, Oskar

AU - Steinlechner, Fabian

AU - Fickler, Robert

AU - Malik, Mehul

AU - Guryanova, Yelena

AU - Ursin, Rupert

AU - Huber, Marcus

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AB - Noise can be considered the natural enemy of quantum information. An often implied benefit of high-dimensional entanglement is its increased resilience to noise. However, manifesting this potential in an experimentally meaningful fashion is challenging and has never been done before. In infinite dimensional spaces, discretization is inevitable and renders the effective dimension of quantum states a tunable parameter. Owing to advances in experimental techniques and theoretical tools, we demonstrate an increased resistance to noise by identifying two pathways to exploit high-dimensional entangled states. Our study is based on two separate experiments utilizing canonical spatiotemporal properties of entangled photon pairs. Following these different pathways to noise resilience, we are able to certify entanglement in the photonic orbital-angular-momentum and energy-time degrees of freedom up to noise conditions corresponding to a noise fraction of 72% and 92%, respectively. Our work paves the way toward practical quantum communication systems that are able to surpass current noise and distance limitations, while not compromising on potential device independence.

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Overcoming Noise in Entanglement Distribution

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