Hyper-entanglement in time and frequency

Publikation: Beitrag in Buch/Bericht/Sammelwerk/KonferenzbandAufsatz in KonferenzbandForschungPeer-Review

Autorschaft

  • Piotr Roztocki
  • Christian Reimer
  • Stefania Sciara
  • Mehedi Islam
  • Luis Romero Cortes
  • Yanbing Zhang
  • Bennet Fischer
  • Sebastien Loranger
  • Raman Kashyap
  • Alfonso Cino
  • Sai T. Chu
  • Brent E. Little
  • David J. Moss
  • Lucia Caspani
  • William J. Munro
  • Jose Azana
  • Michael Kues
  • Roberto Morandotti

Externe Organisationen

  • Institut national de la recherche scientifique (INRS)
  • HyperLight Corporation
  • Unversität Palermo
  • École polytechnique de Montréal
  • Max-Planck-Institut für die Physik des Lichts
  • City University of Hong Kong
  • Xi'an Institute of Optics and Precision Mechanics Chinese Academy of Sciences
  • Swinburne University of Technology
  • University of Strathclyde
  • Nippon Telegraph & Telephone
  • Research Organization of Information and Systems National Institute of Informatics
  • University of Glasgow
  • University of Electronic Science and Technology of China
  • St. Petersburg National Research University of Information Technologies, Mechanics and Optics (ITMO)
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Details

OriginalspracheEnglisch
Titel des SammelwerksEuropean Quantum Electronics Conference, EQEC_2019
Herausgeber (Verlag)OSA - The Optical Society
ISBN (elektronisch)9781557528209
ISBN (Print)9781728104690
PublikationsstatusVeröffentlicht - 2019
Extern publiziertJa
VeranstaltungEuropean Quantum Electronics Conference, EQEC_2019 - Munich, Großbritannien / Vereinigtes Königreich
Dauer: 23 Juni 201927 Juni 2019

Publikationsreihe

NameOptics InfoBase Conference Papers
BandPart F143-EQEC 2019

Abstract

Hyper-entanglement, i.e. entanglement in more than one degree of freedom, enables a multiplicative increase in Hilbert space size. Such systems can be treated as multi-partite even though the number of state particles is not increased, making them highly attractive for applications in high-capacity quantum communications and information processing [1]. Until now, such states have been realized only using combinations of fully independent degrees of freedom, described by commuting operators, such as polarization and optical paths. Time and frequency, in turn, are linked and described by non-commuting operators. Here, using two discrete forms of energy-time entanglement we demonstrate that time and frequency can be used for genuine multi-partite hyper-entangled states [2]. This is achieved by increasing the time-frequency product to far exceed the Heisenberg uncertainty limit, effectively making the time and frequency degrees independent.

ASJC Scopus Sachgebiete

Zitieren

Hyper-entanglement in time and frequency. / Roztocki, Piotr; Reimer, Christian; Sciara, Stefania et al.
European Quantum Electronics Conference, EQEC_2019. OSA - The Optical Society, 2019. 2019-ea_p_3 (Optics InfoBase Conference Papers; Band Part F143-EQEC 2019).

Publikation: Beitrag in Buch/Bericht/Sammelwerk/KonferenzbandAufsatz in KonferenzbandForschungPeer-Review

Roztocki, P, Reimer, C, Sciara, S, Islam, M, Cortes, LR, Zhang, Y, Fischer, B, Loranger, S, Kashyap, R, Cino, A, Chu, ST, Little, BE, Moss, DJ, Caspani, L, Munro, WJ, Azana, J, Kues, M & Morandotti, R 2019, Hyper-entanglement in time and frequency. in European Quantum Electronics Conference, EQEC_2019., 2019-ea_p_3, Optics InfoBase Conference Papers, Bd. Part F143-EQEC 2019, OSA - The Optical Society, European Quantum Electronics Conference, EQEC_2019, Munich, Großbritannien / Vereinigtes Königreich, 23 Juni 2019. <https://opg.optica.org/abstract.cfm?uri=EQEC-2019-ea_p_3>
Roztocki, P., Reimer, C., Sciara, S., Islam, M., Cortes, L. R., Zhang, Y., Fischer, B., Loranger, S., Kashyap, R., Cino, A., Chu, S. T., Little, B. E., Moss, D. J., Caspani, L., Munro, W. J., Azana, J., Kues, M., & Morandotti, R. (2019). Hyper-entanglement in time and frequency. In European Quantum Electronics Conference, EQEC_2019 Artikel 2019-ea_p_3 (Optics InfoBase Conference Papers; Band Part F143-EQEC 2019). OSA - The Optical Society. https://opg.optica.org/abstract.cfm?uri=EQEC-2019-ea_p_3
Roztocki P, Reimer C, Sciara S, Islam M, Cortes LR, Zhang Y et al. Hyper-entanglement in time and frequency. in European Quantum Electronics Conference, EQEC_2019. OSA - The Optical Society. 2019. 2019-ea_p_3. (Optics InfoBase Conference Papers).
Roztocki, Piotr ; Reimer, Christian ; Sciara, Stefania et al. / Hyper-entanglement in time and frequency. European Quantum Electronics Conference, EQEC_2019. OSA - The Optical Society, 2019. (Optics InfoBase Conference Papers).
Download
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title = "Hyper-entanglement in time and frequency",
abstract = "Hyper-entanglement, i.e. entanglement in more than one degree of freedom, enables a multiplicative increase in Hilbert space size. Such systems can be treated as multi-partite even though the number of state particles is not increased, making them highly attractive for applications in high-capacity quantum communications and information processing [1]. Until now, such states have been realized only using combinations of fully independent degrees of freedom, described by commuting operators, such as polarization and optical paths. Time and frequency, in turn, are linked and described by non-commuting operators. Here, using two discrete forms of energy-time entanglement we demonstrate that time and frequency can be used for genuine multi-partite hyper-entangled states [2]. This is achieved by increasing the time-frequency product to far exceed the Heisenberg uncertainty limit, effectively making the time and frequency degrees independent.",
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AU - Roztocki, Piotr

AU - Reimer, Christian

AU - Sciara, Stefania

AU - Islam, Mehedi

AU - Cortes, Luis Romero

AU - Zhang, Yanbing

AU - Fischer, Bennet

AU - Loranger, Sebastien

AU - Kashyap, Raman

AU - Cino, Alfonso

AU - Chu, Sai T.

AU - Little, Brent E.

AU - Moss, David J.

AU - Caspani, Lucia

AU - Munro, William J.

AU - Azana, Jose

AU - Kues, Michael

AU - Morandotti, Roberto

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PY - 2019

Y1 - 2019

N2 - Hyper-entanglement, i.e. entanglement in more than one degree of freedom, enables a multiplicative increase in Hilbert space size. Such systems can be treated as multi-partite even though the number of state particles is not increased, making them highly attractive for applications in high-capacity quantum communications and information processing [1]. Until now, such states have been realized only using combinations of fully independent degrees of freedom, described by commuting operators, such as polarization and optical paths. Time and frequency, in turn, are linked and described by non-commuting operators. Here, using two discrete forms of energy-time entanglement we demonstrate that time and frequency can be used for genuine multi-partite hyper-entangled states [2]. This is achieved by increasing the time-frequency product to far exceed the Heisenberg uncertainty limit, effectively making the time and frequency degrees independent.

AB - Hyper-entanglement, i.e. entanglement in more than one degree of freedom, enables a multiplicative increase in Hilbert space size. Such systems can be treated as multi-partite even though the number of state particles is not increased, making them highly attractive for applications in high-capacity quantum communications and information processing [1]. Until now, such states have been realized only using combinations of fully independent degrees of freedom, described by commuting operators, such as polarization and optical paths. Time and frequency, in turn, are linked and described by non-commuting operators. Here, using two discrete forms of energy-time entanglement we demonstrate that time and frequency can be used for genuine multi-partite hyper-entangled states [2]. This is achieved by increasing the time-frequency product to far exceed the Heisenberg uncertainty limit, effectively making the time and frequency degrees independent.

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T3 - Optics InfoBase Conference Papers

BT - European Quantum Electronics Conference, EQEC_2019

PB - OSA - The Optical Society

T2 - European Quantum Electronics Conference, EQEC_2019

Y2 - 23 June 2019 through 27 June 2019

ER -

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