Petabit-per-second data transmission using a chip-scale microcomb ring resonator source

A. A. Jørgensen; D. Kong; M. R. Henriksen; F. Klejs; Z. Ye; B. Helgason; H. E. Hansen; H. Hu; M. Yankov; S. Forchhammer; P. Andrekson; A. Larsson; M. Karlsson; J. Schröder; Y. Sasaki; K. Aikawa; J. W. Thomsen; T. Morioka; M. Galili; V. Torres-Company; L. K. Oxenløwe

doi:10.1038/s41566-022-01082-z

Petabit-per-second data transmission using a chip-scale microcomb ring resonator source

A. A. Jørgensen^*, D. Kong, M. R. Henriksen, F. Klejs, Z. Ye, B. Helgason, H. E. Hansen, H. Hu, M. Yankov, S. Forchhammer, P. Andrekson, A. Larsson, M. Karlsson, J. Schröder, Y. Sasaki, K. Aikawa, J. W. Thomsen, T. Morioka, M. Galili, V. Torres-CompanyL. K. Oxenløwe

^*Corresponding author for this work

Research output: Contribution to journal › Journal article › Research › peer-review

Abstract

Optical fibre communication is the backbone of the internet. As essential core technologies are approaching their limits of size, speed and energy-efficiency, there is a need for new technologies that offer further scaling of data transmission capacity. Here we show that a single optical frequency-comb source based on a silicon nitride ring resonator supports data capacities in the petabit-per-second regime. We experimentally demonstrate transmission of 1.84 Pbit s^–1 over a 37-core, 7.9-km-long fibre using 223 wavelength channels derived from a single microcomb ring resonator producing a stabilized dark-pulse Kerr frequency comb. We also present a theoretical analysis that indicates that a single, chip-scale light source should be able to support 100 Pbit s^–1 in massively parallel space-and-wavelength multiplexed data transmission systems. Our findings could mark a shift in the design of future communication systems, targeting device-efficient transmitters and receivers.

Original language	English
Journal	Nature Photonics
Volume	16
Pages (from-to)	798-802
ISSN	1749-4885
DOIs	https://doi.org/10.1038/s41566-022-01082-z
Publication status	Published - 2022

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Jørgensen, A. A., Kong, D., Henriksen, M. R., Klejs, F., Ye, Z., Helgason, B., Hansen, H. E., Hu, H., Yankov, M., Forchhammer, S., Andrekson, P., Larsson, A., Karlsson, M., Schröder, J., Sasaki, Y., Aikawa, K., Thomsen, J. W., Morioka, T., Galili, M., ... Oxenløwe, L. K. (2022). Petabit-per-second data transmission using a chip-scale microcomb ring resonator source. Nature Photonics, 16, 798-802. https://doi.org/10.1038/s41566-022-01082-z

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title = "Petabit-per-second data transmission using a chip-scale microcomb ring resonator source",

abstract = "Optical fibre communication is the backbone of the internet. As essential core technologies are approaching their limits of size, speed and energy-efficiency, there is a need for new technologies that offer further scaling of data transmission capacity. Here we show that a single optical frequency-comb source based on a silicon nitride ring resonator supports data capacities in the petabit-per-second regime. We experimentally demonstrate transmission of 1.84 Pbit s–1 over a 37-core, 7.9-km-long fibre using 223 wavelength channels derived from a single microcomb ring resonator producing a stabilized dark-pulse Kerr frequency comb. We also present a theoretical analysis that indicates that a single, chip-scale light source should be able to support 100 Pbit s–1 in massively parallel space-and-wavelength multiplexed data transmission systems. Our findings could mark a shift in the design of future communication systems, targeting device-efficient transmitters and receivers.",

author = "J{\o}rgensen, {A. A.} and D. Kong and Henriksen, {M. R.} and F. Klejs and Z. Ye and B. Helgason and Hansen, {H. E.} and H. Hu and M. Yankov and S. Forchhammer and P. Andrekson and A. Larsson and M. Karlsson and J. Schr{\"o}der and Y. Sasaki and K. Aikawa and Thomsen, {J. W.} and T. Morioka and M. Galili and V. Torres-Company and Oxenl{\o}we, {L. K.}",

note = "Publisher Copyright: {\textcopyright} 2022, The Author(s), under exclusive licence to Springer Nature Limited.",

year = "2022",

doi = "10.1038/s41566-022-01082-z",

language = "English",

volume = "16",

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Jørgensen, AA, Kong, D, Henriksen, MR, Klejs, F, Ye, Z, Helgason, B, Hansen, HE, Hu, H , Yankov, M , Forchhammer, S, Andrekson, P, Larsson, A, Karlsson, M, Schröder, J, Sasaki, Y, Aikawa, K, Thomsen, JW, Morioka, T , Galili, M, Torres-Company, V & Oxenløwe, LK 2022, 'Petabit-per-second data transmission using a chip-scale microcomb ring resonator source', Nature Photonics, vol. 16, pp. 798-802. https://doi.org/10.1038/s41566-022-01082-z

TY - JOUR

T1 - Petabit-per-second data transmission using a chip-scale microcomb ring resonator source

AU - Jørgensen, A. A.

AU - Kong, D.

AU - Henriksen, M. R.

AU - Klejs, F.

AU - Ye, Z.

AU - Helgason, B.

AU - Hansen, H. E.

AU - Hu, H.

AU - Yankov, M.

AU - Forchhammer, S.

AU - Andrekson, P.

AU - Larsson, A.

AU - Karlsson, M.

AU - Schröder, J.

AU - Sasaki, Y.

AU - Aikawa, K.

AU - Thomsen, J. W.

AU - Morioka, T.

AU - Galili, M.

AU - Torres-Company, V.

AU - Oxenløwe, L. K.

PY - 2022

Y1 - 2022

N2 - Optical fibre communication is the backbone of the internet. As essential core technologies are approaching their limits of size, speed and energy-efficiency, there is a need for new technologies that offer further scaling of data transmission capacity. Here we show that a single optical frequency-comb source based on a silicon nitride ring resonator supports data capacities in the petabit-per-second regime. We experimentally demonstrate transmission of 1.84 Pbit s–1 over a 37-core, 7.9-km-long fibre using 223 wavelength channels derived from a single microcomb ring resonator producing a stabilized dark-pulse Kerr frequency comb. We also present a theoretical analysis that indicates that a single, chip-scale light source should be able to support 100 Pbit s–1 in massively parallel space-and-wavelength multiplexed data transmission systems. Our findings could mark a shift in the design of future communication systems, targeting device-efficient transmitters and receivers.

AB - Optical fibre communication is the backbone of the internet. As essential core technologies are approaching their limits of size, speed and energy-efficiency, there is a need for new technologies that offer further scaling of data transmission capacity. Here we show that a single optical frequency-comb source based on a silicon nitride ring resonator supports data capacities in the petabit-per-second regime. We experimentally demonstrate transmission of 1.84 Pbit s–1 over a 37-core, 7.9-km-long fibre using 223 wavelength channels derived from a single microcomb ring resonator producing a stabilized dark-pulse Kerr frequency comb. We also present a theoretical analysis that indicates that a single, chip-scale light source should be able to support 100 Pbit s–1 in massively parallel space-and-wavelength multiplexed data transmission systems. Our findings could mark a shift in the design of future communication systems, targeting device-efficient transmitters and receivers.

U2 - 10.1038/s41566-022-01082-z

DO - 10.1038/s41566-022-01082-z

M3 - Journal article

AN - SCOPUS:85140206814

SN - 1749-4885

VL - 16

SP - 798

EP - 802

JO - Nature Photonics

JF - Nature Photonics

ER -

Petabit-per-second data transmission using a chip-scale microcomb ring resonator source

Abstract

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