Distributed feedback lasers for quantum cooling applications

Scott Watson; Steffan Gwyn; Eugenio Di Gaetano; Euan McBrearty; Thomas J. Slight; Martin Knapp; Szymon Stanczyk; Szymon Grzanka; Amit Yadav; Kevin E. Docherty; Edik Rafailov; Piotr Perlin; Steve Najda; Mike Leszczynski; Mohsin Haji; Marc Sorel; Douglas J. Paul; Anthony E. Kelly

doi:10.1109/ICTON51198.2020.9203200

Distributed feedback lasers for quantum cooling applications

Scott Watson^*, Steffan Gwyn, Eugenio Di Gaetano, Euan McBrearty, Thomas J. Slight, Martin Knapp, Szymon Stanczyk, Szymon Grzanka, Amit Yadav, Kevin E. Docherty, Edik Rafailov, Piotr Perlin, Steve Najda, Mike Leszczynski, Mohsin Haji, Marc Sorel, Douglas J. Paul, Anthony E. Kelly

^*Corresponding author for this work

Aston Institute of Photonic Technologies (AiPT)

Research output: Chapter in Book/Published conference output › Conference publication

Abstract

There is an ever-growing need for compact sources which can be used for the cooling process in high accuracy atomic clocks. Current systems make use of large, expensive lasers which are power-hungry and often require frequency doubling in order to hit the required wavelengths. Distributed feedback (DFB) lasers have been fabricated at a number of key wavelengths which would allow chip scale atomic devices with very high accuracy to become a reality. Two key atomic transitions analysed here are 88Sr+ and 87Rb which require cooling at 422 nm and 780.24 nm, respectively. The vital parameter of the DFB lasers for this application is the linewidth, as very narrow linewidths are required in order for the atomic cooling process to occur. The lasers realised here produce the required power levels, with high side-mode suppression ratios and show good single mode tuning which is important for hitting precise wavelengths. This work will present the latest techniques and results using the DFB lasers at both wavelengths.

Original language	English
Title of host publication	2020 22nd International Conference on Transparent Optical Networks, ICTON 2020
Publisher	IEEE
ISBN (Electronic)	9781728184234
DOIs	https://doi.org/10.1109/ICTON51198.2020.9203200
Publication status	Published - 22 Sept 2020
Event	22nd International Conference on Transparent Optical Networks, ICTON 2020 - Bari, Italy Duration: 19 Jul 2020 → 23 Jul 2020

Publication series

Name	International Conference on Transparent Optical Networks
Volume	2020-July
ISSN (Electronic)	2162-7339

Conference

Conference	22nd International Conference on Transparent Optical Networks, ICTON 2020
Country/Territory	Italy
City	Bari
Period	19/07/20 → 23/07/20

Access to Document

10.1109/ICTON51198.2020.9203200

Cite this

Watson, S., Gwyn, S., Di Gaetano, E., McBrearty, E., Slight, T. J., Knapp, M., Stanczyk, S., Grzanka, S., Yadav, A., Docherty, K. E., Rafailov, E., Perlin, P., Najda, S., Leszczynski, M., Haji, M., Sorel, M., Paul, D. J., & Kelly, A. E. (2020). Distributed feedback lasers for quantum cooling applications. In 2020 22nd International Conference on Transparent Optical Networks, ICTON 2020 Article 9203200 (International Conference on Transparent Optical Networks; Vol. 2020-July). IEEE. https://doi.org/10.1109/ICTON51198.2020.9203200

@inproceedings{9e7cbfb0bd6b4478894cbceb17f69232,

title = "Distributed feedback lasers for quantum cooling applications",

abstract = "There is an ever-growing need for compact sources which can be used for the cooling process in high accuracy atomic clocks. Current systems make use of large, expensive lasers which are power-hungry and often require frequency doubling in order to hit the required wavelengths. Distributed feedback (DFB) lasers have been fabricated at a number of key wavelengths which would allow chip scale atomic devices with very high accuracy to become a reality. Two key atomic transitions analysed here are 88Sr+ and 87Rb which require cooling at 422 nm and 780.24 nm, respectively. The vital parameter of the DFB lasers for this application is the linewidth, as very narrow linewidths are required in order for the atomic cooling process to occur. The lasers realised here produce the required power levels, with high side-mode suppression ratios and show good single mode tuning which is important for hitting precise wavelengths. This work will present the latest techniques and results using the DFB lasers at both wavelengths. ",

author = "Scott Watson and Steffan Gwyn and {Di Gaetano}, Eugenio and Euan McBrearty and Slight, {Thomas J.} and Martin Knapp and Szymon Stanczyk and Szymon Grzanka and Amit Yadav and Docherty, {Kevin E.} and Edik Rafailov and Piotr Perlin and Steve Najda and Mike Leszczynski and Mohsin Haji and Marc Sorel and Paul, {Douglas J.} and Kelly, {Anthony E.}",

year = "2020",

month = sep,

day = "22",

doi = "10.1109/ICTON51198.2020.9203200",

language = "English",

series = "International Conference on Transparent Optical Networks",

publisher = "IEEE",

booktitle = "2020 22nd International Conference on Transparent Optical Networks, ICTON 2020",

address = "United States",

note = "22nd International Conference on Transparent Optical Networks, ICTON 2020 ; Conference date: 19-07-2020 Through 23-07-2020",

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Watson, S, Gwyn, S, Di Gaetano, E, McBrearty, E, Slight, TJ, Knapp, M, Stanczyk, S, Grzanka, S, Yadav, A, Docherty, KE, Rafailov, E, Perlin, P, Najda, S, Leszczynski, M, Haji, M, Sorel, M, Paul, DJ & Kelly, AE 2020, Distributed feedback lasers for quantum cooling applications. in 2020 22nd International Conference on Transparent Optical Networks, ICTON 2020., 9203200, International Conference on Transparent Optical Networks, vol. 2020-July, IEEE, 22nd International Conference on Transparent Optical Networks, ICTON 2020, Bari, Italy, 19/07/20. https://doi.org/10.1109/ICTON51198.2020.9203200

Distributed feedback lasers for quantum cooling applications. / Watson, Scott; Gwyn, Steffan; Di Gaetano, Eugenio et al.
2020 22nd International Conference on Transparent Optical Networks, ICTON 2020. IEEE, 2020. 9203200 (International Conference on Transparent Optical Networks; Vol. 2020-July).

Research output: Chapter in Book/Published conference output › Conference publication

TY - GEN

T1 - Distributed feedback lasers for quantum cooling applications

AU - Watson, Scott

AU - Gwyn, Steffan

AU - Di Gaetano, Eugenio

AU - McBrearty, Euan

AU - Slight, Thomas J.

AU - Knapp, Martin

AU - Stanczyk, Szymon

AU - Grzanka, Szymon

AU - Yadav, Amit

AU - Docherty, Kevin E.

AU - Rafailov, Edik

AU - Perlin, Piotr

AU - Najda, Steve

AU - Leszczynski, Mike

AU - Haji, Mohsin

AU - Sorel, Marc

AU - Paul, Douglas J.

AU - Kelly, Anthony E.

PY - 2020/9/22

Y1 - 2020/9/22

N2 - There is an ever-growing need for compact sources which can be used for the cooling process in high accuracy atomic clocks. Current systems make use of large, expensive lasers which are power-hungry and often require frequency doubling in order to hit the required wavelengths. Distributed feedback (DFB) lasers have been fabricated at a number of key wavelengths which would allow chip scale atomic devices with very high accuracy to become a reality. Two key atomic transitions analysed here are 88Sr+ and 87Rb which require cooling at 422 nm and 780.24 nm, respectively. The vital parameter of the DFB lasers for this application is the linewidth, as very narrow linewidths are required in order for the atomic cooling process to occur. The lasers realised here produce the required power levels, with high side-mode suppression ratios and show good single mode tuning which is important for hitting precise wavelengths. This work will present the latest techniques and results using the DFB lasers at both wavelengths.

AB - There is an ever-growing need for compact sources which can be used for the cooling process in high accuracy atomic clocks. Current systems make use of large, expensive lasers which are power-hungry and often require frequency doubling in order to hit the required wavelengths. Distributed feedback (DFB) lasers have been fabricated at a number of key wavelengths which would allow chip scale atomic devices with very high accuracy to become a reality. Two key atomic transitions analysed here are 88Sr+ and 87Rb which require cooling at 422 nm and 780.24 nm, respectively. The vital parameter of the DFB lasers for this application is the linewidth, as very narrow linewidths are required in order for the atomic cooling process to occur. The lasers realised here produce the required power levels, with high side-mode suppression ratios and show good single mode tuning which is important for hitting precise wavelengths. This work will present the latest techniques and results using the DFB lasers at both wavelengths.

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DO - 10.1109/ICTON51198.2020.9203200

M3 - Conference publication

AN - SCOPUS:85092471290

T3 - International Conference on Transparent Optical Networks

BT - 2020 22nd International Conference on Transparent Optical Networks, ICTON 2020

PB - IEEE

T2 - 22nd International Conference on Transparent Optical Networks, ICTON 2020

Y2 - 19 July 2020 through 23 July 2020

ER -

Distributed feedback lasers for quantum cooling applications

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