Low-loss silicon core fibre platform for mid-infrared nonlinear photonics
Low-loss silicon core fibre platform for mid-infrared nonlinear photonics
Broadband mid-infrared light sources are highly desired for wide-ranging applications that span free-space communications to spectroscopy. In recent years, silicon has attracted great interest as a platform for nonlinear optical wavelength conversion in this region, owing to its low losses (linear and nonlinear) and high stability. However, most research in this area has made use of small core waveguides fabricated from silicon-on-insulator platforms, which suffer from high absorption losses of the use of silica cladding, limiting their ability to generate light beyond 3 µm. Here, we design and demonstrate a compact silicon core, silica-clad waveguide platform that has low losses across the entire silicon transparency window. The waveguides are fabricated from a silicon core fibre that is tapered to engineer mode properties to ensure efficient nonlinear propagation in the core with minimal interaction of the mid-infrared light with the cladding. These waveguides exhibit many of the benefits of fibre platforms, such as a high coupling efficiency and power handling capability, allowing for the generation of mid-infrared supercontinuum spectra with high brightness and coherence spanning almost two octaves (1.6–5.3 µm).
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Ren, Haonan
580be2e3-5394-4592-8db1-fe02f1282463
Shen, Li
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Runge, Antoine F.J.
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Hawkins, Thomas
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Ballato, John
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Gibson, Ursula
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Peacock, Anna
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Ren, Haonan
580be2e3-5394-4592-8db1-fe02f1282463
Shen, Li
1ed90066-0403-4ad3-a4c0-e0d0f94b0954
Runge, Antoine F.J.
874cec37-209b-4c7a-97a5-56d05596dd2b
Hawkins, Thomas
a699621e-1540-41dc-b39c-33e382593102
Ballato, John
a93092f5-bd5f-4126-ada9-142b93308ae5
Gibson, Ursula
a465acb0-eecd-43b9-80c3-2ffe42c48626
Peacock, Anna
685d924c-ef6b-401b-a0bd-acf1f8e758fc
Ren, Haonan, Shen, Li, Runge, Antoine F.J., Hawkins, Thomas, Ballato, John, Gibson, Ursula and Peacock, Anna
(2019)
Low-loss silicon core fibre platform for mid-infrared nonlinear photonics.
Light: Science and Applications, 8 (105), .
(doi:10.1038/s41377-019-0217-z).
Abstract
Broadband mid-infrared light sources are highly desired for wide-ranging applications that span free-space communications to spectroscopy. In recent years, silicon has attracted great interest as a platform for nonlinear optical wavelength conversion in this region, owing to its low losses (linear and nonlinear) and high stability. However, most research in this area has made use of small core waveguides fabricated from silicon-on-insulator platforms, which suffer from high absorption losses of the use of silica cladding, limiting their ability to generate light beyond 3 µm. Here, we design and demonstrate a compact silicon core, silica-clad waveguide platform that has low losses across the entire silicon transparency window. The waveguides are fabricated from a silicon core fibre that is tapered to engineer mode properties to ensure efficient nonlinear propagation in the core with minimal interaction of the mid-infrared light with the cladding. These waveguides exhibit many of the benefits of fibre platforms, such as a high coupling efficiency and power handling capability, allowing for the generation of mid-infrared supercontinuum spectra with high brightness and coherence spanning almost two octaves (1.6–5.3 µm).
Text
s41377-019-0217-z
- Version of Record
More information
Accepted/In Press date: 1 November 2019
e-pub ahead of print date: 21 November 2019
Identifiers
Local EPrints ID: 436249
URI: http://eprints.soton.ac.uk/id/eprint/436249
ISSN: 2095-5545
PURE UUID: fa921fc7-adc9-4871-a332-7f3c6b47c5e7
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Date deposited: 04 Dec 2019 17:30
Last modified: 17 Mar 2024 02:56
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Contributors
Author:
Haonan Ren
Author:
Li Shen
Author:
Antoine F.J. Runge
Author:
Thomas Hawkins
Author:
John Ballato
Author:
Ursula Gibson
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