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Tunable kHz distributed feedback fiber laser fabricated in 3D-printed glass

Tunable kHz distributed feedback fiber laser fabricated in 3D-printed glass
Tunable kHz distributed feedback fiber laser fabricated in 3D-printed glass
For short sections of fiber tailored to a specific application, fast laser-based manufacturing techniques can be considered as an attractive alternative to the often-cumbersome traditional manufacturing routes. With the use of high-power lasers, localized hot zones that are necessary for glass making can be obtained rapidly. For instance, laser-powder-deposition enables rapid fabrication of short, high gain fibers used in, e.g., distributed feedback fiber lasers (DFFLs). DFFLs offer sought after performance suitable for a broad range of applications in modern photonics, i.e., superior stability and narrower, single-frequency linewidth compared to conventional fiber lasers. Tunable, narrow laser sources with output in an eye-safe spectrum are desired for sensing, signal multiplexing, LIDAR systems, quantum applications, etc. In this work, we present DFFL obtained using laser-powder-deposition made Er-doped silica fiber. Milliwatt level, narrow line lasing (<704 kHz, equipment limited) was obtained using a phase-shifted grating written in 16 mm long fiber. The backward slope efficiency was as high as 24% when pumping at 976 nm. The results presented in this work showcase new possibilities in fiber fabrication that were unlocked through laser-assisted additive manufacturing. This fiber laser sets the stage for the future of rapid fabrication of advanced fiber devices through unconventional manufacturing routes.
2378-0967
Maniewski, Pawel
fb31e508-188a-4034-a236-dd0a473874d0
Flint, Alex I.
2314a288-92bc-44ca-9627-350eac1a7e26
Bannerman, Rex H.S.
a6b58fe0-006c-4564-8a14-9a325d9e5757
Lee, Timothy
7a3d744e-344c-49b6-998e-5dabcd8f2f3a
Beresna, Martynas
a6dc062e-93c6-46a5-aeb3-8de332cdec7b
Maniewski, Pawel
fb31e508-188a-4034-a236-dd0a473874d0
Flint, Alex I.
2314a288-92bc-44ca-9627-350eac1a7e26
Bannerman, Rex H.S.
a6b58fe0-006c-4564-8a14-9a325d9e5757
Lee, Timothy
7a3d744e-344c-49b6-998e-5dabcd8f2f3a
Beresna, Martynas
a6dc062e-93c6-46a5-aeb3-8de332cdec7b

Maniewski, Pawel, Flint, Alex I., Bannerman, Rex H.S., Lee, Timothy and Beresna, Martynas (2024) Tunable kHz distributed feedback fiber laser fabricated in 3D-printed glass. APL Photonics, 9 (11), [111301]. (doi:10.1063/5.0232419).

Record type: Letter

Abstract

For short sections of fiber tailored to a specific application, fast laser-based manufacturing techniques can be considered as an attractive alternative to the often-cumbersome traditional manufacturing routes. With the use of high-power lasers, localized hot zones that are necessary for glass making can be obtained rapidly. For instance, laser-powder-deposition enables rapid fabrication of short, high gain fibers used in, e.g., distributed feedback fiber lasers (DFFLs). DFFLs offer sought after performance suitable for a broad range of applications in modern photonics, i.e., superior stability and narrower, single-frequency linewidth compared to conventional fiber lasers. Tunable, narrow laser sources with output in an eye-safe spectrum are desired for sensing, signal multiplexing, LIDAR systems, quantum applications, etc. In this work, we present DFFL obtained using laser-powder-deposition made Er-doped silica fiber. Milliwatt level, narrow line lasing (<704 kHz, equipment limited) was obtained using a phase-shifted grating written in 16 mm long fiber. The backward slope efficiency was as high as 24% when pumping at 976 nm. The results presented in this work showcase new possibilities in fiber fabrication that were unlocked through laser-assisted additive manufacturing. This fiber laser sets the stage for the future of rapid fabrication of advanced fiber devices through unconventional manufacturing routes.

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111301_1_5.0232419 - Version of Record
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Accepted/In Press date: 14 October 2024
Published date: 1 November 2024
Learn more about the Zepler Institute for Photonics and Nanoelectronics Learn more about the Optoelectronics Research Centre

Identifiers

Local EPrints ID: 509330
URI: http://eprints.soton.ac.uk/id/eprint/509330
DOI: doi:10.1063/5.0232419
ISSN: 2378-0967
PURE UUID: 2da45c64-d70c-449d-98dd-0645710dc4ce
ORCID for Pawel Maniewski: ORCID iD orcid.org/0000-0003-0137-260X
ORCID for Alex I. Flint: ORCID iD orcid.org/0000-0001-5103-0419

Catalogue record

Date deposited: 19 Feb 2026 17:31
Last modified: 20 Feb 2026 03:12

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Contributors

Author: Pawel Maniewski ORCID iD
Author: Alex I. Flint ORCID iD
Author: Rex H.S. Bannerman
Author: Timothy Lee
Author: Martynas Beresna

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