Laser-aided manufacturing of ultra-high-aspect ratio optical fibers
Laser-aided manufacturing of ultra-high-aspect ratio optical fibers
The current landscape of optical fiber technology is dominated by fibers with a circular cross-section with axial symmetry and a centrally positioned waveguiding core. This typical layout is dictated by traditional manufacturing routes that often utilize furnaces, gas burners, and glass lathes. Contrastingly, in our work, we utilize laser-based glass additive-manufacturing to melt, weld, and reshape glass powders and prefabricates to create fiber preforms. Additionally, through a combination of mid-IR CO2 laser melting and oxide nano-powder jets aimed into laser-induced hot-zone, high quality glass features can be 3D-printed onto the fiber preform. In our work we focus on high-aspect ratio preforms that can be then drawn in traditional draw towers into over 100 m long ultra-thin fibers. Here, flat fibers as thin as 35 µm and aspect-ratio of up to 27:1 with sub-µm surface flatness were made. Furthermore, by utilizing this novel print-stack-draw approach, microstructure and chemically doped features for e.g., waveguiding and optical gain can be spatially tailored, both laterally and along the direction of draw. Compatibility of these fibers with standard counterparts such as commercial single-mode-fibers was demonstrated through e.g., laser-based splicing. The new manufacturing approach utilized in this work unlocks highly flexible, novel photonic designs with large disruptive potential for areas including lab-in-fiber, physical sensors and fiber lasers.
flat fiber, glass 3d printing, laser manufacturing, optical fiber
Maniewski, P.
f1ddd84b-cd48-4e2f-a05e-b2f7dc042342
Moog, Bruno
fb647fef-2caa-44b3-8157-2b141f5d8cf5
Whitaker, Matthew
4db53e39-c212-4fbb-a630-a9a6bdfd5c3a
Holmes, Christopher
2ec659eb-2bd3-460a-aa8d-5538eb1aeb25
19 March 2025
Maniewski, P.
f1ddd84b-cd48-4e2f-a05e-b2f7dc042342
Moog, Bruno
fb647fef-2caa-44b3-8157-2b141f5d8cf5
Whitaker, Matthew
4db53e39-c212-4fbb-a630-a9a6bdfd5c3a
Holmes, Christopher
2ec659eb-2bd3-460a-aa8d-5538eb1aeb25
Maniewski, P., Moog, Bruno, Whitaker, Matthew and Holmes, Christopher
(2025)
Laser-aided manufacturing of ultra-high-aspect ratio optical fibers.
Kaierle, Stefan and Kleine, Klaus R.
(eds.)
In High-Power Laser Materials Processing: Applications, Diagnostics, and Systems XIV.
vol. 13356,
SPIE.
4 pp
.
(doi:10.1117/12.3043087).
Record type:
Conference or Workshop Item
(Paper)
Abstract
The current landscape of optical fiber technology is dominated by fibers with a circular cross-section with axial symmetry and a centrally positioned waveguiding core. This typical layout is dictated by traditional manufacturing routes that often utilize furnaces, gas burners, and glass lathes. Contrastingly, in our work, we utilize laser-based glass additive-manufacturing to melt, weld, and reshape glass powders and prefabricates to create fiber preforms. Additionally, through a combination of mid-IR CO2 laser melting and oxide nano-powder jets aimed into laser-induced hot-zone, high quality glass features can be 3D-printed onto the fiber preform. In our work we focus on high-aspect ratio preforms that can be then drawn in traditional draw towers into over 100 m long ultra-thin fibers. Here, flat fibers as thin as 35 µm and aspect-ratio of up to 27:1 with sub-µm surface flatness were made. Furthermore, by utilizing this novel print-stack-draw approach, microstructure and chemically doped features for e.g., waveguiding and optical gain can be spatially tailored, both laterally and along the direction of draw. Compatibility of these fibers with standard counterparts such as commercial single-mode-fibers was demonstrated through e.g., laser-based splicing. The new manufacturing approach utilized in this work unlocks highly flexible, novel photonic designs with large disruptive potential for areas including lab-in-fiber, physical sensors and fiber lasers.
Text
PhotonicsWest08012024
- Accepted Manuscript
Available under License Other.
Text
PhotonicsWest08012024
Available under License Other.
More information
Published date: 19 March 2025
Additional Information:
Publisher Copyright:
© 2025 SPIE.
Venue - Dates:
High-Power Laser Materials Processing: Applications, Diagnostics, and Systems XIV 2025, , San Francisco, United States, 2025-01-29 - 2025-01-31
Keywords:
flat fiber, glass 3d printing, laser manufacturing, optical fiber
Identifiers
Local EPrints ID: 502515
URI: http://eprints.soton.ac.uk/id/eprint/502515
ISSN: 0277-786X
PURE UUID: 56240fea-5c40-4308-b2a7-836d502ae7eb
Catalogue record
Date deposited: 27 Jun 2025 16:48
Last modified: 21 Aug 2025 04:38
Export record
Altmetrics
Contributors
Author:
P. Maniewski
Author:
Bruno Moog
Author:
Matthew Whitaker
Author:
Christopher Holmes
Editor:
Stefan Kaierle
Editor:
Klaus R. Kleine
Download statistics
Downloads from ePrints over the past year. Other digital versions may also be available to download e.g. from the publisher's website.
View more statistics