Enhancing excited-state lifetimes in Er3+-doped silica glass through controlled heat exposure
Enhancing excited-state lifetimes in Er3+-doped silica glass through controlled heat exposure
Optimization of rare-earth (RE) doped devices for laser applications necessitates a combination of precision material engineering and advanced performance enhancement strategies. This study presents a novel investigation, to our knowledge, into cluster dynamics in Er-doped glass, utilizing localized CO2 laser heating to simulate the high-temperature conditions typical of glass fabrication processes. Our findings demonstrate that, by a controlled heat exposure, it is possible to influence clustering in Er-doped glass. Minimized clustering leads to a significant improvement in material properties and ultimately device performance. Specifically, we achieved up to 25% increase in the radiative lifetime associated with the 4I13/2 → 4I15/2 radiative transition by exposing samples to elevated temperatures for several minutes. This rapid thermal treatment minimizes dopant mobility in sintered silica glass, thereby reducing cluster formation and improving the homogeneity of the active medium. These results provide a feasible pathway for enhancing the performance of erbium-based optical devices, including lasers and signal amplifiers, and underscore the potential of thermal processing as a versatile tool in photonic material optimization.
Wörmann, Tim Julian
551fa41d-6971-4287-93a5-85866d8f5637
Brunzell, Martin
197ad955-0962-4e80-804a-0b220443b999
Pasiskevicius, Valdas
1a3665b3-07de-4d9b-83d8-7676592e8923
Maniewski, Pawel
fb31e508-188a-4034-a236-dd0a473874d0
3 June 2025
Wörmann, Tim Julian
551fa41d-6971-4287-93a5-85866d8f5637
Brunzell, Martin
197ad955-0962-4e80-804a-0b220443b999
Pasiskevicius, Valdas
1a3665b3-07de-4d9b-83d8-7676592e8923
Maniewski, Pawel
fb31e508-188a-4034-a236-dd0a473874d0
Wörmann, Tim Julian, Brunzell, Martin, Pasiskevicius, Valdas and Maniewski, Pawel
(2025)
Enhancing excited-state lifetimes in Er3+-doped silica glass through controlled heat exposure.
Optics Letters, 50 (12).
(doi:10.1364/OL.562095).
Abstract
Optimization of rare-earth (RE) doped devices for laser applications necessitates a combination of precision material engineering and advanced performance enhancement strategies. This study presents a novel investigation, to our knowledge, into cluster dynamics in Er-doped glass, utilizing localized CO2 laser heating to simulate the high-temperature conditions typical of glass fabrication processes. Our findings demonstrate that, by a controlled heat exposure, it is possible to influence clustering in Er-doped glass. Minimized clustering leads to a significant improvement in material properties and ultimately device performance. Specifically, we achieved up to 25% increase in the radiative lifetime associated with the 4I13/2 → 4I15/2 radiative transition by exposing samples to elevated temperatures for several minutes. This rapid thermal treatment minimizes dopant mobility in sintered silica glass, thereby reducing cluster formation and improving the homogeneity of the active medium. These results provide a feasible pathway for enhancing the performance of erbium-based optical devices, including lasers and signal amplifiers, and underscore the potential of thermal processing as a versatile tool in photonic material optimization.
Text
ol-50-12-3848
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Accepted/In Press date: 19 May 2025
Published date: 3 June 2025
Identifiers
Local EPrints ID: 510087
URI: http://eprints.soton.ac.uk/id/eprint/510087
ISSN: 0146-9592
PURE UUID: c402a733-b06a-481b-af2d-179a57c2aa37
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Date deposited: 17 Mar 2026 17:38
Last modified: 19 Mar 2026 03:15
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Contributors
Author:
Tim Julian Wörmann
Author:
Martin Brunzell
Author:
Valdas Pasiskevicius
Author:
Pawel Maniewski
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