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Quenching dynamics in highly doped erbium fiber core-pumping, amplifier configuration

Quenching dynamics in highly doped erbium fiber core-pumping, amplifier configuration
Quenching dynamics in highly doped erbium fiber core-pumping, amplifier configuration
This study examines the influence of quenching dynamics on the efficiency of erbium-doped fiber amplifiers (EDFAs) with high erbium-ion (E3+-ions) doping concentrations, comparing pulsed and continuous wave core-pumping methods. Our findings indicate that quenching, driven by energy transfer upconversion, substantially impacts signal gain in these fibers. The core-pumping configuration demonstrated significantly higher gain per unit length than both low-doping EDFAs and cladding-pumping systems, with effective energy storage achievable through short pump pulses to reduce concentration quenching effects. The highly doped homemade fiber (fiber under test - FUT No. 3) achieved a gain per unit length exceeding 8.4 dB/m, outperforming the lower doped commercial fiber (FUT No. 4) by a factor of 6.4, although FUT No. 4 displayed better compatibility with the core-pumping system. Additionally, the highest gain per unit length for a counter-directional, cladding-pumped amplifier configuration with a high-concentration fiber was recorded at 5.9 dB/m at a 1560 nm signal wavelength with a 2 mu s pulse duration, positioning FUT No. 3 as a highly efficient option for high-gain applications despite its high doping concentration. Our experimental analysis of quenching dynamics not only highlights an approach for scaling pulse energy using shorter fiber lengths to mitigate nonlinear effects but also provides valuable insights into quenching-influenced gain behavior in pulsed fiber amplifier systems.
2158-3226
Hernandez, Pablo G. Rojas
0917a31d-ce16-4f07-8baa-c9c79c6f175d
Pidishety, Shankar
72c34e1b-b682-41eb-9ad8-d323008c81dc
Nilsson, Johan
f41d0948-4ca9-4b93-b44d-680ca0bf157b
Hernandez, Pablo G. Rojas
0917a31d-ce16-4f07-8baa-c9c79c6f175d
Pidishety, Shankar
72c34e1b-b682-41eb-9ad8-d323008c81dc
Nilsson, Johan
f41d0948-4ca9-4b93-b44d-680ca0bf157b

Hernandez, Pablo G. Rojas, Pidishety, Shankar and Nilsson, Johan (2025) Quenching dynamics in highly doped erbium fiber core-pumping, amplifier configuration. AIP Advances, 15 (1), [015213]. (doi:10.1063/5.0235468).

Record type: Article

Abstract

This study examines the influence of quenching dynamics on the efficiency of erbium-doped fiber amplifiers (EDFAs) with high erbium-ion (E3+-ions) doping concentrations, comparing pulsed and continuous wave core-pumping methods. Our findings indicate that quenching, driven by energy transfer upconversion, substantially impacts signal gain in these fibers. The core-pumping configuration demonstrated significantly higher gain per unit length than both low-doping EDFAs and cladding-pumping systems, with effective energy storage achievable through short pump pulses to reduce concentration quenching effects. The highly doped homemade fiber (fiber under test - FUT No. 3) achieved a gain per unit length exceeding 8.4 dB/m, outperforming the lower doped commercial fiber (FUT No. 4) by a factor of 6.4, although FUT No. 4 displayed better compatibility with the core-pumping system. Additionally, the highest gain per unit length for a counter-directional, cladding-pumped amplifier configuration with a high-concentration fiber was recorded at 5.9 dB/m at a 1560 nm signal wavelength with a 2 mu s pulse duration, positioning FUT No. 3 as a highly efficient option for high-gain applications despite its high doping concentration. Our experimental analysis of quenching dynamics not only highlights an approach for scaling pulse energy using shorter fiber lengths to mitigate nonlinear effects but also provides valuable insights into quenching-influenced gain behavior in pulsed fiber amplifier systems.

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015213_1_5.0235468 - Version of Record
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Accepted/In Press date: 11 December 2024
Published date: 10 January 2025
Learn more about Zepler Institute for Photonics and Nanoelectronics research

Identifiers

Local EPrints ID: 502822
URI: http://eprints.soton.ac.uk/id/eprint/502822
DOI: doi:10.1063/5.0235468
ISSN: 2158-3226
PURE UUID: 6abb75f5-84a7-44e1-abb5-7b86d13a903e
ORCID for Johan Nilsson: ORCID iD orcid.org/0000-0003-1691-7959

Catalogue record

Date deposited: 09 Jul 2025 16:30
Last modified: 22 Aug 2025 01:43

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Contributors

Author: Pablo G. Rojas Hernandez
Author: Shankar Pidishety
Author: Johan Nilsson ORCID iD

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