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Optimizing a 1.9 μm mode-locked laser by controlling the concentration of reduced graphene oxide-magnesium oxide

In this work, a pulsed laser was achieved through mode -locking in a Thulium/Holmium co-doped fiber laser (THDFL) utilizing a saturable absorber (SA) made of reduced graphene oxide/magnesium oxide (rGO/MgO) composite. The composite material was first synthesized using a simple hydrothermal method wi...

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Main Authors: Ahmad, Harith, Loganathan, Kirubhashni, Yusoff, Norazriena, Samion, Muhamad Zharif
Format: Article
Published: Elsevier 2024
Subjects:
QC Physics
Online Access:http://eprints.um.edu.my/45644/
https://doi.org/10.1016/j.optmat.2024.114993
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spelling my.um.eprints.456442024-11-06T09:10:12Z http://eprints.um.edu.my/45644/ Optimizing a 1.9 μm mode-locked laser by controlling the concentration of reduced graphene oxide-magnesium oxide Ahmad, Harith Loganathan, Kirubhashni Yusoff, Norazriena Samion, Muhamad Zharif QC Physics In this work, a pulsed laser was achieved through mode -locking in a Thulium/Holmium co-doped fiber laser (THDFL) utilizing a saturable absorber (SA) made of reduced graphene oxide/magnesium oxide (rGO/MgO) composite. The composite material was first synthesized using a simple hydrothermal method with graphene oxide and magnesium chloride as the precursor for rGO and MgO, respectively. Pulsed fiber laser sources have extensive applications in a diverse array of material diagnostics, encompassing the examination of semiconductor materials employed in telecommunications components, as well as the analysis of biomedical phenomena. The influence of SA concentration on its performance and its impact on pulse generation due to nonlinear interactions were explored. The results demonstrated that the 5 mg/mL rGO/MgO SA exhibited a modulation depth of 46.32 %, while the 10 mg/mL rGO/MgO SA had a value of 51.93 %. As the rGO/MgO concentrations increased from 5 mg/mL to 10 mg/mL, the central wavelength of the stable mode -locking experienced a blueshift from 1907 nm to 1902 nm. Notably, the 10 mg/mL rGO/MgO-based SA outperformed the 5 mg/mL counterpart in various aspects, including signal-to-noise ratio (SNR), pulse duration, average power, pulse energy, peak power, and efficiency. This investigation sheds light on the critical role of SA concentration in optimizing the performance of modelocked THDFL, providing valuable insights for the development of advanced ultrafast laser sources for diverse applications. Elsevier 2024-03 Article PeerReviewed Ahmad, Harith and Loganathan, Kirubhashni and Yusoff, Norazriena and Samion, Muhamad Zharif (2024) Optimizing a 1.9 μm mode-locked laser by controlling the concentration of reduced graphene oxide-magnesium oxide. Optical Materials, 149. p. 114993. ISSN 0925-3467, DOI https://doi.org/10.1016/j.optmat.2024.114993 <https://doi.org/10.1016/j.optmat.2024.114993>. https://doi.org/10.1016/j.optmat.2024.114993 10.1016/j.optmat.2024.114993
institution Universiti Malaya
building UM Library
collection Institutional Repository
continent Asia
country Malaysia
content_provider Universiti Malaya
content_source UM Research Repository
url_provider http://eprints.um.edu.my/
topic QC Physics
spellingShingle QC Physics
Ahmad, Harith
Loganathan, Kirubhashni
Yusoff, Norazriena
Samion, Muhamad Zharif
Optimizing a 1.9 μm mode-locked laser by controlling the concentration of reduced graphene oxide-magnesium oxide
description In this work, a pulsed laser was achieved through mode -locking in a Thulium/Holmium co-doped fiber laser (THDFL) utilizing a saturable absorber (SA) made of reduced graphene oxide/magnesium oxide (rGO/MgO) composite. The composite material was first synthesized using a simple hydrothermal method with graphene oxide and magnesium chloride as the precursor for rGO and MgO, respectively. Pulsed fiber laser sources have extensive applications in a diverse array of material diagnostics, encompassing the examination of semiconductor materials employed in telecommunications components, as well as the analysis of biomedical phenomena. The influence of SA concentration on its performance and its impact on pulse generation due to nonlinear interactions were explored. The results demonstrated that the 5 mg/mL rGO/MgO SA exhibited a modulation depth of 46.32 %, while the 10 mg/mL rGO/MgO SA had a value of 51.93 %. As the rGO/MgO concentrations increased from 5 mg/mL to 10 mg/mL, the central wavelength of the stable mode -locking experienced a blueshift from 1907 nm to 1902 nm. Notably, the 10 mg/mL rGO/MgO-based SA outperformed the 5 mg/mL counterpart in various aspects, including signal-to-noise ratio (SNR), pulse duration, average power, pulse energy, peak power, and efficiency. This investigation sheds light on the critical role of SA concentration in optimizing the performance of modelocked THDFL, providing valuable insights for the development of advanced ultrafast laser sources for diverse applications.
format Article
author Ahmad, Harith
Loganathan, Kirubhashni
Yusoff, Norazriena
Samion, Muhamad Zharif
author_facet Ahmad, Harith
Loganathan, Kirubhashni
Yusoff, Norazriena
Samion, Muhamad Zharif
author_sort Ahmad, Harith
title Optimizing a 1.9 μm mode-locked laser by controlling the concentration of reduced graphene oxide-magnesium oxide
title_short Optimizing a 1.9 μm mode-locked laser by controlling the concentration of reduced graphene oxide-magnesium oxide
title_full Optimizing a 1.9 μm mode-locked laser by controlling the concentration of reduced graphene oxide-magnesium oxide
title_fullStr Optimizing a 1.9 μm mode-locked laser by controlling the concentration of reduced graphene oxide-magnesium oxide
title_full_unstemmed Optimizing a 1.9 μm mode-locked laser by controlling the concentration of reduced graphene oxide-magnesium oxide
title_sort optimizing a 1.9 μm mode-locked laser by controlling the concentration of reduced graphene oxide-magnesium oxide
publisher Elsevier
publishDate 2024
url http://eprints.um.edu.my/45644/
https://doi.org/10.1016/j.optmat.2024.114993
_version_ 1816130432023920640
score 13.214268

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