Modeling mid-infrared fiber laser systems

R. I. Woodward, M. Gorjan: Modeling mid-infrared fiber laser systems. In: Jackson, S. D.; Bernier, M.; Vallee, R. (Ed.): Chapter 13, Woodhead Publishing, 2022, ISBN: 978-0-12-818017-4.

Abstract

Mid-IR fibre lasers are complex nonlinear dynamical systems, involving interplay between many physical phenomena and offering vast design freedom. The development of numerical models to simulate laser behaviour is therefore an invaluable tool, both to optimize output performance and to advance understanding of novel laser transitions. Such insight would be significantly slower and more costly to obtain (or indeed, impossible) through laboratory experimentation alone. In this Chapter, we offer a general introduction to various topics in mid-IR fibre laser modelling, with a particular emphasis on rate equation simulations. Complete formalisms are developed from first principles, notably using a matrix approach which is well suited for complex mid-IR transitions, and we discuss practical solution strategies. Case studies are presented for CW, Q-switched and gain-switched lasers, considering both the dysprosium and erbium ion. The second part of the Chapter then considers thermal modelling to identify cooling strategies for high-power systems and ultrashort pulse simulations for modelling mode-locked lasers.

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BibTeX (Download)

@inbook{Woodward2022,
title = {Modeling mid-infrared fiber laser systems},
author = {R. I. Woodward and M. Gorjan},
editor = {S. D. Jackson and M. Bernier and R. Vallee},
url = {https://riwoodward.com/publication_files/woodward_2022_mirmodel.pdf},
doi = {10.1016/B978-0-12-818017-4.00003-3},
isbn = {978-0-12-818017-4},
year  = {2022},
date = {2022-01-14},
urldate = {2022-01-14},
publisher = {Woodhead Publishing},
chapter = {13},
abstract = {Mid-IR fibre lasers are complex nonlinear dynamical systems, involving interplay between many physical phenomena and offering vast design freedom. The development of numerical models to simulate laser behaviour is therefore an invaluable tool, both to optimize output performance and to advance understanding of novel laser transitions. Such insight would be significantly slower and more costly to obtain (or indeed, impossible) through laboratory experimentation alone. In this Chapter, we offer a general introduction to various topics in mid-IR fibre laser modelling, with a particular emphasis on rate equation simulations. Complete formalisms are developed from first principles, notably using a matrix approach which is well suited for complex mid-IR transitions, and we discuss practical solution strategies. Case studies are presented for CW, Q-switched and gain-switched lasers, considering both the dysprosium and erbium ion. The second part of the Chapter then considers thermal modelling to identify cooling strategies for high-power systems and ultrashort pulse simulations for modelling mode-locked lasers.},
keywords = {},
pubstate = {published},
tppubtype = {inbook}
}