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6 - Principles of Fibre Amplifiers and Lasers for Near-IR Spectroscopy

Published online by Cambridge University Press:  07 April 2021

George Stewart
George Stewart
Affiliation:
University of Strathclyde
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Summary

The fundamental principles which govern the operation and define the characteristics of rare earth-doped fibre amplifiers and lasers are discussed in detail.The important role of phonon interactions with the Stark energy levels of the 4f electron orbitals is explained and the McCumber relationship for the absorption and emission cross-sections is derived. Atomic and cavity rate equations for fibre amplifiers and lasers are derived from first principles, including the contributions from spontaneous and amplified spontaneous emission. The rate equations are used to model fibre lasers under the various conditions of operation that relate to possible applications in near-IR gas spectroscopy, such as for tuneable or multi-wavelength sources, frequency combs and intra-cavity laser absorption spectroscopy.Examples are given of the theoretical laser output when operating under steady-state, multi-wavelength, transient or mode-locked regimes.The principles of stimulated Raman scattering are also discussed for accessing near-IR absorption lines at longer wavelengths by extending, through the Stokes shift, the available wavelength range of operation with fibre amplifiers or lasers.

Keywords

Erbium-doped fibrephononsStark levelsemission cross-sectionMcCumber relationshipcavity-rate equationatomic-rate equationlaser transientsmode-lockingRaman laser
Type
Chapter
Information
Laser and Fiber Optic Gas Absorption Spectroscopy , pp. 159 - 197
Publisher: Cambridge University Press
Print publication year: 2021

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