Diode-pumped Alexandrite laser with passive SESAM Q-switching and wavelength tunability
File(s)
Author(s)
Type
Journal Article
Abstract
We report the first experimental demonstration of a wavelength tunable passively Q-switched red-diode-end
pumped Alexandrite laser using a semiconductor saturable absorber mirror (SESAM). We present the results of
the study of passive SESAM Q-switching and wavelength-tuning in continuous diode-pumped Alexandrite
lasers in both linear cavity and X-cavity configurations. In the linear cavity configuration, pulsed operation up
to 27 kHz repetition rate in fundamental TEM00 mode was achieved and maximum average power was 41 mW.
The shortest pulse generated was 550 ns (FWHM) and the Q-switched wavelength tuning band spanned was
between 740 nm and 755 nm. In the X-cavity configuration, a higher average power up to 73 mW, and obtained
with higher pulse energy 6.5 J at 11.2 kHz repetition rate, in fundamental TEM00 mode with excellent spatial
quality M2 < 1.1. The Q-switched wavelength tuning band spanned was between 775 nm and 781 nm.
pumped Alexandrite laser using a semiconductor saturable absorber mirror (SESAM). We present the results of
the study of passive SESAM Q-switching and wavelength-tuning in continuous diode-pumped Alexandrite
lasers in both linear cavity and X-cavity configurations. In the linear cavity configuration, pulsed operation up
to 27 kHz repetition rate in fundamental TEM00 mode was achieved and maximum average power was 41 mW.
The shortest pulse generated was 550 ns (FWHM) and the Q-switched wavelength tuning band spanned was
between 740 nm and 755 nm. In the X-cavity configuration, a higher average power up to 73 mW, and obtained
with higher pulse energy 6.5 J at 11.2 kHz repetition rate, in fundamental TEM00 mode with excellent spatial
quality M2 < 1.1. The Q-switched wavelength tuning band spanned was between 775 nm and 781 nm.
Date Issued
2017-10-04
Date Acceptance
2017-09-13
Citation
Optics Communications, 2017, 410, pp.970-976
ISSN
0030-4018
Publisher
Elsevier
Start Page
970
End Page
976
Journal / Book Title
Optics Communications
Volume
410
Copyright Statement
© 2017, Elsevier. Licensed under the Creative Commons Attribution-NonCommercial-NoDerivatives 4.0 International http://creativecommons.org/licenses/by-nc-nd/4.0/
Sponsor
British Council (UK)
Innovate UK
Grant Number
215277462
EP/R00420X/1
Subjects
0205 Optical Physics
0906 Electrical And Electronic Engineering
Optoelectronics & Photonics
Publication Status
Published