Quantum well devices for mode-locking fibre lasers
Quantum well devices for mode-locking fibre lasers
The generation of picosecond duration pulses in the 1.55 micron wavelength region is of considerable interest for applications related to telecommunications. In the 1.06 micron region, picosecond pulses are useful for spectroscopy and the electro-optic sampling of high speed integrated circuits [I]. Passive mode-locking of fibre lasers using multiple quantum well (MQW) material can provide optical pulses with picosecond durations in both these wavelength regions. The optical confinement and long lengths available, give doped fibre lasers high gain together with flexibility in physical configuration. The use of QWs with light incident perpendicular to the epitaxial layers, as passive saturable absorbers to mode-lock these lasers, is attractive because of their polarisation insensitivity and the wide range of wavelengths available. The semiconductor sample operating wavelength is governed by the materials, their compositions and dimensions used. In fibre, gain is provided in the 1.55 micron region by doping with Erbium whilst Neodymium is used for operation in the 1.06 micron region.
By integrating the saturable absorber and laser-cavity end mirror into a single semiconductor device we have generated picosecond pulses in very simple cavity configurations.
Atkinson, D.
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Loh, W.H.
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Hopkinson, M.
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Grey, R.
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Seeds, A.J.
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Morkel, P.R.
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Payne, D.N.
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Atkinson, D.
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Loh, W.H.
ad865cd3-2580-4afa-8607-1c1d30cf8312
Hopkinson, M.
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Grey, R.
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Seeds, A.J.
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Morkel, P.R.
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Payne, D.N.
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Atkinson, D., Loh, W.H., Hopkinson, M., Grey, R., Seeds, A.J., Morkel, P.R. and Payne, D.N.
(1993)
Quantum well devices for mode-locking fibre lasers.
IEE Colloquium on Applications of Quantum Well Technologies, London, United Kingdom.
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Conference or Workshop Item
(Paper)
Abstract
The generation of picosecond duration pulses in the 1.55 micron wavelength region is of considerable interest for applications related to telecommunications. In the 1.06 micron region, picosecond pulses are useful for spectroscopy and the electro-optic sampling of high speed integrated circuits [I]. Passive mode-locking of fibre lasers using multiple quantum well (MQW) material can provide optical pulses with picosecond durations in both these wavelength regions. The optical confinement and long lengths available, give doped fibre lasers high gain together with flexibility in physical configuration. The use of QWs with light incident perpendicular to the epitaxial layers, as passive saturable absorbers to mode-lock these lasers, is attractive because of their polarisation insensitivity and the wide range of wavelengths available. The semiconductor sample operating wavelength is governed by the materials, their compositions and dimensions used. In fibre, gain is provided in the 1.55 micron region by doping with Erbium whilst Neodymium is used for operation in the 1.06 micron region.
By integrating the saturable absorber and laser-cavity end mirror into a single semiconductor device we have generated picosecond pulses in very simple cavity configurations.
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e-pub ahead of print date: 5 March 1993
Venue - Dates:
IEE Colloquium on Applications of Quantum Well Technologies, London, United Kingdom, 1993-03-05
Identifiers
Local EPrints ID: 77229
URI: http://eprints.soton.ac.uk/id/eprint/77229
PURE UUID: 5aee7138-89f0-4335-9ba9-b1f119c3198e
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Date deposited: 11 Mar 2010
Last modified: 13 Mar 2024 23:46
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Contributors
Author:
D. Atkinson
Author:
W.H. Loh
Author:
M. Hopkinson
Author:
R. Grey
Author:
A.J. Seeds
Author:
P.R. Morkel
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