Optically pumped planar waveguide lasers, part I: fundamentals and fabrication techniques
Optically pumped planar waveguide lasers, part I: fundamentals and fabrication techniques
The tremendous interest in the field of waveguide lasers in the past two decades is largely attributed to the geometry of the gain medium, which provides the possibility to store optical energy on a very small dimension in the form of an optical mode. This allows for realization of sources with enhanced optical gain, low lasing threshold, and small footprint and opens up exciting possibilities in the area of integrated optics by facilitating their on-chip integration with different functionalities and highly compact photonic circuits. Moreover, this geometrical concept is compatible with high-power diode pumping schemes as it provides exceptional thermal management, minimizing the impact of thermal loading on laser performance. The proliferation of techniques for fabrication and processing capable of producing high optical quality waveguides has greatly contributed to the growth of waveguide lasers from a topic of fundamental research to an area that encompasses a variety of practical applications. In this first part of the review on optically pumped waveguide lasers the properties that distinguish these sources from other classes of lasers will be discussed. Furthermore, the current state-of-the art in terms of fabrication tools used for producing waveguide lasers is reviewed from the aspects of the processes and the materials involved.
solid-state lasers, waveguides, channeled, slab, thin film deposition and fabrication, materials micro-and nanofabrication and processing, integrated optics devices
159-239
Grivas, Christos
7f564818-0ac0-4127-82a7-22e87ac35f1a
November 2011
Grivas, Christos
7f564818-0ac0-4127-82a7-22e87ac35f1a
Grivas, Christos
(2011)
Optically pumped planar waveguide lasers, part I: fundamentals and fabrication techniques.
Progress in Quantum Electronics, 35 (6), .
(doi:10.1016/j.pquantelec.2011.05.002).
Abstract
The tremendous interest in the field of waveguide lasers in the past two decades is largely attributed to the geometry of the gain medium, which provides the possibility to store optical energy on a very small dimension in the form of an optical mode. This allows for realization of sources with enhanced optical gain, low lasing threshold, and small footprint and opens up exciting possibilities in the area of integrated optics by facilitating their on-chip integration with different functionalities and highly compact photonic circuits. Moreover, this geometrical concept is compatible with high-power diode pumping schemes as it provides exceptional thermal management, minimizing the impact of thermal loading on laser performance. The proliferation of techniques for fabrication and processing capable of producing high optical quality waveguides has greatly contributed to the growth of waveguide lasers from a topic of fundamental research to an area that encompasses a variety of practical applications. In this first part of the review on optically pumped waveguide lasers the properties that distinguish these sources from other classes of lasers will be discussed. Furthermore, the current state-of-the art in terms of fabrication tools used for producing waveguide lasers is reviewed from the aspects of the processes and the materials involved.
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e-pub ahead of print date: June 2011
Published date: November 2011
Keywords:
solid-state lasers, waveguides, channeled, slab, thin film deposition and fabrication, materials micro-and nanofabrication and processing, integrated optics devices
Organisations:
Optoelectronics Research Centre
Identifiers
Local EPrints ID: 201069
URI: http://eprints.soton.ac.uk/id/eprint/201069
ISSN: 0079-6727
PURE UUID: a186ad3a-88a6-4eb5-9f16-ec097c4e8e8d
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Date deposited: 28 Oct 2011 07:34
Last modified: 14 Mar 2024 04:21
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Author:
Christos Grivas
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