Book contents
- Frontmatter
- Contents
- Preface
- List of abbreviations
- Part I Basic tools
- Part II Driven laser systems
- Part III Particular laser systems
- 8 Laser with a saturable absorber
- 9 Optically injected semiconductor lasers
- 10 Delayed feedback dynamics
- 11 Far-infrared lasers
- 12 Optical parametric oscillator
- References
- Index
8 - Laser with a saturable absorber
from Part III - Particular laser systems
Published online by Cambridge University Press: 06 August 2010
- Frontmatter
- Contents
- Preface
- List of abbreviations
- Part I Basic tools
- Part II Driven laser systems
- Part III Particular laser systems
- 8 Laser with a saturable absorber
- 9 Optically injected semiconductor lasers
- 10 Delayed feedback dynamics
- 11 Far-infrared lasers
- 12 Optical parametric oscillator
- References
- Index
Summary
In a laser with a saturable absorber (LSA), two spatially separated cells are placed in the laser cavity as shown in Figure 8.1. The roles of the two cells are quite different: one of them is pumped so that the atoms have a positive population inversion (active or amplifying medium); the other one is left with a negative population inversion (passive or absorbing medium). As these two media are in general different, they saturate at different power levels. The most interesting case corresponds to the situation where the absorber saturates more easily than the active medium, introducing nonlinear losses inside the cavity. This new nonlinearity is responsible for two phenomena. An LSA may exhibit optical bistability, i.e. two distinct stable steady states may coexist for a range of values of a parameter. It may also produce pulsating intensity oscillations which have been called “passive Q-switching” (PQS) in contrast to “active Q-switching” experiments such as the “gain switching” experiments discussed in Section 1.3.2.
The interest in LSAs varied very much over time, with peaks in the late 1960s for their large intensity pulses, in the mid 1980s for their chaotic outputs, and in the late 1990s for the design of compact microlasers. Historically, physicists trying to explain the irregular intensity pulses delivered by the ruby laser suspected the possible destabilizing role of a saturable absorber. Shimoda proposed that the nonlinear losses generated by a saturable absorber could explain this phenomenon.
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- Information
- Laser Dynamics , pp. 175 - 212Publisher: Cambridge University PressPrint publication year: 2010