Bose-Einstein Condensation of Excitons and Biexcitons
And Coherent Nonlinear Optics with Excitons

The first book to provide a comprehensive survey, covering theoretical aspects as well as recent experimental work.

S. A. Moskalenko (Author), D. W. Snoke (Author)

9780521022354, Cambridge University Press

Paperback / softback, published 10 November 2005

432 pages, 111 b/w illus. 4 tables
24.5 x 17 x 2.1 cm, 0.685 kg

"...a most useful text by two physicists each of whom has made substantial contributions to the field of Bose-Einstein condensation...a thorough introduction to all aspects of condensed matter physics, combined with much of the formal theory required to understand a wide range of experiments...Any scientist interested in establishing a more constructive dialogue with the science and technology studies community would be well-advised to read [this work]." Physics Today

Bose-Einstein condensation of excitons is a unique effect in which the electronic states of a solid can self-organize to acquire quantum phase coherence. The phenomenon is closely linked to Bose-Einstein condensation in other systems such as liquid helium and laser-cooled atomic gases. This is the first book to provide a comprehensive survey of this field, covering theoretical aspects as well as recent experimental work. After setting out the relevant basic physics of excitons, the authors discuss exciton-phonon interactions as well as the behaviour of biexcitons. They cover exciton phase transitions and give particular attention to nonlinear optical effects including the optical Stark effect and chaos in excitonic systems. The thermodynamics of equilibrium, quasi-equilibrium, and nonequilibrium systems are examined in detail. The authors interweave theoretical and experimental results throughout the book, and it will be of great interest to graduate students and researchers in semiconductor and superconductor physics, quantum optics, and atomic physics.

1. Introduction
2. Basic theory
3. Interaction with phonons
4. Biexcitons
5. Phase transitions of excitons
6. The optical Stark effect
7. Mixed states of excitons and photons
8. Nonequilibrium kinetics
9. Coherent nonlinear optics
10. New directions
Appendix.

Subject Areas: Condensed matter physics [liquid state & solid state physics PHFC]