Synopses & Reviews
One of the most profound revolutions brought about by quantum mechanics is that it does away with the distinction between waves and particles: atoms, in particular, can exhibit all the properties that we associate with wave phenomena, such as diffraction and interference; it has recently even become possible to prepare collections of atoms in coherent states, like those of photons in a laser beam. These developments are at the core of the rapidly expanding field of atom optics. ||Atom Optics gradually leads the reader from elementary concepts to the frontiers of the field. It is organized in three parts, linear, nonlinear, and quantum atom optics. After a review of light forces on atoms and of laser cooling, the first part discusses the application of light forces to atom optical elements such as gratings, mirrors and lenses, matter-wave diffraction, and atomic traps and resonators. The discussion of nonlinear atom optics starts with a review of collisions from a viewpoint that clearly demonstrates its profound analogy with nonlinear optics. The last part, quantum atom optics, first recalls key results of many-body theory in a formulation geared specifically toward atom optics. This is followed by a discussion of atomic Bose-Einstein condensation and "atom lasers." The final chapters treat such applications as atomic solitons, four-wave mixing, superradiance, and conclude with the coherent amplification of matter waves. ||An online web component to the book, a gateway to atom optics, contains links to the leading references and journals in the field, to research sites, and to updates for the contents of the book. FROM THE REVIEWS: ¿Atom optics today has reached maturity: It has become both wave (coherent) and nonlinear atom optics. Of course that expansion required generalization in a new book. Pierre Meystre has taken just such a generalist approach in his timely ATOM OPTICS. His were the pioneering works in atom optics; to get information from the first explorer is always most valuable to the reader ¿ Recommend[ed] to all strata of the physics community.¿ ¿PHYSICS TODAY
Review
From the reviews: "The book is well laid out and elegantly written."-The Physicist "Atom optics today has reached maturity: It has become both wave (coherent) and nonlinear atom optics. Of course that expansion required generalization in a new book. Pierre Meystre has taken just such a generalist approach in his timely ATOM OPTICS. His were the pioneering works in atom optics; to get information from the first explorer is always most valuable to the reader ... Recommend[ed] to all strata of the physics community." -PHYSICS TODAY "Pierre Meystre has taken ... a generalist approach in his timely Atom Optics. His were the pioneering works in atom optics; to get information from the first explorer is always most valuable to the reader. ... The circle of potential readers of the book is very wide - from graduate students to professors ... . I therefore recommend it to all strata of the physics community." (Vladilen Letokhov, Physics Today, November, 2002) "Pierre Meystre is a theoretical physicist at the University of Arizona. His book entitled 'Atom Physics' is the first book published on the subject. ... This book is well laid out and elegantly written. I believe that this book, combined with Hal Metcalf's 'Laser Cooling and Trapping', forms an excellent introduction at a postgraduate level to atom optics." (A. G. Truscott, The Physicist, Vol. 39 (4), 2002)
Review
From the reviews:
"The book is well laid out and elegantly written."-The Physicist
"Atom optics today has reached maturity: It has become both wave (coherent) and nonlinear atom optics. Of course that expansion required generalization in a new book. Pierre Meystre has taken just such a generalist approach in his timely ATOM OPTICS. His were the pioneering works in atom optics; to get information from the first explorer is always most valuable to the reader ... Recommend[ed] to all strata of the physics community."
-PHYSICS TODAY
"Pierre Meystre has taken ... a generalist approach in his timely Atom Optics. His were the pioneering works in atom optics; to get information from the first explorer is always most valuable to the reader. ... The circle of potential readers of the book is very wide - from graduate students to professors ... . I therefore recommend it to all strata of the physics community." (Vladilen Letokhov, Physics Today, November, 2002)
"Pierre Meystre is a theoretical physicist at the University of Arizona. His book entitled 'Atom Physics' is the first book published on the subject. ... This book is well laid out and elegantly written. I believe that this book, combined with Hal Metcalf's 'Laser Cooling and Trapping', forms an excellent introduction at a postgraduate level to atom optics." (A. G. Truscott, The Physicist, Vol. 39 (4), 2002)
Synopsis
The is is the first book on the market on the rapidly developing topic of atom optics, i.e., the manipulation of atoms by light. This research has led to atom cooling and trapping (for which the 1998 Nobel Prize in physics was awarded), Bose-Einstein condensation, and holds great promise for revolutionary developments in the field of lasers.
Synopsis
Quantum mechanics does away with the distinction between particles and waves, and one of the more interesting implications of the wave/particle duality - the discovery that atoms may be manipulated in ways analogous to the manipulation of light with lenses and mirrors - has formed the basis for the relatively new field of atom optics. Pierre Meystre's Atom Optics is the first book entirely devoted to this exciting area of research. Reference links to the leading journals in the field, links to research sites, graphics, and updates can be found online.
Table of Contents
I. GENERAL CONCEPTS 1. Light forces on atoms 2. Atomic cooling II. LINEAR ATOM OPTICS 3. Atomic beam collimation and focusing 4. Atomic diffraction 5. Atomic traps and activities III. NONLINEAR ATOM OPTICS 6. Collisions 7. Simple applications IV. QUANTUM ATOM OPTICS 8. Review of manybody theory 9. Matter-wave coherence 10. Bose-Einstein condensation 11. Atom lasers 12. Nonlinear wave mixing 13. Mixing of optical and matter waves