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This book was written by a group of authors and provides a systematic dis cussion of questions related to bremsstrahlung in many-particle systems. A number of new results have recently been obtained in this area which require a fundamental revision of the previously existing traditional concepts of bremsstrahlung. This ap plies both to complicated atoms containing a large number of electrons and to the additional bremsstrahlung in a system of many particles forming a medium. In fact, the traditional approach was rigorously applicable only either to isolated "structureless" particles (e. g. , to the emission of an electron on a proton) or to par ticles radiating in the limit of extremely high frequencies. Polarization effects (either polarization of an atom itself by an incident particle or polarization of the medium surrounding an atomic particle) have a significant effect in the practically important optical and x-ray frequency ranges and sometimes even predominate. The first effect has come to be known as polarization atomic (or dynamic) bremsstrahlung and the second, as polarization transition bremsstrahlung. The au thors of this book use a single term: polarization bremsstrahlung. It seems that, in contrast to earlier ideas on the subject, bremsstrahlung during collisions of heavy incident particles with atoms is by no means small and is entirely caused by polar ization effects.
This book introduces and reviews both theory and applications of polarizational bremsstrahlung, i.e. the electromagnetic radiation emitted during collisions of charged particles with structured, thus polarizable targets, such as atoms, molecules and clusters. The subject, following the first experimental evidence a few decades ago, has gained importance through a number of modern applications. Thus, the study of several radiative mechanisms is expected to lead to the design of novel light sources, operating in various parts of the electromagnetic spectrum. Conversely, the analysis of the spectral and angular distribution of the photon emission constitutes a new tool for extracting information on the interaction of the colliding particles, and on their internal structure and dynamical properties. Last but not least, accurate quantitative descriptions of the photon emission processes determine the radiative energy losses of particles in various media, thereby providing essential information required for e.g. plasma diagnostics as well as astrophysical and medical applications (such as radiation therapy). This book primarily addresses graduate students and researchers with a background in atomic, molecular, optical or plasma physics, but will also be of benefit to anyone wishing to enter the field.
Ch. 1. Introduction. 1.1. General introduction. 1.2. Short historical note. 1.3. Notations and definitions -- ch. 2. Classical and semiclassical considerations on the bremsstrahlung process. 2.1. Electron-nucleus bremsstrahlung. 2.2. Electron-electron bremsstrahlung. 2.3. Weizsäcker-Williams method of virtual quanta -- ch. 3. Theory of the elementary process of electron-nucleus bremsstrahlung. 3.1. Introduction. 3.2. Bremsstrahlung cross section. 3.3. Born approximation (Bethe-Heitler formula). 3.4. Approximations with the Sommerfeld-Maue wave function. 3.5. Calculation using relativistic partial-wave expansions. 3.6. Spin-dependent cross section and bremsstrahlung asymmetry. 3.7. Bremsstrahlung polarization. 3.8. Radiative corrections to bremsstrahlung -- ch. 4. Experiments on the elementary process of electron-nucleus bremsstrahlung. 4.1. Survey of experimental devices. 4.2. Electron-photon coincidence experiments without regard to polarization variables. 4.3. Electron-photon coincidence experiments including polarization variables. 4.4. Tagged photons -- ch. 5. Theory of the elementary process of electron-electron bremsstrahlung. 5.1. Introduction. 5.2. Kinematics. 5.3. Cross section. 5.4. Bremsstrahlung in the field of bound electrons -- ch. 6. Experiments on the elementary process of electron-electron bremsstrahlung. 6.1. Electron-photon coincidence experiments without regard to polarization variables. 6.2. Electron-photon coincidence experiments including polarization variables -- ch. 7. Some remarks on integrated cross sections and further bremsstrahlung processes. 7.1. Integrated cross sections. 7.2. Positron-nucleus bremsstrahlung. 7.3. Electron-positron bremsstrahlung. 7.4. Two-photon bremsstrahlung. 7.5. Polarization bremsstrahlung. 7.6. Crystalline targets: coherent bremsstrahlung. 7.7. Bremsstrahlung from heavy particles. 7.8. Bremsstrahlung in nuclear decays. 7.9. Bremsstrahlung in magnetic fields. 7.10. Stimulated bremsstrahlung
The rapid growth of the subject since the first edition ten years ago has made it necessary to rewrite the greater part of the book. Except for the introductory portion and the section on Mott scattering, the book has been completely revised. In Chap. 3, sections on polarization violating reflection symmetry, on resonance scattering, and on inelastic processes have been added. Chapter 4 has been rewritten, taking account of the numerous novel results obtained in exchange scattering. Chapter 5 includes the recent discoveries on photoelectron polarization produced by unpolarized radiation with unpolarized targets and on Auger-electron polarization. In Chap. 6, a further discussion of relativistic polarization phenomena has been added to the book. The immense growth of polarization studies with solids and surfaces required an extension and new presentation of Chap. 7. All but one section of Chap. 8 has been rewritten and a detailed treatment of polarization analysis has been included. Again, a nearly comprehensive treatment has been attempted. Even so, substantial selectivity among the wide range of available material has been essential in order to accomplish a compact presentation. The reference list, selected along the same lines as in the first edition, is meant to lead the reader through the literature giving a guide for finding further references. I want to express my indebtedness to a number of people whose help has been invaluable.
This book deals with the theory and experiment of the elementary process of bremsstrahlung, where photons are detected in coincidence with decelerated outgoing electrons. Such experiments allow for a more stringent check of the theoretical work. The main emphasis is laid on electron-atom bremsstrahlung and electron-electron bremsstrahlung, but further bremsstrahlung processes are also dealt with. In the theoretical parts, triply differential cross sections are derived in various approximations, including electron spin and photon-polarization. In the experimental sections, electron-photon coincidence experiments are discussed. These are done partly with transversely polarized electron beams and partly with detectors for the bremsstrahlung linear polarization.
A comprehensive survey of recent theoretical and experimental progress in the area of electron-photon interaction and dense media. A state-of-the-art discussion of radiation production, with descriptions of new ideas and technologies that enhance the production of X-rays in the form of channelling, transition and parametric X-ray production. Progress in electron beam physics to produce sub-picosecond electron bunches from low-energy linear accelerators make it possible to produce coherent, high brightness, submillimeter radiation and sub-picosecond X-ray pulses. Micro-undulators in the form of bent crystalline structures hold great promise as future X-ray sources.
This book deals with diffraction radiation, which implies the boundary problems of electromagnetic radiation theory. Diffraction radiation is generated when a charged particle moves near a target edge at a distance ( – Lorentz factor, – wave length). Diffraction radiation of non-relativistic particles is widely used to design intense emitters in the cm wavelength range. Diffraction radiation from relativistic charged particles is important for noninvasive beam diagnostics and design of free electron lasers based on Smith-Purcell radiation which is diffraction radiation from periodic structures. Different analytical models of diffraction radiation and results of recent experimental studies are presented in this book. The book may also serve as guide to classical electrodynamics applications in beam physics and electrodynamics. It can be of great use for young researchers to develop skills and for experienced scientists to obtain new results.