Abstract
Abstract In this report we review the experimental and theoretical developments concerning the elementary process of electron bremsstrahlung. The term “elementary process” means that not only the emitted bremsstrahlung photons are considered but also the partinent decelerated electrons. Experimentally the elementary process is observed by detecting the photons in coincidence with outgoing electrons scattered into a particular direction. The results of such electron-photon coincidence experiments yield stringent tests for theoretical predictions of the fully differential cross section. Much deeper insight into the bremsstrahlung process is achieved by also taking into account polarization variables such as the spin orientation of the incoming electron or the polarization of the emitted photon. Thus conspicuous effects of the weak spin-orbit interaction can be observed which are usually masked in non-coincidence experiments. Bremsstrahlung is produced not only in the Coulomb field of an atomic nucleus but also in a collision between an incoming electron and an atomic electron which then is ejected. By using the electron-phonon coincidence technique it is possible to differentiate exactly between electron-electron bremsstrahlung and electron-nucleus bremsstrahlung. All coincidence experiments done for studying the elementary bremsstrahlung process have been performed in the energy region of a few hundred keV. In the MeV to GeV region the coincidence method is mainly used to test radiative corrections from quantum electrodynamics or to obtain “monochromatic” tagged photon beams for further applications.
Published Version
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