Overview
- Editors:
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J. Berakdar
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Max-Planck Institute for Microstructure Physics, Halle, Germany
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J. Kirschner
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Max-Planck Institute for Microstructure Physics, Halle, Germany
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Table of contents (40 chapters)
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Coincidence Studies on Atoms and Ions I: Single Ionization/Excitation Processes
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- Andrew Murray, Frank Read
Pages 3-14
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- S. Mazevet, J. Berakdar, J. Lower, E. Weigold
Pages 15-25
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- D. O. Odero, J. L. Peacher, D. H. Madison
Pages 27-43
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- L. U. Ancarani, P. A. Hervieux
Pages 45-56
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- Yu. V. Popov, L. U. Ancarani
Pages 57-69
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- Vladimir L. Shablov, Victor A. Bilyk, Yuri V. Popov
Pages 71-80
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- Peter J. P. Roche, Satoyuki Kawano, Colm T. Whelan, J. Rasch, H. R. J. Walters, R. J. Allan et al.
Pages 81-90
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- Marco Kampp, Colm T Whelan, N C Pyper, H R J Walters, R M Dreizler, H-J Ast et al.
Pages 91-98
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- U Lechner, S Keller, H J Lüdde, E Engel, R M Dreizler
Pages 99-111
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- S. Mazevet, G. Nguyen Vien, J. Langlois, R. J. Tweed, O. Robaux, C. Tannous et al.
Pages 113-125
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- Matthew A. Haynes, Birgit Lohmann
Pages 127-134
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- Norbert Scherer, Volker Schmidt
Pages 135-148
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- B. Paripás, G. Vitéz, Gy. VÃkor, K. Tõkési
Pages 149-161
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- P. Bolognesi, S. J. Cavanagh, L. Avaldi, R. Camilloni, G. Dawber, M. C. A. Lopes et al.
Pages 163-172
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- W. R. Cravero, M. D. Sanchez, G. Gasaneo, F. D. Colavecchia, C. R. Garibotti
Pages 189-201
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Coincidence Studies on Atoms and Ions II: Multiple Ionization/Excitation Processes
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Front Matter
Pages 213-213
About this book
Since the early days of modem physics spectroscopic techniques have been employed as a powerful tool to assess existing theoretical models and to uncover novel phenomena that promote the development of new concepts. Conventionally, the system to be probed is prepared in a well-defined state. Upon a controlled perturbation one measures then the spectrum of a single particle (electron, photon, etc.) emitted from the probe. The analysis of this single particle spectrum yields a wealth of important information on the properties of the system, such as optical and magnetic behaviour. Therefore, such analysis is nowadays a standard tool to investigate and characterize a variety of materials. However, it was clear at a very early stage that real physical compounds consist of many coupled particles that may be excited simultaneously in response to an external perturbation. Yet, the simultaneous (coincident) detection of two or more excited species proved to be a serious technical obstacle, in particular for extended electronic systems such as surfaces. In recent years, however, coincidence techniques have progressed so far as to image the multi-particle excitation spectrum in an impressive detail. Correspondingly, many-body theoretical concepts have been put forward to interpret the experimental findings and to direct future experimental research. This book gives a snapshot of the present status of multi-particle coincidence studies both from a theoretical and an experimental point of view. It also includes selected topical review articles that highlight the achievements and the power of coincident techniques.