Backscattering sources.
"Version: 20241101"--Title page verso.Includes bibliographical references.1. An introduction to high-intensity lasers and nonlinear quantum electrodynamics -- 1.1. Evolution of laser technology and the associated intensities -- 1.2. Going deeper into the fundamental role of the laser strength parameter -- 1.3. The phenomenology of the interaction between electrons/matter and a high-intensity laser -- 1.4. Sauter-Schwinger fields and associated phenomenology -- 1.5. Concluding comments -- 1.6. Comments and exercises2. Quantum electrodynamics and Feynman diagrams : an elementary exposition -- 2.1. Introduction -- 2.2. Dirac equation, antiparticles, and St?uckelberg-Dirac interpretation -- 2.3. A few useful identities for the calculation of quantum electrodynamic Feynman diagrams -- 2.4. Quantum electrodynamic Feynman diagrams -- 2.5. From diagrams to transition rates -- 2.6. Scattering processes and cross section -- 2.7. Comments and exercises3. Nonlinear quantum electrodynamics of Compton backscattering radiation -- 3.1. Introduction -- 3.2. Relativistic quantum electrodynamics of an electron in an intense plane wave -- 3.3. Linear Compton backscattering -- 3.4. Nonlinear Compton backscattering -- 3.5. Extremely nonlinear Compton backscattering regime -- 3.6. Spin-flip Compton backscattering radiation -- 3.7. Comments and exercises4. Advanced CBS sources -- 4.1. Generalities related to free-electron-laser-based Compton backscattering sources -- 4.2. Essentials of FEL oscillator dynamics -- 4.3. Design criteria of an FEL intracavity CBS device -- 4.4. Comments on FEL-CBS systems designed for high-energy photon beams -- 4.5. Two-color, two-polarization CBS sources -- 4.6. Comments and exercises.Full-text restricted to subscribers or individual document purchasers.The top-performing x-ray and gamma ray sources are synchrotrons and free-electron lasers, which require large investment. Consequently, more affordable and accessible platforms are required for research and applications based on x-rays and gamma rays. Compton backscattering (CBS) is a subset of Thomson and Compton scattering and is the mechanism through which high energy electrons interacting with low energy photons transfer part of their energy to the photons. Accordingly, an infrared photon can, for example, be 'transformed' into an x-ray or gamma ray, in a CBS process. Monochromatic and ultrashort x-ray and gamma ray sources are challenging to make; however, CBS provides a compact and accessible platform for this purpose.Aimed at those entering the field for the first time, this second volume focuses on CBS that produces intense gamma rays of higher energy than typical scattering processes. Theoretical problems between the high energy electrons and laser interactions are discussed, along with the possibility of exploring new effects in strong field quantum electrodynamics and how they can be observed. CBS 'factories' and their design characteristics are analysed and later chapters take a more detailed examination of CBS applications and the future of the field.Scientists and graduate and undergraduate students.Also available in print.Mode of access: World Wide Web.System requirements: Adobe Acrobat Reader, EPUB reader, or Kindle reader.Alessandro Curcio obtained a PhD at the School of Accelerator Physics at the University of Rome Sapienza, before winning a Research Fellowship at the CERN Linear Accelerator for Research. Afterwards, he joined the National Polish Synchrotron SOLARIS as Section Leader in beam diagnostics and instrumentation. Later, he was Senior Scientist at CLPU and, currently, he is Senior Scientist at the Italian National Institute for Nuclear Physics (INFN). His research interests have always been particle acceleration, innovative radiation sources and particle-matter interactions for applications. Giuseppe Dattoli is an ENEA Researcher and has been involved in different research projects, including high-energy accelerators, free electron lasers, and applied mathematics networks since 1979. Dr Dattoli has taught in Italian and universities overseas and has received the FEL Prize Award for his outstanding achievements in the field. Emanuele Di Palma received the Laurea degree in mathematics from Sapienza University of Rome Italy, in 1996, a master's degree in 'Fusion Energy: Science and Engineering' from Tor Vergata University of Rome Italy, in 2013 and the PhD degree in 'Fusion Science and Engineering' from the University of Padova Italy, in 2018. His research interests are in the fields of physics and applications of intense electron beams, computer-aided design and development of CARM device for various novel application as in-space solar energy harvesting, in fusion energy for high-field Tokamaks and in biomedical applications to develop compact device for nuclear diagnostics.Title from PDF title page (viewed on December 13, 2024).
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1 online resource (various pagings) :illustrations (some color).
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English
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9780750359795
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539.758
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Alessandro Curcio, Giuseppe Dattoli, Emanuele Di Palma.
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