Quantum Radiation in Ultra-Intense Laser Pulses, Softcover reprint of the original 1st ed. 2014 Springer Theses Series

Scientific advances and several technical breakthroughs have led to a remarkable increase in available laser intensities over the past decades. In available ultra-intense laser fields, photon fluxes may become so high that free charge carriers interact coherently with several of the field's photons. In this thesis such nonlinear interactions are investigated for the prime example of radiation emission by electrons scattered from intense laser pulses of arbitrary temporal structure. To this end, nonlinear quantum field theory is employed taking the interaction with the laser into account exactly. After an in-depth introduction to classical particle dynamics as well as quantum field theory in nonlinearly intense laser fields the emission of one and two photons is explicitly analyzed. The results are then translated to viable technical applications, such as a scheme for the determination of the carrier-envelope phase of ultra-intense laser pulses and a proposal for detecting the strongly suppressed two-photon signal.

Interaction of Electrons with Laser Fields.- Nonlinear Single Compton Scattering.- Nonlinear Double Compton Scattering.- Numerical Integration of Strongly Oscillating Functions.

The author began his physics studies at the University of Constance in 2003, where in 2004/05 he was elected as student member of the Physics faculty council. After the intermediate examination in 2005 he moved to Heidelberg University, where he held several positions as research assistant in the University's Institute for Environmental Physics and the Interdisciplinary Center for Scientific Computing. In 2007 he completed a six-month industrial internship at the BASF AG. In 2009 he was awarded his Physics diploma from Heidelberg University and started his PhD project at the Max Planck Institute for Nuclear Physics.

Nominated as an outstanding Ph.D. thesis by Max Planck Institute for Nuclear Physics, Heidelberg Provides unprecedented insights into quantum dynamics of free charge carriers in intense laser fields Introduces nonlinear QED leading reader to forefront of quantum field theory Develops a powerful stationary phase method applicable to the analysis of any type of photon emission from an electron in an intense laser pulse Includes supplementary material: sn.pub/extras