Fundamentals of Photon Physics

<p>The photon an abstract concept belonging to a global vacuum only manifests itself during</p><p>interaction with matter. Fundamentals of Photon Physics describes the richly faceted basic theory</p><p>of photon-matter interaction selecting a wide number of topics. Together with the author’s book</p><p>Light -- The Physics of the Photon (CRC 2014) both written on a scholarly level the reader is</p><p>given a comprehensive exposition of photon wave mechanics quantum optics and quantum</p><p>electrodynamics (QED).</p><p>Divided into 10 parts the book begins by exploring the relation between photon wave mechanics</p><p>and quantum field theory. It then describes the theories of zero- and one-photon states and</p><p>that of bi-photons. After discussing conservation laws Lagrangian formulations geometric</p><p>phase and topology the author turns towards the theory of photon scattering emphasizing a</p><p>density matrix operator approach and the role of microscopic extinction theorems. The book</p><p>next focuses on mesoscopic QED devoting particular attention to collective jellium excitations</p><p>and photon-spin interactions. Special attention is given to the basics of the photon-magnon</p><p>interaction and nonlinear superconductor electrodynamics including the nonlinear Meissner</p><p>rectification phenomenon before studying the theory of transverse photons tied to (dressing)</p><p>massive particles.</p><p>The last three parts take the reader on a journey to topics usually not treated in books on photon-</p><p>matter interaction. Beginning with photons in curved space-time structures and in spatially</p><p>curved media e.g. Möbius bands the author discusses the extension of QED to the electro-weak</p><p>interaction at an introductory level. Fundamentals of Photon Physics ends with the establishment</p><p>of the set of isovector Maxwell equations in non-Abelian SO(3) gauge theory leading to</p><p>the celebrated hedgehog monopole model.</p><p><b>Ole Keller</b> is professor emeritus of theoretical physics at Aalborg University Denmark. He earned his Licentiate (∼ PhD) degree in semiconductor physics from the Danish Technical University in Copenhagen in 1972 and the Doctor of Science degree from the University of Aarhus (1996). In 1989 he was appointed as the first professor in physics at Aalborg University by Margrethe Den Anden queen of Denmark. The same year he was admitted to Kraks Blaa Bog a prestigious Danish biographical dictionary which (citatum) ”Includes men and women whose life story could have an interest for a wider public”. He is a fellow of the Optical Society of America.</p><p>He has written the books entitled Quantum Theory of Near-Field Electrodynamics (Springer 2011) and LIGHT - The Physics of the Photon (CRC 2014) as well as the monographs Local Fields in the Electrodynamics of Mesoscopic Media (Physics Reports 1996) and On the Theory of Spatial Localization of Photons (Physics Reports 2005). He is the editor of the books Nonlinear Optics in Solids (Springer 1990) Studies in Classical and Quantum Nonlinear Optics (Nova Science 1995) and Notions and Perspectives of Nonlinear Optics (World Scientific 1996).</p><p>In recent years he has carried out theoretical research in fundamental photon physics microscopic few-photon diffraction mesoscopic and Möbius band electrodynamics and studied magnetic monopole theory based on QED and the isovector Maxwell equations in non-Abelian gauge symmetry.</p>