Das Energiespektrum der Elektronen beim Betazerfall war lange Zeit umstritten. 1914 fand Chadwick Hinweise auf ein kontinuierliches Energiespektrum, doch seine Ergebnisse wurden nicht allgemein anerkannt. Chadwick und Ellis lernten einander in einem deutschen Internierungslager wahrend des 1. Weltkriegs kennen. Ellis gelang im Jahre 1927 der endgultige Beweis fur das kontinuierliche Spektrum. Damit war der Weg frei fur Paulis Neutrino-Hypothese und fur die Fermi-Theorie der schwachen Wechselwirkung. In Streuexperimenten mit Alphateilchen fanden Rutherford, Chadwick und andere ab 1920 Hinweise auf eine bis dahin unbekannte Kernkraft, die wir heute als starke Wechselwirkung bezeichnen. Die Entdeckung des Neutrons durch Chadwick im Jahre 1932 war ein entscheidender Beitrag zum Verstandnis beider Kernkrafte. Die Biografien der beiden Physiker werden beleuchtet.

This book provides an introduction to the current state of our knowledge about the structure of matter. Gerhard Ecker describes the development of modern physics from the beginning of the quantum age to the standard model of particle physics, the fundamental theory of interactions of the microcosm. The focus lies on the most important discoveries and developments, e.g. of quantum field theory, gauge theories and the future of particle physics. The author also emphasizes the interplay between theory and experiment, which helps us to explore the deepest mysteries of nature. "Particles, Fields, Quanta" is written for everyone who enjoys physics. It offers high school graduates and students of physics in the first semesters an encouragement to understand physics more deeply. Teachers and others interested in physics will find useful insights into the world of particle physics. For advanced students, the book can serve as a comprehensive preparation for lectures on particle physics and quantum field theory. A brief outline of the mathematical structures, an index of persons with research focuses and a glossary for quick reference of important terms such as gauge theory, spin and symmetry complete the book. From the foreword by Michael Springer: "The great successes and the many open questions this book describes illustrate how immensely complicated nature is and nevertheless how much we already understand of it." The author Gerhard Ecker studied theoretical physics with Walter Thirring at the University of Vienna. His research focus has been on theoretical particle physics, in particular during several long-term visits at CERN, the European Organisation for Nuclear Research in Geneva. In 1986 he was promoted to Professor of Theoretical Physics at the University of Vienna. Since 1977 he has given both basic lectures in theoretical physics and advanced courses on different topics in particle physics, e.g., quantum field theory, symmetry groups in particle physics and renormalisation in quantum field theory.

Einleitung.- Physik um 1900.- Der Weg zur Quantenmechanik.- Warum Quantenfeldtheorie.- Die Krise der Quantenfeldtheorie.- Vom Beta-Zerfall zur elektroschwachen Eichtheorie.- Quantenchromodynamik: Quantenfeldtheorie der starken Kernkraft.- Standardmodell der fundamentalen Wechselwirkungen.- Jenseits des Standardmodells?.- Ausblick.- Mathematische Strukturen, Einheiten und Notation.- Eich-und Lorentz-Invarianz.- Personenregister.- Glossar.- Index.