1. Introduction1.1. Why study fission?1.2. The discovery of fission1.3. The role of women in the development of the field 1.4. Early model of fission: the Bohr and Wheeler paper1.5. Structure of the book
2. Fission Systematics and General Characteristics2.1. Spontaneous and induced fission2.2. Chronology of the fission process2.3. Fission energetics2.4. Fission barriers2.5. Fission isomers2.6. Fragment mass and energy distributions2.7. Neutron distributions
3. Fission Models3.1. The liquid drop model3.2. The Strutinsky shell correction method3.3. Energy surfaces3.4. Transition state theory3.5.
4.1. Mass and charge distributions4.2. Kinetic energy distribution4.3. Angular momentum of fragments4.4. Angular distribution of fragments4.5. Decay of fragments: the Bateman equation
5. Fission Neutrons5.1. Scission and post-scission neutrons5.2. Prompt and delayed neutrons5.3. Neutron yield5.4. Neutron spectrum
6. Fission Gammas6.1. Prompt and delayed gammas6.2. Fission product yields from gamma-ray measurements6.3. Fragment angular momentum deduced from gammas6.4. Average gamma-ray energies and multiplicities6.5. Shape of the gamma-ray spectrum
7. Advanced Topics7.1. The Hartree-Fock approximation7.2. The treatment of pairing in the BCS approximation7.3. Constrained Hartree-Fock+BCS and energy surfaces7.4. The Generator Coordinate Method7.5. Fission dynamics: Semi-classical methods7.6. Fission dynamics: Quantum-mechanical methods7.7. The nucleus at and beyond scission7.8. Future directions in fission theory and experiments

About the Author: Walid Younes received his Ph.D. in nuclear physics from Rutgers University in 1996, and joined the experimental nuclear physics group at the Lawrence Livermore National Laboratory soon after. For the next ten years, he worked principally on the measurement and interpretation of fission cross sections from neutron-induced reactions. In 2006, he made the transition to nuclear theory, studying the quantum many-body problem and its application to describe the nuclear fission process. In addition to numerous publications and presentations on the physics of fission, Dr. Younes co-authored Microscopic Theory of Nuclear Fission in Springer's "Lecture Notes in Physics" series in 2019. He has lectured in summer schools and in the nuclear engineering department at the University of California Berkeley on nuclear physics and fission, where he designed and taught a full-semester course on the physics of fission. Dr. Younes retired from LLNL in 2019, but maintains an active interest in understanding the fission process through measurements and modelling.

Walter D. Loveland is Professor at the department of Chemistry of the Oregon State University, US. He received his PhD in Nuclear Chemistry from the University of Washington after obtaining the SB in Chemistry from MIT. He held postdoctoral positions in Argonne and Oregon State Universities, becoming a faculty member at Oregon State University in 1968. He spent some periods at LBNL, Uppsala, and Argonne as visiting scientist. Prof. Loveland has worked on various aspects of nuclear chemistry, such as the study of heavy ion induced reactions, fast neutron induced fission, environmental chemistry and nuclear chemistry education. He is the author of several nuclear chemistry textbooks. He has published more than 250 scientific articles in the open, refereed literature, given 62 talks at APS meetings, and over 300 talks at professional meetings. He is NSF Sigma Xi (Washington), Tartar, ACS, and AAAS fellow. He was awarded the Sigma Xi Award for Research, Gillfillan award, Beaver Champion Award (Oregon State), and G.T. Seaborg Award.