Supernovae, neutron star physics and nucleosynthesis

This book deals with the interdisciplinary areas of nuclear physics, supernovae and neutron star physics. It addresses the physics and astrophysics of the spectacular supernova explosions, starting with the collapse of massive stars and ending with the birth of neutron stars or black holes. Recent progress in the understanding of core collapse supernova (CCSN) and observational aspects of future detections of neutrinos from CCSN explosions are discussed. The other main focus in this text is the novel phases of dense nuclear matter, its compositions and equation of state (EoS) from low to very high baryon density relevant to supernovae and neutron stars. The multi-messenger astrophysics of binary neutron star merger GW170817 and its relation to EoS through tidal deformability are also presented in detail. The synthesis of elements heavier than iron in the supernova and neutron star environment by the rapid (r)-process are treated here with special emphasis on the nucleosynthesis in the ejected material from GW170817. This monograph is written for graduate students and researchers in the field of nuclear astrophysics.

PREFACE1. INTRODUCTION 2. THEORY OF SUPERNOVA EXPLOSIONS 2.1 Overview- historical 2.2 Supernova Type Ia 2.3 Gravitational collapse and pre-supernova conditions 2.4 Production of neutrinos and their emission 2.5 Shock wave formation and its eventual stalling 2.6 The revival of the shock wave- the neutrino mechanism 2.7 Multi-dimensional hydrodynamic simulations and the present scenario 2.8 The supernova SN1987A 2.9 Detection of neutrinos from future supernova events 3. NEUTRON STARS 3.1 History and discovery of neutron stars 3.2 Observational Constraints on neutron stars 3.3 Compositions and novel phases of neutron stars - crust to core 3.4 Equation of State (EoS) models of neutron star matter 3.5 Relativistic field theoretical models for dense matter at zero and finite temperatures 3.6 Tolman-Oppenheimer-Volkoff Equation and Structures of neutron stars 3.7 A stable branch of compact stars beyond neutron star 3.8 Rotating neutron stars, moment of inertia (I) and quadrupole moment (Q) 3.9 Neutron star matter in strongly quantizing magnetic fields 3.10 EoS tables for supernova and binary neutron star merger simulations 4. BINARY NEUTRON STAR MERGERS 4.1 Gravitational waves as new window into neutron stars 4.2 First binary neutron star (BNS) merger GW170817 and multi-messenger astrophysics 4.3 Tidal deformability, LOVE number and EoS 4.4 I-Love-Q universal relations 4.5 Late inspiral phase of BNS merger, tidal deformability and cold EoS 4.6 Neutron Star radius determination from tidal deformability 4.7 Hot and neutrino trapped merger remnant and finite temperature EoS 5. SYNTHESIS OF HEAVY ELEMENTS IN THE UNIVERSE 5.1 s-, r- and p-processes 5.2 Conditions for production of elements by r- process and the sites 5.3 Electromagnetic counterpart of GW170817 and ejected matter in BNS merger 5.4 Decompression of ejected neutron rich matter in Lattimer and Schramm model 5.5 Kilonova model 5.6 Heavy element synthesis in neutron rich matter ejected in GW170817 INDEX BIBLIOGRAPHY (eventually at chapter-ends)