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Nuclear Spectroscopy and Reactions, Part A covers information regarding the development of nuclear spectroscopy and its reactions, while emphasizing in-beam spectroscopy. This part specifically covers concerns regarding accelerators, specialized auxiliary equipment, and measurement techniques for charged particles and gamma rays. Organized into three major sections, this book first discusses accelerators in low- and intermediate-energy nuclear physics, and then covers electrostatic accelerators, cyclotron, and specialized accelerators. The second section covers polarized beam and targets, as well as on-line mass separations. The last section discusses the measurement of charged particle and gamma ray spectra including the detection of semiconductor radiation, large Nal, and charged particles. This book is written to primarily benefit graduate students who are engaged in research that concerns nuclear spectroscopy.
Nuclear Spectroscopy and Reactions, Part B covers information regarding the development of nuclear spectroscopy and its reactions, while emphasizing in-beam spectroscopy. This part specifically covers charged particle spectroscopy, spectroscopy from meson-induced reactions, and neutron spectroscopy. Organized into three sections, this book first discusses charged particle spectroscopy, which includes resonance reaction, reactions involving light ions, heavy-ion-induced reaction, and specialized reaction. The next section reviews spectroscopy from meson-induced reactions, including muonic and hadronic atoms; radiative capture; and charge exchange, scattering, and direct reactions. The final section discusses neutron spectroscopy, which includes advances in measurement of neutron spectra, charge exchange reactions, and polarization phenomena. This book is written to primarily benefit graduate students who are engaged in research that concerns nuclear spectroscopy.
Nuclei and nuclear reactions offer a unique setting for investigating three (and in some cases even all four) of the fundamental forces in nature. Nuclei have been shown – mainly by performing scattering experiments with electrons, muons and neutrinos – to be extended objects with complex internal structures: constituent quarks; gluons, whose exchange binds the quarks together; sea-quarks, the ubiquitous virtual quark-antiquark pairs and last but not least, clouds of virtual mesons, surrounding an inner nuclear region, their exchange being the source of the nucleon-nucleon interaction. The interplay between the (mostly attractive) hadronic nucleon-nucleon interaction and the repulsive Coulomb force is responsible for the existence of nuclei; their degree of stability, expressed in the details and limits of the chart of nuclides; their rich structure and the variety of their interactions. Despite the impressive successes of the classical nuclear models and of ab-initio approaches, there is clearly no end in sight for either theoretical or experimental developments as shown e.g. by the recent need to introduce more sophisticated three-body interactions to account for an improved picture of nuclear structure and reactions. Yet, it turns out that the internal structure of the nucleons has comparatively little influence on the behavior of the nucleons in nuclei and nuclear physics – especially nuclear structure and reactions – is thus a field of science in its own right, without much recourse to subnuclear degrees of freedom. This book collects essential material that was presented in the form of lectures notes in nuclear physics courses for graduate students at the University of Cologne. It follows the course's approach, conveying the subject matter by combining experimental facts and experimental methods and tools with basic theoretical knowledge. Emphasis is placed on the importance of spin and orbital angular momentum (leading e.g. to applications in energy research, such as fusion with polarized nuclei) and on the operational definition of observables in nuclear physics. The end-of-chapter problems serve above all to elucidate and detail physical ideas that could not be presented in full detail in the main text. Readers are assumed to have a working knowledge of quantum mechanics and a basic grasp of both non-relativistic and relativistic kinematics; the latter in particular is a prerequisite for interpreting nuclear reactions and the connections to particle and high-energy physics.
Alpha-, Beta- and Gamma-Ray Spectroscopy Volume 1 offers a comprehensive account of radioactivity and related low-energy phenomena. It summarizes progress in the field of alpha-, beta- and gamma-ray spectroscopy, including the discovery of the non-conservation of parity, as well as new experimental methods that elucidate the processes of weak interactions in general and beta-decay in particular. Comprised of 14 chapters, the book presents experimental methods and theoretical discussions and calculations to maintain the link between experiment and theory. It begins with a discussion of the interaction of electrons and alpha particles with matter. The book explains the elastic scattering of electrons by atomic nuclei and the interaction between gamma-radiation and matter. It then introduces topic on beta-ray spectrometer theory and design and crystal diffraction spectroscopy of nuclear gamma rays. Moreover, the book discusses the applications of the scintillation counter; proportional counting in gases; and the general processes and procedures used in determining disintegration schemes through a study of the beta- and gamma-rays emitted. In addition, it covers the nuclear shell model; collective nuclear motion and the unified model; and alpha-decay conservation laws. The emissions of gamma-radiation during charged particle bombardment and from fission fragments, as well as the neutron-capture radiation spectroscopy, are also explained. Experimentalists will find this book extremely useful.
Describes how the processes in stars which produce the chemical elements for planets and life may be reproduced in laboratories.
Nuclear Spectroscopy and Reactions, Part C covers information regarding the development of nuclear spectroscopy and its reactions, while emphasizing in-beam spectroscopy. This part covers gamma-ray spectroscopy and other relevant topics that are not discussed in the previous parts. Comprised of only two sections, this book first covers topics relevant to gamma-ray spectroscopy, such as the excitation and reorientation of coulombs; magnetic moments of excited fields; gamma rays from capture reactions; spectroscopy from fission; angular correlation methods; and lifetime measurements. The second section covers other topics that are relevant to nuclear spectroscopy, such as photonuclear reactions; nuclear spectroscopy from delayed particle emission; in-beam atomic spectroscopy; effects of extranuclear fields on nuclear radiations; and a guide to nuclear compilations. This book is written to primarily benefit graduate students who are engaged in research that concerns nuclear spectroscopy.
This book introduces graduate students to the gamma-ray and conversion-electron spectroscopic methods, which have shed new light on nuclear structure and reaction mechanisms. The simplicity and familiarity of the electromagnetic interaction involved gives accurate values for many nuclear quantities, and both static and dynamic properties can be investigated over a wide range of excitation energies. More experienced nuclear physicists will benefit by the book's review of recent developments in the field, including the development of new experimental techniques such as gamma-detector assemblies, electron spectrometers, and measurements of electromagnetic moments. The book is distinguished by a careful balance between the presentation of theoretical concepts and experimental methods.
Direct Nuclear Reactions deals with the theory of direct nuclear reactions, their microscopic aspects, and their effect on the motions of the individual nucleons. The principal results of the theory are described, with emphasis on the approximations involved to understand how well the theory can be expected to hold under specific experimental conditions. Applications to the analysis of experiments are also considered. This book consists of 19 chapters and begins by explaining the difference between direct and compound nuclear reactions. The reader is then introduced to the theory of plane waves, some results of scattering theory, and the phenomenological optical potential. The following chapters focus on form factors and their nuclear structure content; the basis of the optical potential as an effective interaction; reactions such as inelastic single- and two-nucleon transfer reactions; the effect of nuclear correlations; and the role of multiple-step reactions. The theory of inelastic scattering and the relationship between the effective and free interactions are also discussed, along with reactions between heavy ions and the polarizability of nuclear wave functions during a heavy-ion reaction. This monograph will be of interest to nuclear physicists.