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Charged-Particle Reaction List 1948-1971 is a guide to experiments on charged-particle-induced reactions that have been reported in journal literature during the period 1948 to June 1971. This compendium consists of the material from four Reaction Lists which have already appeared in Nuclear Data Tables. Each published article is listed under the target nuclei in the nuclear reactions which it treats. Reactions are denoted by A(a,b)B, where A and B are the target and residual nucleus, respectively; a is the bombarding charged particle and b is the outgoing product particle or particles. The guide also includes a brief information after the reaction designation, namely, the energy E of the bombarding projectile in MeV, a short statement of the type of data that is found in the paper, and a bibliographic information on the paper itself. A symbol THY in the extreme right-hand column denotes the theoretical papers concerned with analysis of nuclear reaction data. For papers dealing with experimental data on energy spectra, the angle of observation of the emerging reaction products, the accelerator, as well as the detector used are given for many entries under the column heading "Quantity Measured." The guide will prove immensely useful for theoretical physicists, nuclear physicists, and molecular physicists.
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.
Advances in Nuclear Science and Technology, Volume 8 discusses the development of nuclear power in several countries throughout the world. This book discusses the world's largest program of land-based electricity production in the United States. Organized into six chapters, this volume begins with an overview of the phenomenon of quasi-exponential behavior by examining two mathematical models of the neutron field. This text then discusses the finite element method, which is a method for obtaining approximate solutions to integral or differential equations. Other chapters consider the status of the accuracy of nuclear data used for reactor calculations and the target accuracies required by reactor physics. This book discusses as well the role of integral experiments for the improvement of nuclear data and the different approaches taken to enhance them. The final chapter deals with the manufacture and application of coated particles. This book is a valuable resource for reactor physicists, engineers, scientists, and research workers.
Atomic and Nuclear Data Reprints, Volume 1: Internal Conversion Coefficients: For Multipolarities E1,. . ., E4, M1,. . ., M4 covers a complete set of values for the internal conversion coefficients. This volume provides a compact tool for the analysis of nuclear radiations. This book contains four chapters and starts with a presentation of values of the internal conversion coefficient, number of electrons per photon emitted in a nuclear transition, from relativistic self-consistent-field calculation, which takes into account finite nuclear size, hole and exchange effects, experimental electron binding energies, and vacuum polarization. The next two chapters provide the conversion coefficients for the four lowest electric and magnetic nuclear transition multipoles, E1 . . . E4, M1 . . . M4, for electrons in the K- , L - , and M-shells and L-, M-, and N-subshells as a function of nuclear-transition or gamma-ray energy. The last chapter presents the K- and L-shell internal conversion coefficients for transition energies above 1 MeV.