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The Physics of Intense Beams and Storage Rings
This cogent, contemporary work by two preeminent Russian accelerator physicists details the physical processes limiting or assisting the performance of intense beams in particle accelerators. The authors apply statistical methods to the physics of stored beams and describe in rigorous detail a wide range of beam physics problems. These range from single particle dynamics, through the theory of linear coherent oscillations and cooling techniques, to the kinetic effects in intense beams and nonlinear collective phenomena.
The Euroschool Lectures on Physics with Exotic Beams
This is the third volume in a series of Lecture Notes based on the highly succesful Euro Summer School on Exotic Beams. The aim of these notes is to provide a thorough introduction to radioactive ion-beam physics at the level of graduate students and young postdocs starting out in the field. Each volume covers a range of topics from nuclear theory to experiment and applications
Contemporary Health Physics: Problems and Solutions
Contemporary Health Physics offers a balanced presentation of all important concepts, calculations, and techniques essential to a full working knowledge of radiation exposure assessments. Not another dry presentation of the basic facts, calculations, and routines, it is specifically designed to help readers to learn, think, and respond like professionals in the field. Featuring a unique, real-world orientation and hundreds of worked examples presented within the context of various scenarios, it prepares readers for the rigors of performing quick, accurate radiation assessments in virtually any routine or emergency situation.
Basic Concepts and New Developments
This volume on black holes can be seen as a sequel to Physics of Black Holes, published by Kluwer Academic Publishers in 1989. The authors are recognised experts in their field, and have many years' experience in teaching courses on general relativity and black holes. The present work covers practically all aspects of black hole physics and its astrophysical applications. Among the topics treated in depth are: spacetime of stationary black holes, general theory of black holes, black hole perturbations, black hole numerics, black hole electrodynamics, black holes in unified theories of gravity, quantum black holes, final states of evaporating black holes and the information loss puzzle.
"Basic Semiconductor Physics"
This book presents a detailed description of the basic physics of semiconductors. All the important equations describing the properties of these materials are derived without the help of other textbooks. The reader is assumed to have only a basic command of mathematics and some elementary semiconductor physics. The text covers a wide range of important semiconductor phenomena, from the simple to the advanced. Examples include recent progress in semiconductor quantum structures such as two-dimensional electron-gas systems, ballistic transport, the quantum Hall effect, the Landauer formula, the Coulomb blockade and the single-electron transistor.
Physics of the Life Sciences
Originally developed for the author's course at Union College, this text is designed for life science students who need to understand the connections of fundamental physics to modern biology and medicine. Almost all areas of modern life sciences integrally involve physics in both experimental techniques and in basic understanding of structure and function. Physics of the Life Sciences is not a watered-down, algebra-based engineering physics book with sections on relevant biomedical topics added as an afterthought. This authoritative and engaging text, which is designed to be covered in a two-semester course, was written with a thoroughgoing commitment to the needs and interests of life science students.
Project Physics Text
Background The Project Physics Course is based on the ideas and research of a national curriculum development project that worked in three phases. First, the authors — a high school physics teacher, a university physicist, and a professor of science education — collaborated to lay out the main goals and topics of a new introductory physics course. They worked together from 1962 to 1964 with financial support from the Carnegie Corporation of New York, and the first version of the text was tried out in two schools with encouraging results.
we have focused our attention on the synergistic relationship between conceplualunderslanding and problem solving, which is a pedagogical issue that underlies all aspects of this course. We have added new features, refined areas in need of improvemcnt, and simplified the design of the book with a vic\I,' toward improving clarity. The many insights and suggestions provided by users of the seventh edition, as well as the work of physics-educltion researchers. have helped us immensely in our efforts.
Solid State Physics: Principles and Modern Applications
Intended for a two semester advanced undergraduate or graduate course in Solid State Physics, this treatment offers modern coverage of the theory and related experiments, including the group theoretical approach to band structures, Moessbauer recoil free fraction, semi-classical electron theory, magnetoconductivity, electron self-energy and Landau theory of Fermi liquid, and both quantum and fractional quantum Hall effects. Integrated throughout are developments from the newest semiconductor devices, e.g. space charge layers, quantum wells and superlattices. The first half includes all material usually covered in the introductory course, but in greater depth than most introductory textbooks. The second half includes most of the important developments in solid-state researches of the past half century, addressing e.g. optical and electronic properties such as collective bulk and surface modes and spectral function of a quasiparticle, which is a basic concept for understanding LEED intensities, X ray fine structure spectroscopy and photoemission. So both the fundamental principles and most recent advances in solid state physics are explained in a class-tested tutorial style, with end-of-chapter exercises for review and reinforcement of key concepts and calculations.
Nuclear Medicine Physics
Edited by a renowned international expert in the field, Nuclear Medicine Physics offers an up-to-date, state-of-the-art account of the physics behind the theoretical foundation and applications of nuclear medicine. It covers important physical aspects of the methods and instruments involved in modern nuclear medicine, along with related biological topics. The book first discusses the physics of and machines for producing radioisotopes suitable for use in conventional nuclear medicine and PET. After focusing on positron physics and the applications of positrons in medicine and biology, it describes the use of radiopharmaceuticals in molecular imaging, clinical, and research studies.
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