Stephen Hawking’s phenomenal, multimillion-copy bestseller, A Brief History of Time, introduced the ideas of this brilliant theoretical physicist to readers all over the world.Now, in a major publishing event, Hawking returns with a lavishly illustrated sequel that unravels the mysteries of the major breakthroughs that have occurred in the years since the release of his acclaimed first book.

    Written for a general audience and keeping both technical language and mathematics to a minimum, Feynman introduces the basics of physics, atoms, energy, gravitation, quantum force, and the relationship of physics to other subjects.

    Richard Gott leads time travel out of the world of H. G. Wells and into the realm of scientific possibility. Building on theories posited by Einstein and advanced by scientists such as Stephen Hawking and Kip Thorne, Gott explains how time travel can actually occur. He describes, with boundless enthusiasm and humor, how travel to the future is not only possible but has already happened, and he contemplates whether travel to the past is also conceivable. Notable not only for its extraordinary subject matter and scientific brilliance, Time Travel in Einstein’s Universe is a delightful and captivating exploration of the surprising facts behind the science fiction of time travel.

    William H. Cropper vividly portrays the life and accomplishments of such giants as Galileo and Isaac Newton, Marie Curie and Ernest Rutherford, Albert Einstein and NielsBohr, right up to contemporary figures such as Richard Feynman, Murray Gell-Mann, and Stephen Hawking. We meet scientists--all geniuses--who could be gregarious, aloof, unpretentious, friendly, dogged, imperious, generous to colleagues or contentious rivals. As Cropper captures their personalities, he also offers vivid portraits of their great moments of discovery, their bitter feuds, their relations with family and friends, their religious beliefs and education. In addition, Cropper has grouped these biographies by discipline--mechanics, thermodynamics, particle physics, and others--eachsection beginning with a historical overview. Thus in the section on quantum mechanics, readers can see how the work of Max Planck influenced Niels Bohr, and how Bohr in turn influenced Werner Heisenberg.Our understanding of the physical world has increased dramatically in the last four centuries. With Great Physicists, readers can retrace the footsteps of the men and women who led the way.

    It combines the essential elements of the theory with the practical applications. Containing many examples and problems with step-by-step solutions, this cleverly structured text assists the reader in mastering the machinery of quantum mechanics. * A comprehensive introduction to the subject * Includes over 65 solved examples integrated throughout the text * Includes over 154 fully solved multipart problems * Offers an indepth treatment of the practical mathematical tools of quantum mechanics * Accessible to teachers as well as students

    Each topic is summarized on a single page using annotated diagrams and concise notes with a full index for easy reference

    The development is organized around a progressively more sophisticated analysis of particular natural systems and weaves examples throughout the presentation. Explorations of phenomena such as transitions to chaos, nonlinear resonances, and resonance overlaps to help the student to develop appropriate analytic tools for understanding. Computational algorithms communicate methods used in the analysis of dynamical phenomena. Expressing the methods of mechanics in a computer language forces them to be unambiguous and computationally effective. Once formalized as a procedure, a mathematical idea also becomes a tool that can be used directly to compute results.The student actively explores the motion of systems through computer simulation and experiment. This active exploration is extended to the mathematics. The requirement that the computer be able to interpret any expression provides strict and immediate feedback as to whether an expression is correctly formulated. The interaction with the computer uncovers and corrects many deficiencies in understanding.

    These problems, chosen almost exclusively from classical (non-quantum) physics, are posed in accessible nontechnical language and require the student to select the right framework in which to analyze the situation. The book will be invaluable to undergraduates preparing for general physics papers. Some physics professors will even find the more difficult questions challenging. The mathematical prerequisites are minimal and do not go beyond elementary calculus. This intriguing book of physics problems will prove instructive, challenging and fun.

    The book explains the wide variety of physical, chemical and geological processes that govern the motions and properties of planets. Observations of the planets, moons, asteroids, comets and planetary rings in our Solar System, as well as extrasolar planets, are described, and the process of planetary formation is discussed.

    The basic principles of absorption, reflection, luminescence, and light scattering are covered for a wide range of materials, including insulators, semiconductors and metals. The text starts with a review of classical optics, and then moves on to the treatment of optical transition rates by quantum theory. In addition to the traditional discussion of crystalline materials, glasses and molecular solids are also covered. The first edition included a number of subjects that are not normally covered in standard texts, notably semiconductor quantum wells, molecular materials, vibronic solid state lasers, and nonlinear optics. The basic structure of the second edition is unchanged, but all of the chapters have been updated and improved. Futhermore, a number of important new topics have been added, including: DT Optical control of spin DT Quantum dots DT Plasmonics DT Negative refraction DT Carbon nanostructures (graphene, nanotubes and fullerenes) DT NV centres in diamond The text is aimed at final year undergraduates, masters students and researchers. It is mainly written for physicists, but might also be useful for electrical engineers, materials scientists and physical chemists. The topics are written in a clear tutorial style with worked examples, chapter summaries and exercises. A solutions manual is available on request for instructors. Features * Up-to-date coverage of modern topics in solid state physics * Wide range of materials covered * Inclusion of important new topics compared to the first edition * Clear tutorial style with worked examples, exercises, and solutions * Well illustrated with recent experimental data * Important new topics have been added, including: DT Optical control of spin DT Quantum dots DT Plasmonics DT Negative refraction DT Carbon nanostructures (graphene, nanotubes and fullere

    It is the perfect introduction for anyone in chemistry or physics who needs an update or background in this time-dependent field. Topics covered include fluctuation-dissipation theorem; linear response theory; time correlation functions, and projection operators. Theoretical models are illustrated by real-world examples and numerous applications such as chemical reaction rates and spectral line shapes are covered. The mathematical treatments are detailed and easily understandable and the appendices include useful mathematical methods like the Laplace transforms, Gaussian random variables and phenomenological transport equations.

    Feynman’s three volume Lectures on Physics has been known worldwide as the classic resource for students and professionals alike. Ranging from the most basic principles of Newtonian physics through such formidable theories as Einstein’s general relativity, superconductivity, and quantum mechanics, Fenyman’s lectures stand as a monument of clear exposition and deep insight. Responding to the tremendous clamour for the original audio tapes from which the Lectures on Physics were transcribed, Perseus Books is releasing Feynman’s original recordings, remastered for modern audio equipment and re-organized for cohesiveness and convenience. All 111 lectures will be available over the coming years.

    

    It also treats some topics of more recent interest such as phase transitions and non-equilibrium phenomena. The presentation introducesmodern concepts, such as the thermodynamic limit and equivalence of Gibbs ensembles, and uses simple models (ideal gas, Einstein solid, simple paramagnet) and many examples to make the mathematical ideas clear. Frequently used mathematical methods are discussed in detail and reviews in an appendix. The book begins with a review of statistical methods and classical thermodynamics, making it suitable for students from a variety of backgrounds. Statistical mechanics is formulated in the microcanonical ensemble; some simple arguments and many examples are used to construct th canonical and grand-canonical ensembles. The discussion of quantum statistical mechanics includes Bose and Fermi ideal gases, the Bose-Einstein condensation, blackbody radiation, phonons and magnons. The van der Waals and Curoe-Weiss phenomenological models are used to illustrate the classical theories of phase transitions and critical phenomena; modern developments are intorducted with discussions of the Ising model, scaling theory, and renormalization-group ideas. The book concludes withy two chapters on nonequilibrium phenomena: one using Boltzmann's kinetic approach, and the other based on stochastic methods. Exercises at the end of each chapter are an integral part of the course, clarifying and extending topics discussed in the text. Hints and solutions can be found on the author's web site.

    Intended for advanced undergraduates and beginning graduate students, the volumes in the series provide not only a complete survey of classical theoretical physics but also a large number of worked examples and problems to show students clearly how to apply the abstract principles to realistic problems.

    The profound unifying influence of geometrical ideas, the powerful formal similarities between statistical mechanics and quantum field theory, and the ubiquitous role of symmetries in determining the essential structure of physical theories are emphasized throughout.This second edition conducts a grand tour of the fundamental theories that shape our modern understanding of the physical world. The book covers the central themes of space-time geometry and the general relativistic account of gravity, quantum mechanics and quantum field theory, gauge theories and the fundamental forces of nature, statistical mechanics, and the theory of phase transitions. The basic structure of each theory is explained in explicit mathematical detail with emphasis on conceptual understanding rather than on the technical details of specialized applications. The book gives straightforward accounts of the standard models of particle physics and cosmology.

    It contains coverage of Resonance Raman and SERS, two hot areas of Raman, in a form suitable for the non-expert.Builds Raman theory up in stages without overloading the reader with complex theoryIncludes two chapters on instrumentation and interpretation that shows how Raman spectra can be obtained and interpretedExplains the potential of using Raman spectroscopy in a wide variety of applicationsIncludes detailed, but concise information and worked examples

    The fractal themes of "self-affinity" and "globality" are presented, while extensive introductory material, written especially for this book, precedes the papers and presents a number of striking new observations and conjectures. The mathematical tools so discussed will be valuable to diverse scientific communities.

    The discovery of the nucleus transformed the past century and will revolutionize this one. Though many persons associate nuclear physics with weapons of mass destruction, it is an exciting, cutting-edge science that has helped to save lives through innovative medical technologies, such as the MRI. In nuclear astrophysics, state-of-the-art theoretical and computer models help to explain the powerful stellar explosions known as supernovas, to account for how stars shine, and to describe how the chemical elements in the universe were formed.Nucleus: A Trip into the Heart of Matter by Ray Mackintosh, Jim Al-Khalili, Bjorn Jonsen, and Theresa Penae is a lavishly illustrated book filled with lively prose and captivating details that describe the evolution of our understanding of this phenomenon. The authors, who include expert nuclear physicists and acclaimed science journalists, tell the story of the nucleus from the early experimental work of the quiet New Zealander Lord Rutherford to the huge atom-smashing machines of today and beyond. Nucleus tells of the protons and neutrons of which the nucleus is made, why some nuclei crumble and are radioactive, and how scientists came up with the "standard model," which shows the nucleus composed of quarks held together by gluons. Nucleus is also the tale of the people behind the struggle to understand this fascinating subject more fully, and of how a vibrant research community uses the power of the nucleus to probe unanswered scientific questions while others seek to harness the nucleus as a tool of twenty-first-century medicine.Intended for a general audience, this bookunravels the scientific mysteries that surround the subject of the nucleus. Anyone with a passing interest in science will delight in this guide to the nuclear age.

    It provides a detailed review of compliant mechanisms and includes a wealth of useful design examples for engineers, students, and researchers. Concise chapters guide the reader from simple to more challenging concepts-using examples of increasing complexity-eventually leading to real-world applications for specific types of devices. The author focuses on compliant mechanisms that can be designed using both standard linear beam equations and more advanced pseudo-rigid-body models. He describes a number of special-purpose compliant mechanisms that have use across a wide range of applications and discusses compliant mechanisms in microelectromechanical systems (MEMS) with several accompanying MEMS examples. Coverage of essential topics in strength of materials, machine design, and kinematics is provided to allow for a self-contained book that requires little additional reference to solve compliant mechanism problems. This information can be used as a refresher on the basics or as resource material for readers from other disciplines currently working in MEMS. Compliant Mechanisms serves as both an introductory text for students and an up-to-date resource for practitioners and researchers. It provides comprehensive, expert coverage of this growing field.

    Authored by Gerald Holton, the text was a landmark in science education. It was the first modern textbook in physics (or in any other science) to make full and effective use of the history and philosophy of science in presenting for both the general and the science-oriented student an account of the nature of physical science. A second edition, prepared by Stephen G. Brush, brought the book up to date by increasing the coverage of topics in modern physics and by taking account of recent scholarly research in the history of science.  In the new book Physics, The Human Adventure, each of the chapters has been reworked to further clarify the physics concepts and to incorporate recent physical advances and research. The book shows the unifying power of science by bringing in connections to chemistry, astronomy, and geoscience. In short, the aid of the new edition is to teach good physics while presenting physical science as a human adventure that has become a major force in our civilization. New chapters discuss theories of the origin of the solar system and the expanding universe; fission, fusion, and the Big Bang–Steady State Controversy; and thematic elements and styles in scientific thought. New topics include:• Theories of vision: does the eye send out rays or receive them?• Distances in the solar system• The prediction of the return of Halley’s comet and analysis of deviations from Kepler’s laws• Angular momentum conservation and Laplace’s nebular hypothesis• Relation between symmetries and conservation laws: Emmy Noether’s theorem• First estimates of atomic sizes• Consequences of the indistinguishability of elementary particles of the same kind• Applications of quantum mechanics to many-particle systems• Dirac’s prediction of anti-matter• The anthropic principle and other controversial issues on the frontiers of research

    Writing for a primary readership of advanced undergraduate and graduate philosophy students, Barry Dainton introduces the central ideas and arguments that make space and time such philosophically challenging topics. Although recognising that many issues in the philosophy of time and space involve technical features of physics, Dainton has been careful to keep the conceptual issues accessible to students with little scientific or mathematical training. Surveying historical debates and ideas at the forefront of contemporary thinking, the book is unrivaled in its coverage. Topics include McTaggart's argument for the unreality of change; static, tensed, and dynamic time; time travel and causal arrows; space as void, motion, and curved spac; as well as a non-technical introduction to the special theory of relativity and the key features of general relativity, spacetime, and strings. Dainton also addresses the relationship between the philosophy of time and broader human concerns involving actions, ethics, fatalism, and death.

    Through this astonishing work, he manages to stoke wonder at the powers and unlikely events that conspired to create our solar system, our ecosystem, and us.

    It is unique in providing the means to master gauge field theory prior to the advanced study of quantum mechanics. Though gauge field theory is typically included in courses on quantum field theory, many of its ideas and results can be understood at the classical or semi-classical level. Accordingly, this book is organized so that its early chapters require no special knowledge of quantum mechanics. Aspects of gauge field theory relying on quantum mechanics are introduced only later and in a graduated fashion--making the text ideal for students studying gauge field theory and quantum mechanics simultaneously.The book begins with the basic concepts on which gauge field theory is built. It introduces gauge-invariant Lagrangians and describes the spectra of linear perturbations, including perturbations above nontrivial ground states. The second part focuses on the construction and interpretation of classical solutions that exist entirely due to the nonlinearity of field equations: solitons, bounces, instantons, and sphalerons. The third section considers some of the interesting effects that appear due to interactions of fermions with topological scalar and gauge fields. Mathematical digressions and numerous problems are included throughout. An appendix sketches the role of instantons as saddle points of Euclidean functional integral and related topics.Perfectly suited as an advanced undergraduate or beginning graduate text, this book is an excellent starting point for anyone seeking to understand gauge fields.

    This novel textbook provides a comprehensive guided tour of the mathematical knowledge and techniques needed by students in this area. In contrast to more traditional textbooks, all the material is presented in the form of problems. Within these problems the basic mathematical theory and its physical applications are very well integrated. In this way the mathematical insights that the students acquire are driven by their physical insight. Topics that are covered include vector calculus (div, grad, curl, Laplacian), linear algebra, Fourier analysis, scale analysis, Green's functions, normal modes, tensor calculus and perturbation theory. This book can be used by undergraduates or by lower-level graduate students in the physical sciences. It can serve as a stand-alone text, or as a source of problems and examples to complement other textbooks. This guided tour of mathematical techniques is instructive, applied, and even fun.

    In Quantum Dialogue, Mara Beller shows that science is rooted not just in conversation but in disagreement, doubt, and uncertainty. She argues that it is precisely this culture of dialogue and controversy within the scientific community that fuels creativity.Beller draws her argument from her radical new reading of the history of the quantum revolution, especially the development of the Copenhagen interpretation. One of several competing approaches, this version succeeded largely due to the rhetorical skills of Niels Bohr and his colleagues. Using extensive archival research, Beller shows how Bohr and others marketed their views, misrepresenting and dismissing their opponents as "unreasonable" and championing their own not always coherent or well-supported position as "inevitable."Quantum Dialogue, winner of the 1999 Morris D. Forkosch Prize of the Journal of the History of Ideas, will fascinate everyone interested in how stories of "scientific revolutions" are constructed and "scientific consensus" achieved.

    The text includesfull development of quantum theory. It begins with the most basic concepts of quantum theory, assuming only that students have some familiarity with such ideas as the uncertainty principle and quantized energy levels. Fayer's accessible approach presents balanced coverage of various quantum theoryformalisms, such as the Schr: odinger representation, raising and lowering operator techniques, the matrix representation, and density matrix methods. He includes a more extensive consideration of time dependent problems than is usually found in an introductory graduate course. Throughout the book, sufficient mathematical detail and classical mechanics background are provided to enable students to follow the quantum mechanical developments and analysis of physical phenomena. Fayer provides many examples and problems with fully detailed analytical solutions. Creating a distinctive flavorthroughout, Fayer has produced a challenging text with exercises designed to help students become fluent in the concepts and language of modern quantum theory, facilitating their future understanding of more specialized topics. The book concludes with a section containing problems for each chapterthat amplify and expand the topics covered in the book. A complete and detailed solution manual is available.

    Electrodynamics is a comprehensive study of the field produced by (and interacting with) charged particles, which in practice means almost all matter.Fulvio Melia's Electrodynamics offers a concise, compact, yet complete treatment of this important branch of physics. Unlike most of the standard texts, Electrodynamics neither assumes familiarity with basic concepts nor ends before reaching advanced theoretical principles. Instead this book takes a continuous approach, leading the reader from fundamental physical principles through to a relativistic Lagrangian formalism that overlaps with the field theoretic techniques used in other branches of advanced physics. Avoiding unnecessary technical details and calculations, Electrodynamics will serve both as a useful supplemental text for graduate and advanced undergraduate students and as a helpful overview for physicists who specialize in other fields.

    Written for students in physics and material science, the book takes a pedagogical approach to the subject through the extensive use of illustrations, examples and problem sets. The author draws on his extensive experience teaching band theory to provide the reader with a thorough understanding of the field. Considerable attention is paid to the vocabulary and quantum-mechanical training necessary to learn about the electronic, optical and structural properties of materials in science and technology. The text also offers several chapters on the newest experimental techniques used to study band structure. Concise yet rigorous, it fills a long overdue gap between student texts and current research activities.

    There have now been space probes to all the major planets of the Earth's Solar System -- the only worlds that are likely to be physically explored in our lifetime. Beyond the Solar System, across the final frontier of space, however, astronomers are now able to explore the Universe by proxy, using evidence from light, radio waves, x-ray, and other information gathered by telescopes on the Earth's surface and by orbiting satellites. Astronomers can now work out the life cycles of stars, the evolution of galaxies, the location of other solar systems, and the fate of the Universe itself. Hyperspace: Our Final Frontier provides a compelling insight into the way that astronomers work, explaining how they make the discoveries that make headlines, as well as the stories behind those headlines. From the first steps which measured the distances to the nearest stars, to the latest discovery that the Universe is expanding at an ever faster rate, John Gribbin puts deep space into perspective with the aid of specially commissioned illustrations and revealing photographs from the latest generation of astronomical telescopes.

    Throughout the book, the theory is illustrated with real-life applications in modern technology. It also includes detailed work examples and step-by-step explanations to help readers develop their problem-solving strategies and skills and consolidate their understanding. In addition to a meticulous development of thse traditional, analytical mathematical approaches, readers are also introduced to a range of techniques required for solving problems using computers. "Electromagnetism" provides an ideal preparation for readers who plan advanced studies in electrodynamics as well as those moving into industry or engineering .

    Cosmic Horizons illuminates the most recent discoveries of modern astrophysics with essays by leading astronomers, including NASA scientists. The book also features profiles of astronomers such as Carl Sagan and Georges Lemaître (father of the Big Bang theory), case studies that cover the controversial evidence for the possibility of life on Mars, and stunning four-color photographs throughout. Written for the general reader, Cosmic Horizons makes the complex, abstract areas of astronomy and astrophysics—from the Big Bang to black holes—accessible and comprehensible to the public. Complementing the museum's acclaimed new Frederick Phineas and Sandra Priest Rose Center exhibition, the book investigates how the universe expands to produce galaxies, stars, and planets, and, perhaps, life on other worlds. It also examines some of the emerging technologies that make these discoveries possible. With more than eighty full-color images and a resource section that includes a bibliography and an extensive glossary, Cosmic Horizons offers a new appreciation of the complexities of time and space and a greater understanding of our fragile planet and the universe beyond. Four-color illustrations throughout. The New Press is pleased to announce the publication of this new title with the American Museum of Natural History, a collaboration that began with the publication of Epidemic! in 2000. Founded in 1869, the American Museum of Natural History in New YorkCity is one of the world's preeminent institutions for scientific research and education, visited by more than four million people annually. Three new titles, Earth, The Biodiversity Crisis, and Cosmic Horizons, are companion volumes to three major new permanent exhibitions at the museum: the David S. and Ruth L. Gottesman Hall of Planet Earth, the Hall of Biodiversity, and the Frederick Phineas and Sandra Priest Rose Center for Earth and Space. Author Biography: Steven Soter is a member of the Department of Astrophysics at the American Museum of Natural History. He was a cowriter, with Carl Sagan and Ann Druyan, of the Cosmos television series, and co-author with Ann Druyan of the new Hayden Planetarium's inaugural sky show. Neil de Grasse Tyson is director of New York City's Hayden Planetarium. He has authored five books on the universe, including The Sky Is Not the Limit: Adventures of an Urban Astrophysicist. He is also a monthly columnist for Natural History magazine and was the project scientist for the Hall of the Universe in the Rose Center for Earth and Space.

    Turning philosophical and metaphysical problems into problems that physics can treat, and hopefully solve, has been an achievement of the twentieth century. Modern Cosmology brings together contributions from a number of outstanding scientists currently working in various research fields in cosmology. Topics covered range over several different aspects of modern cosmology, from observational matters to advanced theoretical speculations.

    does not include most We are therefore reminded "of physical problems. the of the man home late at after an alcoholic who, story returning night the for his under he was a knew, evening, scanning ground key lamppost; be that he had it somewhere but under the to sure, dropped else, only Yet was there to conduct a searcW' . light lamppost enough proper we feel the interest for such models is nowadays sufficiently widespread because of their their mathematical relevance and their multi beauty, farious that need be made for no our apologies applicative potential choice. In whoever undertakes to read this book will know from any case, its title what she is in for! Yet this title a of it some may require explanations: gloss (including its extended inside front follows. version, see cover) and nonrelativistic "Classical" we mean nonquantal (although By consider the which indeed some are Ruijsenaars Schneider models, treated in this relativistic versions as known, nonre book, of, previously lativistic is focussed see our on models; below): presentation mainly of whose time evolution is determined many body point particles systems Newtonian of motion to by equations (acceleration proportional force).

    Most of them were presented as lectures at various universities in Europe and the USA by Jagdish Mehra, while some were published individually and others in collaboration with Helmut Rechenberg. This book deals with the most important themes developed in the first 40 years of the 20th century by some of the greatest pioneers and architects of modern physics. It is a vital source of information about what can be described as "the golden age of theoretical physics".

    It offers a unique and comprehensive treatment of filters based on the microstrip structure and includes full design methodologies that are also applicable to waveguide and other transmission line filters.The authors include coverage of new configurations with advanced filtering characteristics, new design techniques, and methods for filter miniaturization. The book utilizes numerous design examples to illustrate and emphasize computer analysis and synthesis while also discussing the applications of commercially available software. Other highlights include:Lowpass and bandpass filters Highpass and bandstop filters Full-wave electromagnetic simulation Advanced materials and technologies Coupled resonator circuits Computer-aided design for low-cost/high-volume production Compact filters and filter miniaturization Microstrip Filters for RF/Microwave Applications is not only a valuable design resource for practitioners, but also a handy reference for students and researchers in microwave engineering.

    The course at Berkeley was greatly inspired in content and style by Victor Guillemin, whose masterly teaching of beautiful courses on topics related to s- plectic geometry at MIT, I was lucky enough to experience as a graduate student. I am very thankful to him! That course also borrowed from the 1997 Park City summer courses on symplectic geometry and topology, and from many talks and discussions of the symplectic geometry group at MIT. Among the regular participants in the MIT - formal symplectic seminar 93-96, I would like to acknowledge the contributions of Allen Knutson, Chris Woodward, David Metzler, Eckhard Meinrenken, Elisa Prato, Eugene Lerman, Jonathan Weitsman, Lisa Jeffrey, Reyer Sjamaar, Shaun Martin, Stephanie Singer, Sue Tolman and, last but not least, Yael Karshon. Thanks to everyone sitting in Math 242 in the Fall of 1997 for all the c- ments they made, and especially to those who wrote notes on the basis of which I was better able to reconstruct what went on: Alexandru Scorpan, Ben Davis, David Martinez, DonBarkauskas, EzraMiller, HenriqueBursztyn, John-PeterLund, Laura De Marco, Olga Radko, Peter P? rib ?k, Pieter Collins, Sarah Packman, Stephen Bigelow, Susan Harrington, Tolga Etgu ] and Yi Ma.

    After reviewing the key observational results and nomenclature used in stellar astronomy, the book develops a solid understanding of central concepts including stellar structure and evolution, the physics of stellar remnants, pulsars, binary stars, the sun and planetary systems, interstellar medium and globular clusters. Throughout, the reader's comprehension is developed and tested with more than seventy-five exercises. This indispensable volume will allow graduate students to master the material sufficiently to read and engage in research with heightened understanding. It can be used alone or in conjunction with Volume 1, which covers a wide range of astrophysical processes, and the forthcoming Volume 3, on galaxies and cosmology.