Astronomy Today / Edition 5

Astronomy Today / Edition 5

ISBN-10:
0131924923
ISBN-13:
9780131924925
Pub. Date:
07/24/2004
Publisher:
Prentice Hall (School Division)
Astronomy Today / Edition 5

Astronomy Today / Edition 5

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Overview

Chaisson/McMillan's writing style and pedagogically driven art program are recognized as being scientifically accurate yet accessible to non-science majors. The integrated media program contains the market's only E-book. It provides readers with innovative and interactive tools to learn and test their understanding of astronomy concepts.Topics covered include Astronomy and the Universe, Our Planetay System, Stars and Stellar Evolution, Galaxies and Cosmology, and more.For one or two-semester introductory astronomy course.

Product Details

ISBN-13: 9780131924925
Publisher: Prentice Hall (School Division)
Publication date: 07/24/2004
Edition description: New Edition
Pages: 800
Product dimensions: 6.50(w) x 1.50(h) x 9.50(d)
Age Range: 16 - 17 Years

About the Author

Eric Chaisson holds a Doctorate in Astrophysics from Harvard University, where he spent 10 years on the faculty of Arts and Sciences. For more than two decades thereafter, he served on the senior science staff at the Space Telescope Science Institute and held various professorships at Johns Hopkins and Tufts universities. He is now back at Harvard, where he teaches and conducts research at the Harvard-Smithsonian Center for Astrophysics. Eric has written 12 books on astronomy and has published nearly 200 scientific papers in professional journals.

Steve McMillan holds a Bachelor’s and Master’s Degree in Mathematics from Cambridge University and a Doctorate in Astronomy from Harvard University. He held postdoctoral positions at the University of Illinois and Northwestern University, where he continued his research in theoretical astrophysics, star clusters, and high-performance computing. Steve is currently Distinguished Professor of Physics at Drexel University and a frequent visiting researcher at Princeton’s Institute for Advanced Study and Leiden University. He has published more than 100 articles and scientific papers in professional journals.

Emily L. Rice, College of Staten Island, City University of New York

Emily holds bachelor’s degrees in physics and astronomy and German from the University of Pittsburgh and a master’s degree and doctorate in astronomy and astrophysics from UCLA. After completing her Ph.D. she held a postdoctoral position at the American Museum of Natural History, where she is still a resident research associate. Emily is currently Assistant Professor at the College of Staten Island and doctoral faculty in physics at the Graduate Center, both part of the City University of New York. In addition to her research on low-mass stars, brown dwarfs, and exoplanets as co-PI of the Brown Dwarfs in New York City (BDNYC) group, she is the co-author of Astronomy Labs: A Concept Oriented Approach and co-founder of the astronomy fashion blog STARtorialist.

Read an Excerpt

Astronomy continues to enjoy a golden age of exploration and discovery. Fueled by new technologies and novel theoretical insights, the study of the cosmos has never been more exciting. We are pleased to have the opportunity to present a representative sample of the known facts, evolving ideas, and frontier discoveries in astronomy today.

This book is written for students who have taken no previous college science courses and who will likely not major in physics or astronomy. The text is suitable for both onesemester and twosemester courses. We present a broad view of astronomy, straightforwardly descriptive and without complex mathematics. The absence of sophisticated mathematics, however, in no way prevents discussion of important concepts. Rather, we rely on qualitative reasoning as well as analogies with objects and phenomena familiar to the student to explain the complexities of the subject without oversimplification. We have tried to impart the enthusiasm that we feel about astronomy, and to awaken students to the marvelous universe around us.

In teaching astronomy to nonscientists, as in writing this book, we are not seeking to convert students to careers in astronomy or even science in general. Instead, we strive to reach the wider audience of students who are majoring in many other worthwhile fields. We want to encourage these students to become scientifically literate members of modern society—to appreciate new developments in the world of science, to understand what scientists do for a living and its importance, to make informed judgments regarding national initiatives in science and the public funding of scientific projects, and to voteintelligently in our democratic, increasingly technological world.

We are very gratified that the first three editions of this text have been so well received by many in the astronomy education community. In using those earlier texts, many of you—teachers and students alike—have sent us helpful feedback and constructive criticisms. From these, we have learned to better communicate both the fundamentals and the excitement of astronomy. Many improvements inspired by your comments have been incorporated into this new edition.

Organization and Approach

Our overall organization follows the popular and effective "Earthout" progression. We have found that most students, especially those with little scientific background, are much more comfortable studying the (relatively familiar) solar system before tackling stars and galaxies. Thus, Earth is the first object we discuss in detail. With Earth and the Moon as our initial planetary models, we move through the solar system, drawing on comparative planetology to provide an understanding of the many varied worlds we encounter. We conclude our coverage of the solar system with a discussion of its formation, a line of investigation that leads directly into a study of our Sun.

With the Sun as our model star, we then broaden the scope of our discussion to include stars in general—their properties, their evolutionary histories, and their varied fates. This journey naturally leads us to coverage of the Milky Way Galaxy, which in turn serves as an introduction to our treatment of other galaxies. Finally, we reach the subject of cosmology and the largescale structure and dynamics of the universe as a whole. Throughout, we strive to emphasize the dynamic nature of the cosmos—virtually every major topic, from planets to quasars, includes a discussion of how those objects formed and how they evolve.

We continue to place much of the needed physics in the early chapters—an approach derived from years of experience teaching thousands of students. Additional physical principles are developed as needed later, both in the text narrative and in the boxed More Precisely features (described below). We feel strongly that this is the most economical and efficient means of presentation. However, we acknowledge that not all instructors feel the same way. Accordingly, we have made the treatment of physics, as well as the more quantitative discussions, as modular as possible, so that these topics can be deferred to later stages of an astronomy course if desired. In addition, we have included as much modern astronomy as possible in the introductory chapters. These chapters are likely to engage students only if they are made to realize how simple physical principles provide the keys to our understanding of a vast and otherwise incomprehensible universe.

New and Revised Material

The text has been extensively updated in content since the third edition. Most chapters have been significantly changed, and several have seen major reorganization. Among the many changes are:

  • New boxes in Chapter 1 on astronomical timekeeping and distance measurement.
  • Expanded discussion in Chapter 2 of Newton's discovery of the law of gravity.
  • Updated material in Chapter 5 on adaptive optics, Subaru, Gemini, the VLT, and infrared and optical interferometry; new material on the Chandra mission; updates (and a conclusion) to the CGRO story.
  • New material in Chapter 6 on measuring planetary properties; updates on the Galileo, Cassini, and Mars Global Surveyor missions.
  • Expanded material in Chapter 6 on Clementine and Lunar Prospector, with updates on their important findings, including the possibility of ice at the lunar poles.
  • Greatly expanded coverage in Chapter 10 of Mars Global Surveyor and the many scientific results that have come from it; the possibility of (past or present) liquid water on Mars; an update on the Martian Meteorite controversy.
  • Updates in Chapter 11 on the Galileo/GEM mission, including the latest results on the possible existence of a liquid water ocean below Europa's icy surface; discussion of the magnetic fields of the Galilean moons.
  • Coverage of the many new moons of Jupiter, Saturn, and Uranus.
  • Expanded coverage of Pluto and the Kuiper belt in Chapters 1315.
  • Updates in Chapter 14 on asteroid numbers and the properties of nearEarth objects; coverage of the NEAR mission and its exploration of Eros.
  • Substantially updated coverage of solar system formation in Chapter 15, including disk instabilities, planetary migration, and their implications for extrasolar planetary systems.
  • New section in Chapter 15 on extrasolar planets, with updated material on the latest observations.
  • Incorporation of results from the Yohkoh, SOHO, and TRACE missions into Chapter 16.
  • The latest experimental results in the search for the missing solar neutrinos (Chapter 16).
  • Use of Hipparcos data in Chapter 17 and throughout the text; new HR diagram based on Hipparcos measurements; discussion of future astrometry missions and their implications.
  • Updated information in Chapter 17 on the numbers and mass distribution of stars in our Galaxy.
  • Extensive revision of the material on stellar mass determination in Chapter 17.
  • Expanded discussion in Chapter 18 of the Local Bubble.
  • Updated information in Chapter 19 on brown dwarfs; new material on jets and outflows in star formation.
  • New coverage in Chapter 20 of the endstates of stellar and binary evolution; discussion of blue stragglers; more examples of familiar stars in specific evolutionary stages.
  • New section and latest results on gammaray bursts in Chapter 22; discussion of intermediatemass and supermassive black holes.
  • Latest results in Chapter 23 on Sgr A* and the Galaxy's central black hole.
  • Expanded and substantially revised coverage in Chapter 24 of galaxy collisions, hierarchical merging, and galaxy evolution; updated discussion of the measurement of Hubble's constant.
  • Streamlined discussion in Chapter 25 of active galaxies and quasars; revised discussion of active galaxy evolution.
  • New material in Chapter 25 on quasar absorption lines and the Lymanalpha forest; expanded discussion of gravitational lensing, including the construction of darkmatter maps from lensing of background galaxies.
  • Extensive rewriting of Chapter 26 to include recent observations of cosmic acceleration and discussion of "dark energy;" revised discussions of the cosmological constant and the "age controversy"
  • New material in Chapter 26 on HDFS and the Chandra Deep Field.
  • Consistent distances and times in Chapters 2527, assuming a flat universe with dark matter and dark energy. Expanded discussion in Chapter 27 of inflation, dark energy, and structure formation; results from the Boomerang experiment suggesting a flat universe.
  • Updated coverage of Europa, Mars, interstellar organic molecules, and extrasolar planets in Chapter 28.

The Illustration Program

Visualization plays an important role in both the teaching and the practice of astronomy, and we continue to place strong emphasis on this aspect of our book. We have tried to combine aesthetic beauty with scientific accuracy in the artist's conceptions that adorn the text, and we have sought to present the best and latest imagery of a wide range of cosmic objects. Each illustration has been carefully crafted to enhance student learning; each is pedagogically sound and tied tightly to the nearby discussion of important scientific facts and ideas. For this edition, the illustration program has been extensively revised and updated, resulting in more than 100 figures that show the latest imagery and the results learned from them.

Full Spectrum Coverage and Spectrum Icons
Increasingly, astronomers are exploiting the full range of the electromagnetic spectrum to gather information about the cosmos. Throughout this book, images taken at radio, infrared, ultraviolet, Xray, or gammaray wavelengths are used to supplement visiblelight images. As it is sometimes difficult (even for a professional) to tell at a glance which images are visiblelight photographs and which are falsecolor images created with other wavelengths, each photo in the text is provided with an icon that identifies the wavelength of electromagnetic radiation used to capture the image and reinforces the connection between wavelength and radiation properties.

Compound Art
It is rare that a single image, be it a photograph or an artist's conception, can capture all aspects of a complex subject. Wherever possible, multiplepart figures are used in an attempt to convey the greatest amount of information in the most vivid way:

  • Visible images are often presented along with their counterparts captured at other wavelengths.
  • Interpretive line drawings are often superimposed on or juxtaposed with real astronomical photographs, helping students to really "see" what the photographs reveal.
  • Breakouts—often multiple ones—are used to zoom in from widefield shots to closeups so that detailed images can be understood in their larger context.

Explanatory Captions
Students often review a chapter by "looking at the pictures." For this reason, the captions in this book are often a bit longer and more detailed than those in other texts.

HR Diagrams and the Cosmic Distance Ladder
All of the HR diagrams, assembled and drawn by Lola Judith Chaisson, are presented in a uniform format, using real data wherever possible. The goal is to make it easy for students to compare theoretical and observational results presented across several different chapters. The cosmic distance ladder is a theme that spans the text, and we use an evolving set of standard figures to illustrate how distance measurement techniques fit into and ultimately drive our understanding of the cosmos.

Acetate Overlays
Two unique sets of transparent acetate overlays dramatically illustrate two key pedagogical elements of the book. The HR diagram overlays demonstrate to students how astronomers organize information about the stars and track their evolutionary histories. The cosmic distance scale overlays summarize, in simplified form, the main methods used by astronomers to chart their way among increasing scales in the universe.

Other Pedagogical Features

As with many other parts of our textbook, instructors have helped guide us toward what is most helpful for effective student learning. With their assistance, we have revised both our inchapter and endofchapter pedagogical apparatus to increase its utility to students.

Learning Goals. Studies indicate that beginning students often have trouble prioritizing textual material. For this reason, a few (typically five or six) welldefined Learning Goals are provided at the start of each chapter. These help students to structure their reading of the chapter and then test their mastery of key facts and concepts. The Learning Goals are numbered and crossreferenced to key sections in the body of each chapter. This intext highlighting of the most important aspects of the chapter also helps students to review. They are organized and phrased in such a way as to make them objectively testable, affording students a means of gauging their own progress.

Concept Checks. New to this edition, we have 1 incorporated into each chapter a number of "Concept Checks"—key questions that require the reader to reconsider some of the material just presented or attempt to place it into a broader context. Answers to the Concept Check questions are provided at the end of the book.

CrossLinks. In astronomy, as in many scientific disciplines, almost every topic seems to have some bearing on almost every other. In particular, the connection between the specifically astronomical material and the physical principles set forth early in the text is crucial. Practically everything in Chapters 628 of this text rests on the foundation laid in the first five chapters. For example, it is important that students, when they encounter the discussion of highredshift objects in Chapter 25, recall not only what they just learned about Hubble's law in Chapter 24 but also refresh their memories, if necessary, about the inversesquare law (Chapter 17), stellar spectra (Chapter 4), and the Doppler shift (Chapter 3). Similarly, the discussions of the mass of binarystar components (Chapter 17) and of galactic rotation (Chapter 23) both depend on the discussion of Kepler's and Newton's laws in Chapter 2. Throughout, the discussion of new astronomical objects relies heavily on comparison with topics introduced earlier.

It is essential to remind students of these links so they can recall the principles on which later discussions rest and, if necessary, review them. To reinforce these connections, "cross links" have been inserted throughout the text—symbols that mark key intellectual bridges between material in different chapters. The links are denoted by the infinity symbol and, together with a section reference (a hyperlink on the accompanying CDROM), signal to students that the topic under discussion is related in some significant way to ideas developed earlier, and direct them to material that they might wish to review before proceeding.

Key Terms. Like all subjects, astronomy has its own special vocabulary. To aid student learning, the most important astronomical terms are boldfaced at their first appearance in the text. Each boldfaced key term is also incorporated in the appropriate chapter summary, together with the page number where it was defined. In addition, a full alphabetical glossary, defining each key term and locating its first use in the text, appears at the end of the book.

Planetary Data Boxes. Providing concise summaries of planetary properties within the body of each chapter, the data are repeated in the Appendix for easy reference. Similar data boxes are provided for both the Moon and the Sun. All planetary data are drawn from the database maintained by the Solar System Dynamics Group at the Jet Propulsion Laboratory.

Discovery Boxes. Exploring a 1 wide variety of interesting supplementary topics, these features have been expanded and renamed from the "Interludes" of previous editions to better reflect their goal of providing the reader with insight into how scientific knowledge evolves.

More Precisely Boxes. These provide quantitative treatments of subjects discussed qualitatively in the text, or explore the physics of astronomical processes in greater detail. Removing these more challenging topics from the main flow of the narrative and placing them within a separate modular element of the chapter design (so that they can be covered in class, assigned as supplementary material, or simply left as optional reading for those students who find them of interest) affords instructors greater flexibility in setting the level of their coverage.

Chapter Summaries. The chapter summaries, a primary review tool for the student, have been revised and streamlined for the fourth edition. All key terms introduced in each chapter are listed again, in context and in boldface, along with page references to the text discussion.

Questions, Problems, and Projects. Other elements of the endofchapter material have also seen substantial reorganization and expansion:

  • Each chapter incorporates 30 SelfTest questions, equally divided between "True/False" and "FillintheBlank" formats, designed to allow students to assess their understanding of the chapter material. Answers to all questions appear at the end of the book.
  • Each chapter also has 20 Review and Discussion questions (increased from 15 in the previous edition), which may be used for inclass review or for assignments. As with the SelfTest questions, the material needed to answer Review questions may be found within the chapter. The Discussion questions explore particular topics more deeply, often asking for opinions, riot just facts. As with all discussions, these questions usually have no single "correct" answer.
  • The endofchapter Problems have been expanded to contain 15 questions, spanning a somewhat broader range of difficulty than those in the previous edition. The level of difficulty is indicated on each problem. Answers to the Problems, particularly for the more sophisticated ones, are not necessarily contained verbatim within the chapter, but all the information required to solve the problems is in the text. Solutions for the oddnumbered problems are given at the end of the book. New for this edition, we have put algorithmic versions of the problems in a Practice Problems module of the text's Companion Website: The values in each problem change each time the student uses a chapter's problem set, thereby giving students unlimited practice in solving numeric problems.
  • Each chapter includes a few (24) Projects meant to get the student out of the classroom and looking at the sky, although some entail research in libraries or other extracurricular activities.

New to this edition are Collaborative Exercises 1 provided by Tim Slater at Montana State University. These interactive collaborative learning group activities are designed to encourage students to work together on reasoning tasks. They are designed specifically for use in the classroom, allow for multiple correct solution pathways, and give students some degree of choice in how to approach solving a complex, multifaceted problem. Most tasks require 712 minutes to complete.

Also new to this edition and provided by Tim Slater are "Researching on the Web" exercises. Using stable and maintained Internet resources hyperlinked from the Destinations module on the text's Companion Website, students are assigned analysis tasks using current and realtime Internet data sources. Quite different from the single correct answer tasks often used, many of these engaging tasks yield different but correct results for students accessing data resources on different days.

Finally, each chapter now concludes with SkyChart III Projects by Erik Bodegom and Sean Goe of Portland State University and Duane Ingram Of Rock Valley College. These exercises are based on the SkyChart III Student Version planetarium software, which is included as a separately executable program on the ebook CD in the back of the text. Square bullets preceding each exercise indicate its approximate level of difficulty. Appendix 4 provides general instructions for the software, and specific menu commands are included with each exercise. Instructor's notes for all the exercises are included in a passwordprotected part of the text's Companion Website.

eBook CD and Companion Website

eBook CD. Each copy of the text comes with a free ebook CD. This is a browserbased version of the text with extensive hyperlinks (over 3000 throughout the text), 61 videos integrated with relevant text discussions, and links to our Companion Website, which is organized by text chapter and updated monthly. We have added 12 new, exclusive animations from the Wright Center at Tufts University and redigitized all the videos and animations for larger size and higher resolution, and now they all have narrations.

SkyChart III Student Version. Also included on the eBook CD as a separately executable program is a student version of the SkyChart III planetarium software by Southern Stars Systems. This planetarium program accurately simulates and displays the sky as it currently appears, as well as thousands of years in the past or future. The sky can be viewed from any place on Earth, or from any object in the solar system or beyond. The program includes a database of 300,000 fully customizable objects based on NASA's SKY2000 Master Star Catalog, showing all stars up to about magnitude 10.

Companion Website. Our Companion Website organizes Destinations (links to related websites), additional Images and Animations, Multiple Choice, True/False, and Labeling exercises, and algorithmic versions of the text's endofchapter Problems on a chapterbychapter basis. The Destinations, Images, and Animations modules are updated monthly to keep links current and provide information on significant new discoveries. All of the exercises and problems are interactive, meaning that the student answers the questions online and then receives immediate scoring and feedback, including text section references for any areas the student needs to study further if they answered a given question incorrectly.

Additional Supplementary Material

This edition of Astronomy Today is accompanied by an outstanding set of instructional aids.

Comets. Published annually at the beginning of each academic year and available free to adopters, Comets is a unique kit that includes a collection of slides, videos, and New York Times articles on events and discoveries that have occurred since the publication of the prior year's Comets kit. The slide kit contains 28 new slides from NASA, JPL, STScI, GSFC, HST Comet LINEAR Investigation Team, APL, JPL, ESA, Hubble Heritage Team, IPAC, European Southern Observatory, SDSS/Astrophysical Research Consortium, and the U.S. Department of Defense. Custom animations prepared by the Wright Center for Science Visualization and many other videos of new discoveries and animations from various sources, including NASA, STScI, APL/NRL, ESA, Stanford Lockheed Institute for Space Research, and JPL are provided in both CD and DVD formats. The collection of New York Times articles, called "Themes of the Times," is published twice yearly and is available free in quantity for your students using either Chaisson/McMillan text. A newsletter provides a cross reference between all the materials in the Comets kit and corresponding chapters of both Chaisson/McMillan texts, as well as annotations describing the subject and source of each slide and video in the kit.
ISBN 0130938017

Instructor's Resource Manual. By Leo Connolly (California State University at San Bernardino). This manual provides an overview of each chapter, pedagogical tips, useful analogies, suggestions for classroom demonstrations, writing questions, answers to the endofchapter Review and Discussion questions and Problems. New features include an expanded introduction with an overview of how to utilize the IRM, an index of demonstrations, applications of the writing questions, sample assignments, discussion of common student misconceptions, teaching notes for the collaborative exercises, and a list of selected readings for each chapter.
ISBN 0130937967

Media Portfolio CDROM. By Suzanne Willis (Northern Illinois University). This flexible, easytouse tool contains a wealth of photographs, line art, animations, and videos to use in class lectures. Instructors can easily search, access, and organize the materials according to their lecture outlines and add their own visuals and lecture notes. The hybrid CD contains all of the line art and photographs from Astronomy Today 4e, as well as the animations and videos that are on the eBook CD in the back of the student text. In addition, the Image Viewer incorporates slides from the current and past editions of Comets. ISBN 0130937916

Acetates and Slides. A set of approximately 260 images from the textalmost double the number offered for the third editionare available as a package of color acetates or 35mm slides, and are available free to qualified adopters.
ISBN 0130937800 (Slide set)
ISBN 0130938033 (Transparency pack)

Test Item File. An extensive file of over 2600 test questions, newly compiled and revised for the fourth edition by Wayne Wooten (Pensacola Junior College), is offered free upon adoption. Available in both printed and electronic formats (Macintosh or Windows format). The fourth edition Test Item File has been thoroughly revised, including many new Multiple Choice and Essay questions for added conceptual emphasis. Overall, approximately 600 new questions have been added.
ISBN 0130937983

Prentice Hall Custom Test. Available for Macintosh and Windows, Prentice Hall Custom Test allows educators to create and tailor the exam to their own needs. With the Online Testing option, exams can also be administered online, and data can then be automatically transferred for evaluation. A comprehensive desk reference guide is included, along with online assistance.
ISBN 0130937975
(Macintosh) ISBN 0130937991 (Windows)

Science on the Internet. By Andrew Stull and Harry Nickla. A guide to general science resources on the Internet. Everything you need to know to get yourself online and browsing the World Wide Web!
ISBN 0130282537

Table of Contents

(NOTE: Volume 1 contains Chs. 1-15 and Volume 2 containsChs. 1-5 and 16-28.)

ASTRONOMY AND THE UNIVERSE.

1. Charting the Heavens: The Foundation of Astronomy.
Our Place in Space. The Obvious View. Earth's Orbital Motion. The Motion of the Moon. The Measurement of Distance.

2. The Copernican Revolution: The Birth of Modern Science.
Ancient Astronomy. The Geocentric Universe. The Heliocentric Model of the Solar System. The Birth of Modern Astronomy. The Laws of Planetary Motion. The Dimensions of the Solar System. Newton's Laws.

3. Radiation: Information from the Cosmos.
Information from the Skies. Waves in What? The Electromagnetic Spectrum. The Distribution of Radiation. The Doppler Effect.

4. Spectroscopy: The Inner Workings of Atoms.
Spectral Lines. The Formation of Spectral Lines. Molecules. Spectral-Line Analysis.

5. Telescopes: The Tools of Astronomy.
Optical Telescopes. Telescope Size. High-Resolution Astronomy. Radio Astronomy. Interferometry. Space-Based Astronomy. Full-Spectrum Coverage.

OUR PLANETARY SYSTEM.

6. The Solar System: An Introduction to Comparative Planetology.
An Inventory of the Solar System. Planetary Properties. The Overall Layout of the Solar System. Terrestrial and Jovian Planets. Interplanetary Debris. Spacecraft Exploration of the Solar System.

7. The Earth: Our Home in Space.
Overall Structure of Planet Earth. Earth's Atmosphere. Earth's Interior. Surface Activity. Earth's Magnetosphere. The Tides.

8. The Moon and Mercury: Scorched and Battered World.
Orbital Properties. PhysicalProperties. Surface Features on the Moon and Mercury. Rotation Rates. Lunar Cratering and Surface Composition. The Surface of Mercury. Interiors. The Origin of the Moon. Evolutionary History of the Moon and Mercury.

9. Venus: Earth's Sister Planet.
Orbital Properties. Physical Properties. Long-Distance Observations of Venus. The Surface of Venus. The Atmosphere of Venus. Venus's Magnetic Field and Internal Structure.

10. Mars: A Near Miss for Life?
Orbital Properties. Physical Properties. Long-Distance Observations of Mars. The Surface of Mars. The Martian Atmosphere. Martian Internal Structure. The Moons of Mars.

11. Jupiter: Giant of the Solar System.
Orbital and Physical Properties. The Atmosphere of Jupiter. Internal Structure. Jupiter's Magnetosphere. The Moons of Jupiter. Jupiter's Ring.

12. Saturn: Spectacular Rings and Mysterious Moons.
Orbital and Physical Properties. Saturn's Atmosphere. Saturn's Interior and Magnetosphere. Saturn's Spectacular Ring System. The Moons of Saturn.

13. Uranus, Neptune, and Pluto: The Outer Worlds of theSolar System.
The Discovery of Uranus. The Discovery of Neptune. Physical Properties of Uranus and Neptune. The Atmospheres of Uranus and Neptune. Magnetospheres and Internal Structure. The Moon Systems of Uranus and Neptune. The Rings of the Outermost Jovian Planets. The Discovery of Pluto. Physical Properties of Pluto. The Origin of Pluto.

14. Solar System Debris: Keys to Our Origin.
Asteroids. Comets. Meteoroids.

15. The Formation of Planetary System: The Birth of OurWorld.
Modeling the Origin of Our Solar System. The Condensation Theory. The Differentiation of the Solar System. The Role of Catastrophes. Planets Beyond the Solar System.

STARS AND STELLAR EVOLUTION.

16. The Sun: Our Parent Star.
Physical Properties of the Sun. The Solar Interior. The Solar Atmosphere. The Active Sun. The Heart of the Sun. Observations of Solar Neutrinos.

17. Measuring the Stars: Giants, Dwarfs and the Main Sequence.
The Distance to the Stars. Stellar Motion. Luminosity and Apparent Brightness. Stellar Temperatures. Stellar Sizes. The Hertzsprung-Russell Diagram. Extending the Cosmic Distance Scale. Stellar Masses.

18. The Interstellar Medium: Gas and Dust Among the Stars.
Interstellar Matter. Emission Nebulae. Dark Dust Clouds. 21-Centimeter Radiation. Interstellar Molecules.

19. Star Formation: A Traumatic Birth.
Star-Forming Regions. The Formation of Stars Like the Sun. Stars of Other Masses. Observations of Cloud Fragments and Protostars. Shock Waves and Star Formation. Star Clusters.

20. Star Evolution: The Life of a Star.
Leaving the Main Sequence. The Evolution of a Sunlike Star. The Death of a Low-Mass Star. Evolution of Stars More Massive. Observing Stellar Evolution in Star Clusters. The Evolution of Binary-Star Systems.

21. Stellar Explosions: Novae, Supernovae, and the Formation of the Heavy Elements.
Life after Death for White Dwarfs. The End of a High-Mass Star. Supernova Explosions. The Formation of the Elements. The Cycle of Stellar Evolution.

22. Neutron Stars and Black Holes: Strange States of Matter.
Neuron Stars. Pulsars. Neutron-Star Binaries. Gamma-Rays Bursts. Black Holes. Black Holes and Curved Space. Space Travel Near Black Holes. Observational Evidence for Black Holes.

GALAXIES AND COSMOLOGY.

23. The Milky Way Galaxy: A Grand Design.
Our Parent Galaxy. Measuring the Milky Way. The Large-Scale Structure of Our Galaxy. The Formation of the Milky Way. Galactic Spiral Arms. The Mass of the Milky Way Galaxy. The Galactic Center.

24. Normal Galaxies: The Large-Scale Structure of the Universe.
Hubble's Galaxy Classification. The Distribution of Galaxies in Space. Galaxy Masses. Galaxy Formation and Evolution. Hubble's Law.

25. Active Galaxies and Quasars: Limits of the ObservableUniverse.
Beyond the Local Realm. Properties of Active Galaxies. Quasi-Stellar Objects. The Central Engine of an Active Galaxy. Quasars as Cosmic Probes. Active Galaxy Evolution.

26. Cosmology: The Big Bang and the Fate of the Universe.
The Universe on the Largest Scales. The Expanding Universe. The Fate of the Universe. Will the Universe Expand Forever? The Geometry of Space. The Cosmic Microwave Background.

27. The Early Universe: Toward the Beginning of Time.
Back to the Big Bang. The Evolution of the Universe. The Formation of Nuclei and Atoms. The Inflationary Universe. The Formation of Structure in the Universe.

28. Life in the Universe: Are We Alone?
Cosmic Evolution. Life in the Solar System. Intelligent Life in the Galaxy. The Search for Extraterrestrial Intelligence.

APPENDICES.

Appendix I: Scientific Notation.
Appendix II: Astronomical Measurement.
Appendix III: Tables.
Appendix IV: Using SkyChart III.
Glossary.
Answers to Concept Check Questions.
Answers to Self-Test Questions.
Index.
Star Charts.

Preface

Astronomy continues to enjoy a golden age of exploration and discovery. Fueled by new technologies and novel theoretical insights, the study of the cosmos has never been more exciting. We are pleased to have the opportunity to present a representative sample of the known facts, evolving ideas, and frontier discoveries in astronomy today.

This book is written for students who have taken no previous college science courses and who will likely not major in physics or astronomy. The text is suitable for both one-semester and two-semester courses. We present a broad view of astronomy, straightforwardly descriptive and without complex mathematics. The absence of sophisticated mathematics, however, in no way prevents discussion of important concepts. Rather, we rely on qualitative reasoning as well as analogies with objects and phenomena familiar to the student to explain the complexities of the subject without oversimplification. We have tried to impart the enthusiasm that we feel about astronomy, and to awaken students to the marvelous universe around us.

In teaching astronomy to nonscientists, as in writing this book, we are not seeking to convert students to careers in astronomy or even science in general. Instead, we strive to reach the wider audience of students who are majoring in many other worthwhile fields. We want to encourage these students to become scientifically literate members of modern society—to appreciate new developments in the world of science, to understand what scientists do for a living and its importance, to make informed judgments regarding national initiatives in science and the public funding of scientific projects, and to vote intelligently in ourdemocratic, increasingly technological world.

We are very gratified that the first three editions of this text have been so well received by many in the astronomy education community. In using those earlier texts, many of you—teachers and students alike—have sent us helpful feedback and constructive criticisms. From these, we have learned to better communicate both the fundamentals and the excitement of astronomy. Many improvements inspired by your comments have been incorporated into this new edition.

Organization and Approach

Our overall organization follows the popular and effective "Earth-out" progression. We have found that most students, especially those with little scientific background, are much more comfortable studying the (relatively familiar) solar system before tackling stars and galaxies. Thus, Earth is the first object we discuss in detail. With Earth and the Moon as our initial planetary models, we move through the solar system, drawing on comparative planetology to provide an understanding of the many varied worlds we encounter. We conclude our coverage of the solar system with a discussion of its formation, a line of investigation that leads directly into a study of our Sun.

With the Sun as our model star, we then broaden the scope of our discussion to include stars in general—their properties, their evolutionary histories, and their varied fates. This journey naturally leads us to coverage of the Milky Way Galaxy, which in turn serves as an introduction to our treatment of other galaxies. Finally, we reach the subject of cosmology and the large-scale structure and dynamics of the universe as a whole. Throughout, we strive to emphasize the dynamic nature of the cosmos—virtually every major topic, from planets to quasars, includes a discussion of how those objects formed and how they evolve.

We continue to place much of the needed physics in the early chapters—an approach derived from years of experience teaching thousands of students. Additional physical principles are developed as needed later, both in the text narrative and in the boxed More Precisely features (described below). We feel strongly that this is the most economical and efficient means of presentation. However, we acknowledge that not all instructors feel the same way. Accordingly, we have made the treatment of physics, as well as the more quantitative discussions, as modular as possible, so that these topics can be deferred to later stages of an astronomy course if desired. In addition, we have included as much modern astronomy as possible in the introductory chapters. These chapters are likely to engage students only if they are made to realize how simple physical principles provide the keys to our understanding of a vast and otherwise incomprehensible universe.

New and Revised Material

The text has been extensively updated in content since the third edition. Most chapters have been significantly changed, and several have seen major reorganization. Among the many changes are:

  • New boxes in Chapter 1 on astronomical timekeeping and distance measurement.
  • Expanded discussion in Chapter 2 of Newton's discovery of the law of gravity.
  • Updated material in Chapter 5 on adaptive optics, Subaru, Gemini, the VLT, and infrared and optical interferometry; new material on the Chandra mission; updates (and a conclusion) to the CGRO story.
  • New material in Chapter 6 on measuring planetary properties; updates on the Galileo, Cassini, and Mars Global Surveyor missions.
  • Expanded material in Chapter 6 on Clementine and Lunar Prospector, with updates on their important findings, including the possibility of ice at the lunar poles.
  • Greatly expanded coverage in Chapter 10 of Mars Global Surveyor and the many scientific results that have come from it; the possibility of (past or present) liquid water on Mars; an update on the Martian Meteorite controversy.
  • Updates in Chapter 11 on the Galileo/GEM mission, including the latest results on the possible existence of a liquid water ocean below Europa's icy surface; discussion of the magnetic fields of the Galilean moons.
  • Coverage of the many new moons of Jupiter, Saturn, and Uranus.
  • Expanded coverage of Pluto and the Kuiper belt in Chapters 13-15.
  • Updates in Chapter 14 on asteroid numbers and the properties of near-Earth objects; coverage of the NEAR mission and its exploration of Eros.
  • Substantially updated coverage of solar system formation in Chapter 15, including disk instabilities, planetary migration, and their implications for extrasolar planetary systems.
  • New section in Chapter 15 on extrasolar planets, with updated material on the latest observations.
  • Incorporation of results from the Yohkoh, SOHO, and TRACE missions into Chapter 16.
  • The latest experimental results in the search for the missing solar neutrinos (Chapter 16).
  • Use of Hipparcos data in Chapter 17 and throughout the text; new H-R diagram based on Hipparcos measurements; discussion of future astrometry missions and their implications.
  • Updated information in Chapter 17 on the numbers and mass distribution of stars in our Galaxy.
  • Extensive revision of the material on stellar mass determination in Chapter 17.
  • Expanded discussion in Chapter 18 of the Local Bubble.
  • Updated information in Chapter 19 on brown dwarfs; new material on jets and outflows in star formation.
  • New coverage in Chapter 20 of the end-states of stellar and binary evolution; discussion of blue stragglers; more examples of familiar stars in specific evolutionary stages.
  • New section and latest results on gamma-ray bursts in Chapter 22; discussion of intermediate-mass and supermassive black holes.
  • Latest results in Chapter 23 on Sgr A* and the Galaxy's central black hole.
  • Expanded and substantially revised coverage in Chapter 24 of galaxy collisions, hierarchical merging, and galaxy evolution; updated discussion of the measurement of Hubble's constant.
  • Streamlined discussion in Chapter 25 of active galaxies and quasars; revised discussion of active galaxy evolution.
  • New material in Chapter 25 on quasar absorption lines and the Lyman-alpha forest; expanded discussion of gravitational lensing, including the construction of dark-matter maps from lensing of background galaxies.
  • Extensive rewriting of Chapter 26 to include recent observations of cosmic acceleration and discussion of "dark energy;" revised discussions of the cosmological constant and the "age controversy"
  • New material in Chapter 26 on HDF-S and the Chandra Deep Field.
  • Consistent distances and times in Chapters 25-27, assuming a flat universe with dark matter and dark energy. Expanded discussion in Chapter 27 of inflation, dark energy, and structure formation; results from the Boomerang experiment suggesting a flat universe.
  • Updated coverage of Europa, Mars, interstellar organic molecules, and extrasolar planets in Chapter 28.

The Illustration Program

Visualization plays an important role in both the teaching and the practice of astronomy, and we continue to place strong emphasis on this aspect of our book. We have tried to combine aesthetic beauty with scientific accuracy in the artist's conceptions that adorn the text, and we have sought to present the best and latest imagery of a wide range of cosmic objects. Each illustration has been carefully crafted to enhance student learning; each is pedagogically sound and tied tightly to the nearby discussion of important scientific facts and ideas. For this edition, the illustration program has been extensively revised and updated, resulting in more than 100 figures that show the latest imagery and the results learned from them.

Full Spectrum Coverage and Spectrum Icons
Increasingly, astronomers are exploiting the full range of the electromagnetic spectrum to gather information about the cosmos. Throughout this book, images taken at radio, infrared, ultraviolet, X-ray, or gamma-ray wavelengths are used to supplement visible-light images. As it is sometimes difficult (even for a professional) to tell at a glance which images are visible-light photographs and which are false-color images created with other wavelengths, each photo in the text is provided with an icon that identifies the wavelength of electromagnetic radiation used to capture the image and reinforces the connection between wavelength and radiation properties.

Compound Art
It is rare that a single image, be it a photograph or an artist's conception, can capture all aspects of a complex subject. Wherever possible, multiple-part figures are used in an attempt to convey the greatest amount of information in the most vivid way:

  • Visible images are often presented along with their counterparts captured at other wavelengths.
  • Interpretive line drawings are often superimposed on or juxtaposed with real astronomical photographs, helping students to really "see" what the photographs reveal.
  • Breakouts—often multiple ones—are used to zoom in from wide-field shots to closeups so that detailed images can be understood in their larger context.

Explanatory Captions
Students often review a chapter by "looking at the pictures." For this reason, the captions in this book are often a bit longer and more detailed than those in other texts.

H-R Diagrams and the Cosmic Distance Ladder
All of the H-R diagrams, assembled and drawn by Lola Judith Chaisson, are presented in a uniform format, using real data wherever possible. The goal is to make it easy for students to compare theoretical and observational results presented across several different chapters. The cosmic distance ladder is a theme that spans the text, and we use an evolving set of standard figures to illustrate how distance measurement techniques fit into and ultimately drive our understanding of the cosmos.

Acetate Overlays
Two unique sets of transparent acetate overlays dramatically illustrate two key pedagogical elements of the book. The H-R diagram overlays demonstrate to students how astronomers organize information about the stars and track their evolutionary histories. The cosmic distance scale overlays summarize, in simplified form, the main methods used by astronomers to chart their way among increasing scales in the universe.

Other Pedagogical Features

As with many other parts of our textbook, instructors have helped guide us toward what is most helpful for effective student learning. With their assistance, we have revised both our in-chapter and end-of-chapter pedagogical apparatus to increase its utility to students.

Learning Goals. Studies indicate that beginning students often have trouble prioritizing textual material. For this reason, a few (typically five or six) well-defined Learning Goals are provided at the start of each chapter. These help students to structure their reading of the chapter and then test their mastery of key facts and concepts. The Learning Goals are numbered and cross-referenced to key sections in the body of each chapter. This in-text highlighting of the most important aspects of the chapter also helps students to review. They are organized and phrased in such a way as to make them objectively testable, affording students a means of gauging their own progress.

Concept Checks. New to this edition, we have 1 incorporated into each chapter a number of "Concept Checks"—key questions that require the reader to reconsider some of the material just presented or attempt to place it into a broader context. Answers to the Concept Check questions are provided at the end of the book.

Cross-Links. In astronomy, as in many scientific disciplines, almost every topic seems to have some bearing on almost every other. In particular, the connection between the specifically astronomical material and the physical principles set forth early in the text is crucial. Practically everything in Chapters 6-28 of this text rests on the foundation laid in the first five chapters. For example, it is important that students, when they encounter the discussion of high-redshift objects in Chapter 25, recall not only what they just learned about Hubble's law in Chapter 24 but also refresh their memories, if necessary, about the inversesquare law (Chapter 17), stellar spectra (Chapter 4), and the Doppler shift (Chapter 3). Similarly, the discussions of the mass of binary-star components (Chapter 17) and of galactic rotation (Chapter 23) both depend on the discussion of Kepler's and Newton's laws in Chapter 2. Throughout, the discussion of new astronomical objects relies heavily on comparison with topics introduced earlier.

It is essential to remind students of these links so they can recall the principles on which later discussions rest and, if necessary, review them. To reinforce these connections, "cross links" have been inserted throughout the text—symbols that mark key intellectual bridges between material in different chapters. The links are denoted by the infinity symbol and, together with a section reference (a hyperlink on the accompanying CD-ROM), signal to students that the topic under discussion is related in some significant way to ideas developed earlier, and direct them to material that they might wish to review before proceeding.

Key Terms. Like all subjects, astronomy has its own special vocabulary. To aid student learning, the most important astronomical terms are boldfaced at their first appearance in the text. Each boldfaced key term is also incorporated in the appropriate chapter summary, together with the page number where it was defined. In addition, a full alphabetical glossary, defining each key term and locating its first use in the text, appears at the end of the book.

Planetary Data Boxes. Providing concise summaries of planetary properties within the body of each chapter, the data are repeated in the Appendix for easy reference. Similar data boxes are provided for both the Moon and the Sun. All planetary data are drawn from the database maintained by the Solar System Dynamics Group at the Jet Propulsion Laboratory.

Discovery Boxes. Exploring a 1 wide variety of interesting supplementary topics, these features have been expanded and renamed from the "Interludes" of previous editions to better reflect their goal of providing the reader with insight into how scientific knowledge evolves.

More Precisely Boxes. These provide quantitative treatments of subjects discussed qualitatively in the text, or explore the physics of astronomical processes in greater detail. Removing these more challenging topics from the main flow of the narrative and placing them within a separate modular element of the chapter design (so that they can be covered in class, assigned as supplementary material, or simply left as optional reading for those students who find them of interest) affords instructors greater flexibility in setting the level of their coverage.

Chapter Summaries. The chapter summaries, a primary review tool for the student, have been revised and streamlined for the fourth edition. All key terms introduced in each chapter are listed again, in context and in boldface, along with page references to the text discussion.

Questions, Problems, and Projects. Other elements of the end-of-chapter material have also seen substantial reorganization and expansion:

  • Each chapter incorporates 30 Self-Test questions, equally divided between "True/False" and "Fill-in-the-Blank" formats, designed to allow students to assess their understanding of the chapter material. Answers to all questions appear at the end of the book.
  • Each chapter also has 20 Review and Discussion questions (increased from 15 in the previous edition), which may be used for in-class review or for assignments. As with the Self-Test questions, the material needed to answer Review questions may be found within the chapter. The Discussion questions explore particular topics more deeply, often asking for opinions, riot just facts. As with all discussions, these questions usually have no single "correct" answer.
  • The end-of-chapter Problems have been expanded to contain 15 questions, spanning a somewhat broader range of difficulty than those in the previous edition. The level of difficulty is indicated on each problem. Answers to the Problems, particularly for the more sophisticated ones, are not necessarily contained verbatim within the chapter, but all the information required to solve the problems is in the text. Solutions for the odd-numbered problems are given at the end of the book. New for this edition, we have put algorithmic versions of the problems in a Practice Problems module of the text's Companion Website: The values in each problem change each time the student uses a chapter's problem set, thereby giving students unlimited practice in solving numeric problems.
  • Each chapter includes a few (2-4) Projects meant to get the student out of the classroom and looking at the sky, although some entail research in libraries or other extracurricular activities.

New to this edition are Collaborative Exercises 1 provided by Tim Slater at Montana State University. These interactive collaborative learning group activities are designed to encourage students to work together on reasoning tasks. They are designed specifically for use in the classroom, allow for multiple correct solution pathways, and give students some degree of choice in how to approach solving a complex, multifaceted problem. Most tasks require 7-12 minutes to complete.

Also new to this edition and provided by Tim Slater are "Researching on the Web" exercises. Using stable and maintained Internet resources hyperlinked from the Destinations module on the text's Companion Website, students are assigned analysis tasks using current and real-time Internet data sources. Quite different from the single correct answer tasks often used, many of these engaging tasks yield different but correct results for students accessing data resources on different days.

Finally, each chapter now concludes with SkyChart III Projects by Erik Bodegom and Sean Goe of Portland State University and Duane Ingram Of Rock Valley College. These exercises are based on the SkyChart III Student Version planetarium software, which is included as a separately executable program on the e-book CD in the back of the text. Square bullets preceding each exercise indicate its approximate level of difficulty. Appendix 4 provides general instructions for the software, and specific menu commands are included with each exercise. Instructor's notes for all the exercises are included in a password-protected part of the text's Companion Website.

e-Book CD and Companion Website

e-Book CD. Each copy of the text comes with a free e-book CD. This is a browser-based version of the text with extensive hyperlinks (over 3000 throughout the text), 61 videos integrated with relevant text discussions, and links to our Companion Website, which is organized by text chapter and updated monthly. We have added 12 new, exclusive animations from the Wright Center at Tufts University and redigitized all the videos and animations for larger size and higher resolution, and now they all have narrations. A script to facilitate use of the e-Book CD under Unix is available

SkyChart III Student Version. Also included on the e-Book CD as a separately executable program is a student version of the SkyChart III planetarium software by Southern Stars Systems. This planetarium program accurately simulates and displays the sky as it currently appears, as well as thousands of years in the past or future. The sky can be viewed from any place on Earth, or from any object in the solar system or beyond. The program includes a database of 300,000 fully customizable objects based on NASA's SKY2000 Master Star Catalog, showing all stars up to about magnitude 10.

Companion Website. Our Companion Website at our site organizes Destinations (links to related websites), additional Images and Animations, Multiple Choice, True/False, and Labeling exercises, and algorithmic versions of the text's end-of-chapter Problems on a chapter-by-chapter basis. The Destinations, Images, and Animations modules are updated monthly to keep links current and provide information on significant new discoveries. All of the exercises and problems are interactive, meaning that the student answers the questions on-line and then receives immediate scoring and feedback, including text section references for any areas the student needs to study further if they answered a given question incorrectly.

Additional Supplementary Material

This edition of Astronomy Today is accompanied by an outstanding set of instructional aids.

Comets. Published annually at the beginning of each academic year and available free to adopters, Comets is a unique kit that includes a collection of slides, videos, and New York Times articles on events and discoveries that have occurred since the publication of the prior year's Comets kit. The slide kit contains 28 new slides from NASA, JPL, STScI, GSFC, HST Comet LINEAR Investigation Team, APL, JPL, ESA, Hubble Heritage Team, IPAC, European Southern Observatory, SDSS/Astrophysical Research Consortium, and the U.S. Department of Defense. Custom animations prepared by the Wright Center for Science Visualization and many other videos of new discoveries and animations from various sources, including NASA, STScI, APL/NRL, ESA, Stanford Lockheed Institute for Space Research, and JPL are provided in both CD and DVD formats. The collection of New York Times articles, called "Themes of the Times," is published twice yearly and is available free in quantity for your students using either Chaisson/McMillan text. A newsletter provides a cross reference between all the materials in the Comets kit and corresponding chapters of both Chaisson/McMillan texts, as well as annotations describing the subject and source of each slide and video in the kit.
ISBN 0-13-093801-7

Instructor's Resource Manual. By Leo Connolly (California State University at San Bernardino). This manual provides an overview of each chapter, pedagogical tips, useful analogies, suggestions for classroom demonstrations, writing questions, answers to the end-of-chapter Review and Discussion questions and Problems. New features include an expanded introduction with an overview of how to utilize the IRM, an index of demonstrations, applications of the writing questions, sample assignments, discussion of common student misconceptions, teaching notes for the collaborative exercises, and a list of selected readings for each chapter.
ISBN 0-13-093796-7

Media Portfolio CD-ROM. By Suzanne Willis (Northern Illinois University). This flexible, easy-to-use tool contains a wealth of photographs, line art, animations, and videos to use in class lectures. Instructors can easily search, access, and organize the materials according to their lecture outlines and add their own visuals and lecture notes. The hybrid CD contains all of the line art and photographs from Astronomy Today 4e, as well as the animations and videos that are on the e-Book CD in the back of the student text. In addition, the Image Viewer incorporates slides from the current and past editions of Comets. ISBN 0-13-093791-6

Acetates and Slides. A set of approximately 260 images from the text-almost double the number offered for the third edition-are available as a package of color acetates or 35mm slides, and are available free to qualified adopters.
ISBN 0-13-093780-0 (Slide set)
ISBN 0-13-093803-3 (Transparency pack)

Test Item File. An extensive file of over 2600 test questions, newly compiled and revised for the fourth edition by Wayne Wooten (Pensacola Junior College), is offered free upon adoption. Available in both printed and electronic formats (Macintosh or Windows format). The fourth edition Test Item File has been thoroughly revised, including many new Multiple Choice and Essay questions for added conceptual emphasis. Overall, approximately 600 new questions have been added.
ISBN 0-13-093798-3

Prentice Hall Custom Test. Available for Macintosh and Windows, Prentice Hall Custom Test allows educators to create and tailor the exam to their own needs. With the On-line Testing option, exams can also be administered on-line, and data can then be automatically transferred for evaluation. A comprehensive desk reference guide is included, along with on-line assistance.
ISBN 0-13-093797-5
(Macintosh) ISBN 0-13-093799-1 (Windows)

Science on the Internet. By Andrew Stull and Harry Nickla. A guide to general science resources on the Internet. Everything you need to know to get yourself on-line and browsing the World Wide Web!
ISBN 0-13-028253-7

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