Synopses & Reviews
This engaging text takes the reader along the trail of light from Newton's particles to Einstein's relativity. Like the best detective stories, it presents clues and encourages the reader to draw conclusions before the answers are revealed. The first seven chapters cover the behavior of light, Newton's particle theory, waves and an electromagnetic wave theory of light, the photon, and wave-particle duality. Baierlein goes on to develop the special theory of relativity, showing how time dilation and length contraction are consequences of the two simple principles underlying the theory. An extensive chapter derives the equation E = mc2 clearly from first principles and then explores its consequences.
Review
' ... I find Baierlein's approach highly congenial. Indeed I expect that some of the fascinating stories I learned from him and, more importantly, some of the excellent tricks he has taught me (particularly several neat and simple gedanken experiments that lead to relativistic momentum) will make my own course very much better. I can offer no higher praise. N. David Mermin, American Journal of Physics
Review
'The exposition is absolutely sound and lucid. The discussion is never allowed to get too abstract, being filled with fine descriptions of modern experimental demonstrations of the fundamental relativistic effects. I could quite happily teach a course from this book, and I can recommend it warmly.' American Journal of Physics
Review
'The book has many excellent features ... includes some recent and quite interesting experiments not found in other textbooks ... This is a fine textbook that should give students a real 'feel' for what physics is and how it progresses ... It also makes these topics, which are inherently difficult, as easy as possible for students to grasp.' Joseph F. Mulligan, JCST
Review
'Although written for classroom use, an excellent introduction to some of the important ideas of modern physics that should be both interesting and accessible to the proverbial intelligent general reader ... Highly recommended for all college and university libraries.' K. L. Schick, Choice
Review
'... a pleasure ... it is a must for every library.' Peter Borcherds, European Journal of Physics
Review
'This undergraduate text is an excellent introduction to some of the important ideas of modern physics that should be both interesting and accessible also to the general reader.' GLASS Science and Technology
Synopsis
This undergraduate text takes the non-science student from Newton's particles to Einstein's relativity.
Synopsis
This undergraduate text takes the non-science student from Newton's particles to Einstein's relativity.
Synopsis
This undergraduate text takes the reader along the trail of light from Newton's particles to Einstein's relativity. Like the best detective stories, it presents clues and encourages the reader to draw conclusions before the answers are revealed. The first seven chapters describe how light behaves, develop Newton's particle theory, introduce waves and an electromagnetic wave theory of light, discover the photon, and culminate in the wave-particle duality. The book grew out of a popular one-semester course for non-science students.
About the Author
RALPH BAIERLEIN received his PhD from Princeton University; his thirty seven years of classroom teaching were spent at Harvard and at Wesleyan University, Connecticut. He has published papers in astrophysics, cosmology and relativity theory. For eight years he served as book review editor of the American Journal of Physics, and has written many papers related to the teaching of physics. In 1996 he was elected a fellow of the American Physical Society.
Table of Contents
Preface; 1. How light behaves; 2. Newton's particle theory; 3. A wave theory of light; 4. Interference; 5. Electromagnetic waves; 6. The photon; 7. The wave-particle duality; 8. Does the speed of light depend on the motion of the source of light?; 9. The principles of the Special Theory of Relativity; 10. Time dilation and length contraction; 11. E=mc2; 12. The twins; 13. The Lorentz transformations; 14. Space and time; Glossary; Appendices; Index.