Book contents
- Frontmatter
- Contents
- Preface
- 1 Special relativity
- 2 Vector analysis in special relativity
- 3 Tensor analysis in special relativity
- 4 Perfect fluids in special relativity
- 5 Preface to curvature
- 6 Curved manifolds
- 7 Physics in curved spacetime
- 8 The Einstein field equations
- 9 Gravitational radiation
- 10 Spherical solutions for stars
- 11 Schwarzschild geometry and black holes
- 12 Cosmology
- Appendix A Acronyms and definitions
- Appendix B Useful results
- References
- Index
Preface
Published online by Cambridge University Press: 18 December 2015
- Frontmatter
- Contents
- Preface
- 1 Special relativity
- 2 Vector analysis in special relativity
- 3 Tensor analysis in special relativity
- 4 Perfect fluids in special relativity
- 5 Preface to curvature
- 6 Curved manifolds
- 7 Physics in curved spacetime
- 8 The Einstein field equations
- 9 Gravitational radiation
- 10 Spherical solutions for stars
- 11 Schwarzschild geometry and black holes
- 12 Cosmology
- Appendix A Acronyms and definitions
- Appendix B Useful results
- References
- Index
Summary
General relativity is a beautiful theory, our standard theory of gravity, and an essential component of the working knowledge of the theoretical physicist, cosmologist, and astrophysicist. It has the reputation of being difficult but Bernard Schutz, with his groundbreaking textbook, A First Course in General Relativity (first edition published in 1984, current edition in 2009), demonstrated that GR is actually quite accessible to the undergraduate physics student. With this solution manual I hope that GR, using Schutz's textbook as a main resource and perhaps one or two complementary texts (see recommendations at the end of this preface), is accessible to all “technically minded self-learners” e.g. the retired engineer with some time to devote to a dormant interest, a philosopher of physics with a serious interest in deep understanding of the subject, the mathematics undergraduate who wants to become comfortable with the language of the physicist, etc.
You can do it too!
I'm speaking with some experience when I say that an engineer can learn GR and in particular starting with Schutz's textbook. My bachelor's and master's degrees are in engineering and I started learning GR on my own when my academic career had gained enough momentum that I could afford a bit of time to study a new area in my free time. I must admit it wasn't always easy. I personally found the explanations of mathematics in the excellent textbook by Misner, Thorne and Wheeler (1973) more confusing then helpful. (In retrospect I'm at a loss to explain why; in no way do I blame the authors.) Soon two children arrived miraculously in our household, free time became an oxymoron, but with the constant reward I found from beavering away at Schutz's exercises I continued to learn GR, albeit slowly and with screaming (not always my own) interruptions. In his autobiography John A. Wheeler explains that he started learning GR in the 1940s when he finally got the chance to teach the subject. Similarly the real breakthrough for me came when I was offered the possibility to teach the subject to third-year undergraduate students at the Université de Bretagné Occidentale in Brest, France. Suddenly my hobby became my day job, fear of humiliation became my motivation, and most significantly I was forced to view the subject from the student's point of view.
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- Publisher: Cambridge University PressPrint publication year: 2016