A Journey into Gravity and Spacetime (A Scientific American Library Paperback) [Paperback]

John Archibald Wheeler (Author)

Book Description

Series: A Scientific American Library Paperback | Publication Date: June 7, 1999

Gravity is not a force acting at a distance. It is mass gripping spacetime, telling it how to curve, and spacetime gripping mass, telling it how to move. According to preeminent physicist John Archibald Wheeler, gravity makes the closest connection between the world we see around us and the inner-most workings of the universe.

In this imaginative volume, Wheeler explores gravity and spacetime by applying Einstein's battle-tested theory to both familiar and exotic phomomena--everything from flying tennis balls, to hurling gravity waves from crashing stars, the motion of the planets, and the collapse of a star into a black hole. It's a provocative, revealing, fully engaging scientific journey led by a frontline participant in the most important work in physics in the last 50 years.

Editorial Reviews

Review

"Journey into Gravity and Spacetime is a colorful and imaginative introduction to a topical subject, delightfully produced. Wheeler complements his subject by continually demonstrating its underlying simplicity, in the face of the apparent magnitude of the task. I recommend this book to anyone wishing to gain an honest insight into the wonders of gravity and the physics of spacetime." -- Times Higher Education Supplement

"A thorough exploration of Einstein's geometric theory of gravity and its implications for the relationship between mass and spacetime." -- Nature

"I am reading Wheeler so that I can write more intelligently about Einstein's general theory of relativity." -- Isaac Asimov, Night Table Reading, Vanity Fair

"Wheeler takes the reader into a world of space-time, gravitational waves, and black holes. As one of the foremost contributors to the study of relativity, and as the person mainly responsible for the resurgence of interest in general relativity in the 1960s, he is well qualified to write such a book. . . . Strongly recommended." -- Choice

About the Author

John Archibald Wheeler is Joseph Henry Professor Emeritus at Princeton University and was, until his retirement, Blumberg Professor of Physics and Director, Center for Theoretical Physics at the University of Texas at Austin. A past president of the American Physical Society, he is a recipient of the Enrico Fermi Award (1968), the National Medal of Science (1971), the Niels Bohr International Gold Medal (1982) and the Wolf Prize (1997).

Product Details

• Paperback: 258 pages
• Publisher: W. H. Freeman (June 7, 1999)
• Language: English
• ISBN-10: 0716760347
• ISBN-13: 978-0716760344
• Product Dimensions: 9.3 x 8.5 x 0.7 inches
• Shipping Weight: 1.4 pounds
• Average Customer Review: 4.2 out of 5 stars  See all reviews (5 customer reviews)
• Amazon Best Sellers Rank: #1,302,214 in Books (See Top 100 in Books)

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Customer Reviews

Most Helpful Customer Reviews

73 of 75 people found the following review helpful:

5.0 out of 5 stars A stunner of a book, December 12, 1999

By 

Tom Mahood (Irvine, CA) - See all my reviews

This review is from: A Journey into Gravity and Spacetime (A Scientific American Library Paperback) (Paperback)

This is truely an amazing book. Wheeler does for General Relativity what Hawking did for Cosmology in "A Brief History of Time", and in some sense they are similar books. However Wheeler has a unique, quirky style of writing that makes the book an entertaining adventure to read.

Wheeler is able to pull off a major accomplishment: He explains Einstein's General Relativity in a clear, straightforward manner, with a minimum of math. It's "conventional wisdom" that General Relativity is seriously serious stuff, the domain of hardcore Physics geeks. That doesn't faze Wheeler. He leads the reader along, gleefully pointing out the scenery, making it all look quite simple and understandable. And then all of a sudden, when you least expect it, you find he's derived and presented Einstein's field equations with only a teensy-tiny bit of algebra! Even if you know this stuff already, his presentation makes you think about it with a new perspective.

And did I mention the illustrations? They are really exceptional.

If you have any interest or dealings with GR, ya gotta have this book!

14 of 14 people found the following review helpful:

4.0 out of 5 stars Awesome: from an MSEE, August 25, 2002

By 

A Customer (Brecksville, OH United States) - See all my reviews

This review is from: A Journey into Gravity and Spacetime (A Scientific American Library Paperback) (Paperback)

The interrelation of gravity and spacetime is a formidable subject to describe; the author does so with excellence. The diagrams and charts reinforce the understanding.

Unfortunately when a key subject left me rather clueless, (Boundary of a Boundary) I spent quite a few frustrated hours being uncertain on whether or not to continue reading without the support of the material on those pages. As it turned out, the subject became clearer once I read on and returned again. I never did grasp it as completely as the rest of the book.

The book contains the most enlightening description of transverse wave propagation I've ever seen. It also helps solidify one's understanding of interval and relativity.

Not a book to be read overnight.

26 of 30 people found the following review helpful:

5.0 out of 5 stars The author's mind has no boundary...., February 3, 2002

By 

Dr. Lee D. Carlson (Baltimore, Maryland USA) - See all my reviews
(VINE VOICE)    (HALL OF FAME REVIEWER)    (REAL NAME)   

This review is from: A Journey into Gravity and Spacetime (A Scientific American Library Paperback) (Paperback)

This author is one of the most briliant, the most optimistic, and the most enthusiastic writer in all of physics, and in this book, his competence as a physicist and his deep fascination with the physical world is brought out dramatically. He is clearly a man who is feeling a powerful sense of exhiliration of the discoveries now taking place in all areas of knowledge. His foundation and his theme in the book is a simple geometric principle, namely that the boundary of a boundary is zero. He then guides the reader, assumed to have a rudimentary knowledge of mathematics, in a splendid presentation of the power of this principle in gravitational physics.

The first chapter is an overview of the history behind the subject, via the work of people who contributed to our current understanding of gravity. And then, with a masterfull use of diagrams he gives the reader a taste of the simplicity of the equivalence principle and the need to tack on an additional dimension (time) to the 3-dimensional space of everyday experience. The Pound-Rebka experiment is discussed as one that illustrates the idea of the spacetime interval, and the role of time dilation is discussed via the possibility of practical space travel. And such enthusiasm in his dialog: "the universe will grow ever more exciting", he says, and looking at the developments now taking place in today's science, he is indeed correct.

Chapter 4 gives a fascinating overview of what the author calls the boomerang, which illustrates the action of curvature on nearby test masses. This thought experiment involves the motion of a spacecraft through an imaginary tunnel through the Earth. The author analyzes the motion from the standpoint of Newtonian physics and general relativity. Curvature as the "grammar of gravity" is the topic of the next chapter, with illustrations of the paths of ants on spaces of zero, positive, and negative curvature. A very intuitive treatment of parallel transport around a closed path on a curved surface is given. The tides are discussed as a natural manifestation of the gravitational influence of the Moon on Earth.

Must difficult for a layman to understand is how spacetime acts on masive objects, but the author explains it brilliantly in the next chapter, taught via the concept of "momenergy". This entity is a 4-vector, and the author uses it to show how its creation in a spacetime region can be written as the sum of 8 terms, reflecting the fact that the "boundary" of a four-dimensional block in spacetime consists of eight three-dimensional cubes. That the contents of these cubes sum to zero is the famous "boundary of a boundary is zero", which is discussed in the next chapter. This chapter is one of the best explanations ever given (at this level) of the physics behind spacetime curvature and massive objects. The actual mathematical quantification of curvature is detailed in chapters 8 and 9, using elementary mathematics. The author discusses nicely the famous Scharwzschild geometry.

Concepts of a more concrete nature are discussed in chapter 10, wherein the author discusses the famous Pound-Rebka experiment and planetary motion. This is followed by a discussion of the elusive gravitational waves in chapter 11. Again with a clever use of illustrations, the author explains the transverse property of gravitational waves, and compares gravitational waves with electromagnetic waves. The role of the quadrupole moment in the creation of gravitational waves is brought out briliantly by the author. He discusses briefly various attempts to detect gravitational waves.

Black holes are the topic of chapter 12, wherein the famous Penrose process for extracting energy from a black hole is discussed, and the "no-hair" theorem for black holes. A neat symbolic representation of the Bekenstein number of a black hole is given. The role of the Hawking process, connection quantum processes with the physics of black holes is briefly discussed. The author ends the book with a look at the expansion of the universe, the missing mass problem, and another very interesting topic that has gained much attention recently: the concept of gravitomagnetism. This is a "weak-field" prediction of general relativity, and predicts that the rotation of the Earth should influence the motion of orbiting satellites. This topic is currently bringing together ideas such as the quantum Zeno effect, Mach's principle, and the notorious "frame dragging" effect in general relativity. Experiments do measure it are currently in play and in the proposal stage, namely the LAGEOS and LAGEOS II experiments, which measure the gravitomagnetic orbital perturbation, which is known as the Lense-Thirring effect.