- STAFF PICKS
- GIFTS + GIFT CARDS
- SELL BOOKS
- FIND A STORE
This item may be
Check for Availability
The Black Hole War: My Battle with Stephen Hawking to Make the World Safe for Quantum Mechanics
Synopses & Reviews
What happens when something is sucked into a black hole? Does it disappear? Three decades ago, a young physicist named Stephen Hawking claimed it did-and in doing so put at risk everything we know about physics and the fundamental laws of the universe. Most scientists didn't recognize the import of Hawking's claims, but Leonard Susskind and Gerard t'Hooft realized the threat, and responded with a counterattack that changed the course of physics. THE BLACK HOLE WAR is the thrilling story of their united effort to reconcile Hawking's revolutionary theories of black holes with their own sense of reality-effort that would eventually result in Hawking admitting he was wrong, paying up, and Susskind and t'Hooft realizing that our world is a hologram projected from the outer boundaries of space.
A brilliant book about modern physics, quantum mechanics, the fate of stars and the deep mysteries of black holes, Leonard Susskind's account of the Black Hole War is mind-bending and exhilarating reading.
"Bets made over a beer between scientists rarely make the headlines, but in 2004 Stephen Hawking conceded that he'd lost a bet and that a view he had held for 30 years was wrong. According to Stanford physicist Susskind (The Cosmic Landscape), one of the leaders of the anti-Hawking camp, the argument was a simple one: if information falls into a black hole, is it lost forever? Hawking's theory that information is destroyed undermined everything scientists thought they knew about quantum physics. Susskind gives readers a course in black holes, quantum physics and string theory as he explains his belief that information cannot be destroyed. Along the way he introduces bizarre theories like the Holographic Principle (which he helped develop), claiming that the third dimension is an illusion and that energy and matter are just forms of information. Susskind also profiles two hot-shot South American physicists who helped deliver the coup de grace to Hawking's argument. Black hole and Hawking fans should go for this book, even if the great physicist was wrong. B&w illus. (July 7)" Publishers Weekly (Copyright Reed Business Information, Inc.)
What is it about black holes, anyway? To most scientists, a black hole is something like a duck-billed platypus in the sky: weird, unusual, esoteric and not all that connected to real life. On the other hand, people just can't seem to get enough of them. Any teacher will tell you that it's a whole lot easier to get a class interested in black holes than in DNA, even though the latter will most assuredly... Washington Post Book Review (read the entire Washington Post review) have a real impact on their future and the former will not. Oh well, if you must learn about black holes, you could do a lot worse than to pick up this engagingly written book. Stanford physicist Leonard Susskind provides a marvelous introduction to the subject that is both readable and easy to understand. Or at least as easy as something involving the two great 20th-century advances in science — relativity and quantum mechanics — can possibly be. You see, until the end of the 19th century, scientists who thought about the fundamental structure of the universe had concentrated on normal-sized objects moving at normal speeds (think billiard balls). We associate this kind of science with Isaac Newton. Then, in rapid succession, the 20th century brought two revolutions. The first, which dealt with objects moving near the speed of light or having very large mass, was relativity, the brainchild of Albert Einstein. The second revolution came when people starting thinking about very small objects, such as the stuff inside the atom. The resulting theory is called quantum mechanics and was developed by a small group of young scientists in the 1920s, the most familiar probably being Werner Heisenberg of uncertainty-principle fame. One note in passing: These revolutions didn't so much replace Newton as extend his reach. Like a tree, mature sciences grow by adding new material while leaving their heartwood intact. With increasing urgency over the past 50 years, theoretical physicists have tried to tie these two great 20th-century advances together, to produce what Nobel Laureate Steven Weinberg calls "The Final Theory." So far, we have not been successful. But if you can't bring the two fields together, you would at least like to know that they don't contradict each other, that they are mutually consistent. And this is where Susskind's "war to make the world safe for quantum mechanics" comes in, because for a period of almost 20 years, it looked as if there could well be a fundamental contradiction between the basic postulates underlying the two theories. At least that's what Stephen Hawking argued, and when Hawking talks, physicists listen. Remember that a black hole is an object so compact and so massive that nothing, not even light, can escape from it. It is, in fact, a kind of one-way gate in the universe: Stuff can fall in, but nothing can come out. Because it involves both a large mass and extremely high energy, the black hole forms a kind of nexus where both relativity and quantum mechanics come into play. Thus, if there are going to be problems joining these two fields, they are likely to turn up in the behavior of black holes. In 1983, Hawking proved that, against all expectations, black holes are not eternal. In fact, over unimaginably long spans of time, they evaporate, more or less like a puddle of water on a sunny day. And that's when the "war" started, because if a black hole evaporates (and everyone agrees that it will), what happens to all the information that was carried by the stuff that fell in? That information might include things like the mass of the particles that fell in, their spin, their identity and all kinds of other properties. Hawking argued that this information was lost forever, that the black hole was truly a one-way street to oblivion. The problem is that one of the basic laws of quantum mechanics is that information cannot be lost. (I should point out that in quantum mechanics the term "information" has a technical meaning, and that losing it is more of a problem than, say, losing the shopping list you need at the supermarket.) In the case of the evaporating puddle, for example, it is theoretically possible to reconstruct the puddle by looking at the air molecules above the spot where it used to be. Hawking argued, however, that with the material that evaporated from the black hole, no such thing is possible, that the information simply disappeared. Susskind's account of his reaction to this claim and of driving home from the conference where it was first presented, distractedly scribbling equations in the frost on his windshield, beautifully describes how disturbing the idea of disappearing information was to those of us steeped in the lore of the quantum. In the end, Susskind and his colleagues were able to resolve this dilemma and, in the words of the subtitle, "make the world safe for quantum mechanics." I won't spoil the book for you by telegraphing the ending. Suffice it to say that it involves a tour through the whole arcane menagerie of modern physics — quarks, gluons, branes, strings. And this illustrates the main problem faced by authors of this sort of book. Black hole astrophysics is about as far from everyday experience as you can get, which means that the author has to spend a lot of time bringing the reader up to speed (indeed, it takes Susskind almost 200 pages). Even when, as in this book, there is virtually no mathematics, there is an overwhelming number of strange new concepts. Consequently, I recommend digesting this book in small segments, allowing each new concept to settle in before moving on. In the end, "The Black Hole Wars" is as good an introduction as you're going to find to the strange world of black hole astrophysics. Add that to the chance to ride along as real scientists resolve a fundamental issue and you have the makings of a great read. James Trefil is Clarence J. Robinson Professor of Physics at George Mason University. His most recent book is "Why Science." Reviewed by James Trefil, Washington Post Book World (Copyright 2006 Washington Post Book World Service/Washington Post Writers Group)
(hide most of this review)
Book News Annotation:
Susskind (theoretical physics, Stanford U.) offers his account of the debate he and fellow physicists Hawking and Gerard 't Hooft have had over the nature of black holes, and the underlying understanding of the entire universe. He emphasizes that this is a true scientific controversy, not a squabble among scientists and, for example, intelligent design mongers or corporate global-warming deniers. One difference is that at the end, everyone wins. Annotation ©2008 Book News, Inc., Portland, OR (booknews.com)
"The Black Hole War" is the thrilling story of Susskind's effort to reconcile Stephen Hawking's revolutionary theories of black holes with his own sense of reality--an effort that would eventually result in Hawking admitting he was wrong.
At the beginning of the 21st century, physics is being driven to very unfamiliar territory--the domain of the incredibly small and the incredibly heavy. The new world is a world in which both quantum mechanics and gravity are equally important. But mysteries remain. One of the biggest involved black holes. Famed physicist Stephen Hawking claimed that anything sucked in a black hole was lost forever. For three decades,
THE BLACK HOLE WAR will explain the mind-blowing science that finally won out, and the emergence of a new paradigm that argues the world--this catalog, your home, your breakfast, you--is actually a hologram projected from the edges of space.
About the Author
Leonard Susskind has been the Felix Bloch Professor in theoretical physics at Stanford University since 1978. The author of The Cosmic Landscape, he is a member of the National Academy of Science and the American Academy of Arts and Sciences, and the recipient of numerous prizes including the science writing prize of the American Institute of Physics for his Scientific American article on black holes. He lives in Palo Alto, California.
What Our Readers Are Saying
Biography » Science and Technology