Nature's Blueprint by Dan Hooper | Hardcover | Barnes & Noble
Nature's Blueprint: Supersymmetry and the Search for a Unified Theory of Matter and Force

Nature's Blueprint: Supersymmetry and the Search for a Unified Theory of Matter and Force

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by Dan Hooper

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The first accessible book on a theory of physics that explains the relationship between the particles and forces that make up our universe.

For decades, physicists have been fascinated with the possibility that two seemingly independent aspects of our world—matter and force—may in fact be intimately connected and


The first accessible book on a theory of physics that explains the relationship between the particles and forces that make up our universe.

For decades, physicists have been fascinated with the possibility that two seemingly independent aspects of our world—matter and force—may in fact be intimately connected and inseparable facets of nature. This idea, known as supersymmetry, is considered by many physicists to be one of the most beautiful and elegant theories ever conceived. According to this theory, however, there is much more to our universe than we have witnessed thus far. In particular, supersymmetry predicts that for each type of particle there must also exist others, called superpartners. To the frustration of many particle physicists, no such superpartner particles have ever been observed. As the world's most powerful particle accelerator—the Large Hadron Collider—begins operating in 2008, this may be about to change. By discovering the forms of matter predicted by supersymmetry, this incredible machine is set to transform our current understanding of the universe's laws and structure, and overturn the way that we think about matter, force, space, and time.

Nature's Blueprint explores the reasons why supersymmetry is so integral to how we understand our world and describes the incredible machines used in the search for it. In an engaging and accessible style, it gives readers a glimpse into the symmetries, patterns, and very structure behind the universe and its laws.

Editorial Reviews

New Scientist
“As the world’s most powerful particle accelerator revs up, Dan Hooper’s book is essential reading.”
Author Dan Hooper is a member of the theoretical astrophysics group at the famed Fermi National Accelerator Laboratory, but don't let those elite credentials frighten you away from this quite accessible book. In Nature's Blueprint, Hooper sets out to explain supersymmetry, an advanced theory of physics that explains the relationship between the particles and forces that make up our universe. Until now, this theory has remained a wondrously beautiful, elegant idea that could not be tested, but that all changed when the Large Hadron Collider, the world's most powerful accelerator ever, went online this summer. Timely, cutting-edge news about the nature of our universe.
Kirkus Reviews
An enthusiastic, mostly comprehensible account of a popular theory many scientists believe will unite two of the few remaining separate elements in the universe: matter and energy. Though more than 30 years of research has turned up no evidence for supersymmetry, Hooper (Dark Cosmos: In Search of Our Universe's Missing Mass and Energy, 2006, etc.), an astrophysicist at the Fermi National Accelerator Laboratory, does not allow that reality to dampen his enthusiasm. The author begins with Galileo and proceeds through Newton, Maxwell and Einstein, finishing with the great 20th-century quantum theorists from Planck to Feynman who laid out the Standard Model, a dazzlingly successful picture of the particles and forces that make up the universe. Although a magnificent achievement, the Standard Model does not explain how gravity fits in with other forces or why the universe's elements (electrons, protons, quarks) have their particular properties (charge, mass, spin). Since the '70s, physicists have tried to close these gaps, and supersymmetry is a leading candidate: a complex theory that requires a host of new, weird and so far undetected subatomic particles. Hooper pins his hopes on the Large Hadron Collider, the world's most powerful particle accelerator now beginning operation in Switzerland, which may or may not succeed in producing these particles. Like similar books in this arena, such as Brian Greene's The Elegant Universe (1999), Hooper does a fine job explaining historical physics and newer concepts (quantum theory, relativity), but he has more difficulty explaining supersymmetry for a general audience. Many of his witty, educational anecdotes and parallels are so simplified thatreaders may not make the connection. Some concepts, such as gauge theory or R-parity, will remain challenging to readers without a background in physics. Veteran readers who do not expect the universe to reveal its secrets easily will put in the work required to finish this energetic exploration of modern physics. Agent: Antony Harwood/Antony Harwood Literary Agency

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HarperCollins Publishers
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6.10(w) x 9.10(h) x 1.40(d)

Read an Excerpt

Nature's Blueprint
Supersymmetry and the Search for a Unified Theory of Matter and Force

Chapter One


The real voyage of discovery consists not in seeking new landscapes but in having new eyes.
Marcel Proust

To the curious, nothing is more exciting than discovery. Nothing is more powerful, and nothing is more awe inspiring. There is something truly and profoundly irresistible about the act of learning secrets—in knowing what had once been hidden. Scientists, and science itself, are driven by this fascination. The secrets that science seeks are those belonging to nature. Nature presents us with the grandest of all puzzles. With every new advance or insight, we get a further glimpse into the inner workings of our world—the very blueprint of nature. Today, we are preparing to sneak a deeper and more detailed glimpse at this blueprint. We are poised upon the very edge of discovery.

For more than thirty years, physicists have been investigating a theory known as supersymmetry. Supersymmetry is a framework—a principle, really—that describes and explains the relationship between two of the most fundamental concepts in physics: matter and force. This is a theory possessing the highest degree of mathematical beauty and elegance. On a more practical note, the presence of supersymmetry also has the ability to solve many of the long-standing problems of particle physics. To date, however, experimental confirmation that supersymmetry actually exists has remained elusive. If or when evidence for supersymmetry is finally observed, it will be a monumental, era-definingmoment in the history of science, on par with the greatest discoveries of Einstein, Newton, and Galileo. It will be the discovery of a lifetime.

The theory of supersymmetry predicts that many unseen kinds of matter must exist. This matter takes the form of particles called superpartners. Despite the efforts of many hundreds of physicists conducting experiments in search of these particles, no superpartners have ever been observed or detected. They remain hidden, at least for the time being. This has had little effect in deterring the theoretical physicists who passionately expect nature to be formulated in this way—to be supersymmetric. To many of these scientists, the ideas behind supersymmetry are simply too beautiful and too elegant not to be part of our universe. They solve too many problems and fit into our world too naturally. To these true believers, the superpartner particles simply must exist. That they remain hidden is merely a standing challenge to future physicists and the experiments they conduct.

Supersymmetry may not remain hidden from us for much longer. In fact, many of the world's most prominent physicists think it likely that the elusive superpartners are about to be revealed. To accomplish this feat, a remarkable machine has been built. This machine, called the Large Hadron Collider—the LHC for short—is an enormous particle accelerator located beneath and around the city of Geneva, Switzerland, and extending across the border into France. Through a circular underground tunnel, seventeen miles in circumference, protons will be accelerated by ultra-powerful magnets to amazing speeds—99.9999991 percent of the speed of light, or more than 670 million miles per hour. When two beams of protons are collided head-on, so much energy will be compressed into one place at one time that entirely new and unknown forms of matter will be able to be brought into existence. Among these new forms of matter, many believe, will be the superpartner particles predicted by the theory of supersymmetry. With this incredible machine, humankind will finally learn whether supersymmetry is—or is not—built into the very fabric of our universe.

Beauty can be a difficult thing to understand, and an even more difficult thing to define. Although we all have some idea of what it means for something to be beautiful, it is very hard to put our finger on the appeal of a beautiful sound, image, or idea. Whether found in a da Vinci masterpiece, a Beethoven symphony, a Shakespeare sonnet, or a magnificent sunset, many of us feel that we can recognize beauty when we see or hear it. Ultimately, however, we also recognize that this is a subjective quality—something of ourselves that we project onto that which we perceive. Beauty truly is in the eye of the beholder.

This intrinsic subjectivity can even be found in the paragraph you just read. In it, I chose to use da Vinci, Beethoven, and Shakespeare as examples of artistic beauty because I somehow imagine that they might relate to most people, including those reading this book. Personally, I find far more beautiful the works of Pablo Picasso, the Rolling Stones, and John Steinbeck. You probably have other feelings of your own about beauty. Whether you find the work of Beethoven, the Rolling Stones, or Celine Dion more beautiful, you are neither right nor wrong.Subjectivity is the essence of beauty.

So if beauty is purely subjective, how can science, which strives to be objective, find something—such as the idea of supersymmetry—to be beautiful? Science has never produced an equation that could be used to calculate the quantity of beauty possessed by anything. Nor will it in the future. Beauty is not something that can be quantified. Perhaps sociologists could scientifically conduct surveys to learn how beautiful a subject appears to a given individual or set of individuals, but this tells us something only about the people being surveyed, and not about the subject itself. It is absolutely beyond the reach of science to judge beauty.

Although beauty may be beyond the purview of science, it is certainly not beyond the nature of scientists. Scientists are—beneath their lofty goals of objectivity—creatures of flesh and blood like everyone else. And like everyone else, we scientists see beauty in the world all around us. We may not be able to prove rigorously that one scientific idea is more beautiful than another, but we do experience and appreciate beauty. Like all human beings, we feel that we know beauty when we see it.

Nature's Blueprint
Supersymmetry and the Search for a Unified Theory of Matter and Force
. Copyright © by Dan Hooper. Reprinted by permission of HarperCollins Publishers, Inc. All rights reserved. Available now wherever books are sold.

Meet the Author

Dan Hooper is an associate scientist in the theoretical astrophysics group at the Fermi National Accelerator Laboratory in Batavia, Illinois, where he investigates dark matter, supersymmetry, neutrinos, extra dimensions, and cosmic rays. Originally from Cold Spring, Minnesota, Dr. Hooper received his PhD at the University of Wisconsin and was a postdoctoral fellow at the University of Oxford in the United Kingdom. He is the author of Dark Cosmos: In Search of our Universe's Missing Mass and Energy, a SEED magazine Notable Book.

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