The hidden reality Parallel universes and the deep laws of the cosmos

Review by Choice Review

Greene (Columbia Univ.) is an accomplished theoretical physicist and author of two earlier books on cosmology for general audiences (The Fabric of the Cosmos, CH, Jul'04, 41-6506; The Elegant Universe, CH, Jul'99, 36-6332). In The Hidden Reality, the author tries to explain string theory to the general reader. This is an extremely difficult goal, for string theory is an attempt to unify the theories of gravity and quantum mechanics by postulating an additional seven dimensions to be added to the three spatial and one time dimension that are familiar to us all. The additional dimensions, together with the imposition of quantum mechanics, are beyond our ken and can only be described using some very complex mathematics. To describe the resulting 11-dimensional structures, scientists working in this field have developed a rich vocabulary that echoes more commonplace concepts. But even with these tools, describing string theory to a nonspecialist is very difficult. Greene does an admirable job, and the book is worth reading for that reason. He also includes a very thoughtful chapter on the meaning of the concept of scientific explanation in the context of the hidden dimensions that are at the heart of string theory. Summing Up: Highly recommended. All academic and general readers. A. Spero formerly, University of California

Copyright American Library Association, used with permission.

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Review by New York Times Review

MORE has been learned about the cosmos in the past century than in all prior human history. Today's cosmologists can age-date the universe, trace how it evolved into its present form and accurately predict the outcome of fundamental events from here to the far reaches of space and time. Yet the game may just be getting under way. Contemporary cosmological research has become so thought-provoking - and just so flat-out weird - as to make the attainments of the last hundred years resemble the rattling, ratcheting start of a roller coaster ride. Sober scientists out to solve basic problems in microscopic and macroscopic physics alike are finding themselves obliged to consider, however reluctantly, the daunting prospect that ours is just one among many universes. These theoretical universes range from vast bubbles far, far away to hyperdimensional sheets hovering right in front of one's nose. They may sound fanciful, but they keep bubbling up out of the physics calculations, as insistently as a dinner partner trying to signal that you have spinach on your teeth. Multiverses, the physicist Brian Greene writes in his challenging and capable new book, "The Hidden Reality," are "harder to avoid than they are to find." Consider the relatively simple question of how fast our universe expands. Were it a bit faster, the universe would have expanded too rapidly for planets, stars and galaxies to have formed. Were it a bit slower, the universe would have faltered and collapsed before life appeared. In either case, we wouldn't be here to worry about it. One can always just shrug that off - quoting, perhaps, from the old drinking song: "We're here because we're here because we're here" - but it is also possible that there are lots of universes, with many different randomly generated expansion rates, few of which ever play host to life. That prospect gains support from the model that Greene calls "the inflationary multiverse." Inflation theory, inherently elegant and supported by observations of early cosmic structure, suggests that our universe began as a rapidly expanding bubble of empty space. Quantum fluctuations in the field driving the expansion caused it to brake suddenly, transforming expansion energy into the fiery broth of the Big Bang. But the inflationary mechanism envisioned by this theory also makes many other universes, and never stops making them. Inflating space, it seems, can no more produce just one universe than a thunderstorm can produce just one raindrop. What might an array of universes look like? One account Greene describes, known as the "landscape multiverse" model, combines inflation with string theory - in which tiny, vibrating "strings" replace subatomic particles as the building blocks of matter and energy - to yield an evocative array of universes, each with its own set of physical laws. The "mountaintops" in this landscape are high-energy regions, collections of dark, starless universes expanding indefinitely at velocities greater than the speed of light. The "valleys" are low-energy regions, where universes expand at more modest rates. We live in a valley. Greene notes that string theory posits two kinds of strings: loops and snippets. The loops convey gravity. The snippets account for everything else, their vibration rates determining which subatomic particles they impersonate. Strings that get entangled in space early on can be stretched out by cosmic expansion to become hyperdimensional "branes." A brane may, in Greene's words, resemble "a gargantuan flag whose surface extends indefinitely." The snippets, which comprise everything other than gravity, are anchored to the brane - so if we're made of strings the brane is right here, less than a centimeter from every part of you and me and everything else in our universe. Loop strings, however, can fall off the brane, leaking to another dimension. That could explain why gravity seems weak compared with the other fundamental forces of nature. Brane theory predicts that gravity will turn out to be unexpectedly strong if probed on a scale small enough to catch it leaking off the brane. If the effect is sufficiently large, it might even be detected in experiments currently being run at the Large Hadron Collider near Geneva. So this very odd theory is, strangely enough, also one of the most accessible to experimental testing. My personal favorite among Greene's menagerie of exotic models is the strange and beautiful "holographic multiverse." Imagine a sphere surrounding any given physical system. (This can be the actual horizon of the observable universe, or the horizon of a black hole, or just a laboratory sphere lined with detectors.) Everything transpiring within the sphere is recorded on its inside surface. Now start calculating, and - lo and behold - clarity dawns as vividly as the rising sun illuminating an unfamiliar landscape. Newton's and Einstein's laws are derived from first principles, quantum theory generates string theory almost automatically and information emerges as the key to understanding nature. "I suspect that the holographic principle will be a beacon for physicists well into the 21st century," Greene declares, and he's probably right. If information is indeed the key to understanding nature, the question arises of whether the universe "is" a computer, as some advocates of the so-called computational universe have claimed. Most physicists would regard this as at best a useful metaphor. After all, scientists of the past compared nature to a musical instrument, a clockwork or a steam engine (from which came, respectively, Pythagorean mathematics, Newtonian dynamics and thermodynamics), but they didn't think the universe really was any of those things. The Oxford philosopher Nick Bostrom takes the metaphor literally. He makes the clever if disturbing argument that computers will eventually become powerful enough to run simulations involving intelligent entities like human beings so realistically that the beings inside the sims think they're living real lives. (The science fiction writer Stanislaw Lem, in the 1971 short story "Non Serviam," called such sims "the cruelest science," in that everything the simulated beings work and care and fight for is ultimately artificial.) INDEED, in Bostrom's opinion, we may already be living inside such a simulation. He notes that simulations would be highly popular among the inhabitants of any civilization capable of running them. Terrestrial historians might, for instance, run thousands of sims to determine the results of altering Napoleon's tactics at Waterloo, or social scientists run sims to predict how various pieces of social legislation will pan out. The implication of running sims in minutes that replicate events taking years is that the number of sims greatly exceeds the number of real people running them - in which case, the odds are that we're living in a sim, "perhaps one created by future historians with a fascination for what life was like back on 21st-century earth," as Greene puts it. Nauseatingly claustrophobic and difficult to disprove, the simulated multiverse may be more a philosophical curiosity than a scientific hypothesis, but it's hard to get out of your head. Greene's own taste in multiverse theories, he writes, is "for the expansive," though he draws the line at ideas that have no hope of being meaningfully tested by experiment or observation. His ultimate goal is to help us think big in more ways than one. "I find it parochial," he writes, "to bound our thinking by the arbitrary limits imposed by where we are, when we are and who we are. Reality transcends these limits, so it's to be expected that sooner or later the search for deep truths will too." If extraterrestrials landed tomorrow and demanded to know what the human mind is capable of accomplishing, we could do worse than to hand them a copy of this book. We may be living inside a simulated universe, created by future historians obsessed with the 21st century. Timothy Ferris's books include "The Whole Shebang," "Coming of Age in the Milky Way" and, most recently, "The Science of Liberty: Democracy, Reason, and the Laws of Nature."

Copyright (c) The New York Times Company [February 6, 2011]

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Review by Booklist Review

That our cosmos is but one of many has inspired a recent spate of theoretical physicist-authors Lisa Randall, Michio Kaku, Leonard Susskind to advance their particular idea of the multiverse in general-interest works. Here their peer, Greene, comprehensively covers major variations of the multiverse concept. Numbering nine, they emerge from mathematical substrates that have yet to connect multiverse speculation with physical reality. Theory as arbiter of experimental and observational proof looms over each multiverse Greene discusses, some of which might become detectable with contemporary or some fantastic future technology, and some of which in principle could never be perceived. Greene explains that more accessible versions of the multiverse arise from investigations into general relativity and quantum mechanics. Puzzling over gravity, the wave function of electrons, and values of physical constants, physicists have devised daughter universes budding off our own or hovering nearby in higher dimensions postulated by string theory. Greene's exceptional clarity shows what evidence would hint at such parallel universes emerging from well-established theory and presents mind-benders suggesting that all universes are holograms projected from the surfaces of black holes. As bizarre as multiverses appear, the credence that scientists accord them is wonderfully transmitted to a lay readership by Greene. HIGH-DEMAND BACKSTORY: Greene's as big a name as science produces: he hosted a PBS Nova television series based on his The Elegant Universe (1999); his encore, The Fabric of Reality (2004), loitered for 10 weeks on the New York Times best-seller list. All-out marketing from book tour to tweets portend demand equal to the publisher's celebrity-scale first printing of 300,000 copies.--Taylor, Gilbert Copyright 2010 Booklist

From Booklist, Copyright (c) American Library Association. Used with permission.

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Review by Publisher's Weekly Review

"There was a time when 'universe' meant 'all there is,' " writes Greene, but soon we may have to redefine that word, along with our own meager understanding of the cosmos. A theoretical physicist and celebrated author, Greene offers intrepid readers another in-depth yet marvelously accessible look inside the perplexing world of modern theoretical physics and cosmology. Greene's book The Elegant Universe explained late 20th-century efforts to find a unified theory of everything, culminating with string theory. But string theory opened up a new can of worms, hinting at the possible existence of multiple universes and other strange entities. The possibility of other universes existing alongside our own like holes in "a gigantic block of Swiss cheese" seems more likely every day. Beginning with relativity theory, the Big Bang, and our expanding universe, Greene introduces first the mind-blowing multiplicity of forms those parallel universes might take, from patchwork quilts or stretchy "branes" to landscapes and holograms riddled with black holes. With his inspired analogies starring everyone from South Park's Eric Cartman to Ms. Pac-Man and a can of Pringles, Greene presents a lucid, intriguing, and triumphantly understandable state-of-the-art look at the universe. Illus. (Feb.) (c) Copyright PWxyz, LLC. All rights reserved.

(c) Copyright PWxyz, LLC. All rights reserved

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Review by Kirkus Book Review

An exploration of cutting-edge physics written for intelligent readers willing to pay close attention.Greene (Physics and Mathematics/Columbia Univ.; The Fabric of the Cosmos: Space, Time, and the Texture of Reality, 2004, etc.) points out that some astronomers believe that our universe is infinite. If so, the focus of his book, parallel universes, follows naturally. Mathematic calculations prove that an infinite universe contains innumerable regions with identical Milky Ways, solar systems and sentient life, plus many more regions differing in minor details. At this level, the existence of parallel universes is fairly simple. Thereafter, it becomes extremely complex. Essential to the current state of our cosmos is a momentary, massive expansion of the universe occurring an instant after the big bang: inflation. Some theorists maintain that this burst of expansion was not a one-time event but continues to occur, producing innumerable, parallel "bubble universes." Near the beginning of the book, Greene pauses to recap string theory, the subject of his previous books. An unproven, complex but widely held system for explaining all forces and matter, it allows for half-a-dozen additional parallel universes such as the Cyclic, Brane and Landscape multiverses. The author makes imaginative use of charts, diagrams, photographs, analogies and anecdotes to describe difficult scientific ideas. His accounts of confirmed phenomena such as relativity, quantum theory and recent revelations in astronomy provide lucid explanations that will satisfy a lay audience. Where he delves into string theory, many readers will struggle, not always successfully.The latest cosmological discoveries and speculations, directed at a popular audience but definitely not oversimplified.]] Copyright Kirkus Reviews, used with permission.

Copyright (c) Kirkus Reviews, used with permission.

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Chapter 1 The Bounds of Reality On Parallel Worlds If, when I was growing up, my room had been adorned with only a single mirror, my childhood daydreams might have been very different. But it had two. And each morning when I opened the closet to get my clothes, the one built into its door aligned with the one on the wall, creating a seemingly endless series of reflections of anything situated between them. It was mesmerizing. I delighted in seeing image after image populating the parallel glass planes, extending back as far as the eye could discern. All the reflections seemed to move in unison--but that, I knew, was a mere limitation of human perception; at a young age I had learned of light's finite speed. So in my mind's eye, I would watch the light's round-trip journeys. The bob of my head, the sweep of my arm silently echoed between the mirrors, each reflected image nudging the next. Sometimes I would imagine an irreverent me way down the line who refused to fall into place, disrupting the steady progression and creating a new reality that informed the ones that followed. During lulls at school, I would sometimes think about the light I had shed that morning, still endlessly bouncing between the mirrors, and I'd join one of my reflected selves, entering an imaginary parallel world constructed of light and driven by fantasy. It was a safe way to break the rules. To be sure, reflected images don't have minds of their own. But these youthful flights of fancy, with their imagined parallel realities, resonate with an increasingly prominent theme in modern science--the possibility of worlds lying beyond the one we know. This book is an exploration of such possibilities, a considered journey through the science of parallel universes. Universe and Universes There was a time when "universe" meant "all there is." Everything. The whole shebang. The notion of more than one universe, more than one everything, would seemingly be a contradiction in terms. Yet a range of theoretical developments has gradually qualified the interpretation of "universe." To a physicist, the word's meaning now largely depends on context. Sometimes "universe" still connotes absolutely everything. Sometimes it refers only to those parts of everything that someone such as you or I could, in principle, have access to. Sometimes it's applied to separate realms, ones that are partly or fully, temporarily or permanently, inaccessible to us; in this sense, the word relegates ours to membership in a large, perhaps infinitely large, collection. With its hegemony diminished, "universe" has given way to other terms introduced to capture the wider canvas on which the totality of reality may be painted. Parallel worlds or parallel universes or multiple universes or alternate universes or the metaverse, megaverse, or multiverse --they're all synonymous and they're all among the words used to embrace not just our universe but a spectrum of others that may be out there. You'll notice that the terms are somewhat vague. What exactly constitutes a world or a universe? What criteria distinguish realms that are distinct parts of a single universe from those classified as universes of their own? Perhaps someday our understanding of multiple universes will mature sufficiently for us to have precise answers to these questions. For now, we'll use the approach famously applied by Justice Potter Stewart in attempting to define pornography. While the U.S. Supreme Court wrestled mightily to delineate a standard, Stewart declared simply and forthrightly, "I know it when I see it." In the end, labeling one realm or another a parallel universe is merely a question of language. What matters, what's at the heart of the subject, is whether there exist realms that challenge convention by suggesting that what we've long thought to be the universe is only one component of a far grander, perhaps far stranger, and mostly hidden reality. During the last half century, science has provided ample ways in which this possibility might be realized. Varieties of Parallel Universes A striking fact (it's in part what propelled me to write this book) is that many of the major developments in fundamental theoretical physics-- relativistic physics, quantum physics, cosmological physics, unified physics, computational physics--have led us to consider one or another variety of parallel universe. Indeed, the chapters that follow trace a narrative arc through nine variations on the multiverse theme. Each envisions our universe as part of an unexpectedly larger whole, but the complexion of that whole and the nature of the member universes differ sharply among them. In some, the parallel universes are separated from us by enormous stretches of space or time; in others, they're hovering millimeters away; in others still, the very notion of their location proves parochial, devoid of meaning. A similar range of possibility is manifest in the laws governing the parallel universes. In some, the laws are the same as in ours; in others, they appear different but have shared a heritage; in others still, the laws are of a form and structure unlike anything we've ever encountered. It's at once humbling and stirring to imagine just how expansive reality may be. Some of the earliest scientific forays into parallel worlds were initiated in the 1950s by researchers puzzling over aspects of quantum mechanics, a theory developed to explain phenomena taking place in the microscopic realm of atoms and subatomic particles. Quantum mechanics broke the mold of the previous framework, classical mechanics, by establishing that the predictions of science are necessarily probabilistic. We can predict the odds of attaining one outcome, we can predict the odds of another, but we generally can't predict which will actually happen. This well-known departure from hundreds of years of scientific thought is surprising enough. But there's a more confounding aspect of quantum theory that receives less attention. After decades of closely studying quantum mechanics, and after having accumulated a wealth of data confirming its probabilistic predictions, no one has been able to explain why only one of the many possible outcomes in any given situation actually happens. When we do experiments, when we examine the world, we all agree that we encounter a single definite reality. Yet, more than a century after the quantum revolution began, there is no consensus among the world's physicists as to how this basic fact is compatible with the theory's mathematical expression. Over the years, this substantial gap in understanding has inspired many creative proposals, but the most startling was among the first. Maybe, that early suggestion went, the familiar notion that any given experiment has one and only one outcome is flawed. The mathematics underlying quantum mechanics--or at least, one perspective on the math-- suggests that all possible outcomes happen, each inhabiting its own separate universe. If a quantum calculation predicts that a particle might be here, or it might be there, then in one universe it is here, and in another it is there. And in each such universe, there's a copy of you witnessing one or the other outcome, thinking--incorrectly--that your reality is the only reality. When you realize that quantum mechanics underlies all physical processes, from the fusing of atoms in the sun to the neural firing that constitutes the stuff of thought, the far-reaching implications of the proposal become apparent. It says that there's no such thing as a road untraveled. Yet each such road-- each reality--is hidden from all others. This tantalizing Many Worlds approach to quantum mechanics has attracted much interest in recent decades. But investigations have shown that it's a subtle and thorny framework (as we will discuss in Chapter 8); so, even today, after more than half a century of vetting, the proposal remains controversial. Some quantum practitioners argue that it has already been proven correct, while others claim just as assuredly that the mathematical underpinnings don't hold together. What is beyond doubt is that this early version of parallel universes resonated with themes of separate lands or alternative histories that were being explored in literature, television, and film, creative forays that continue today. (My favorites since childhood include The Wizard of Oz, It's a Wonderful Life, the Star Trek episode "The City on the Edge of Forever," and, more recently, Sliding Doors and Run Lola Run ). Collectively, these and many other works of popular culture have helped integrate the concept of parallel realities into the zeitgeist and are responsible for fueling much public fascination with the topic. But the mathematics of quantum mechanics is only one of numerous ways that a conception of parallel universes emerges from modern physics. In fact, it won't be the first I'll discuss. Instead, in Chapter 2, I'll begin with a different route to parallel universes, perhaps the simplest route of all. We'll see that if space extends infinitely far--a proposition that is consistent with all observations and that is part of the cosmological model favored by many physicists and astronomers--then there must be realms out there (likely way out there) where copies of you and me and everything else are enjoying alternate versions of the reality we experience here. Chapter 3 will journey deeper into cosmology: the inflationary theory, an approach that posits an enormous burst of superfast spatial expansion during the universe's earliest moments, generates its own version of parallel worlds. If inflation is correct, as the most refined astronomical observations suggest, the burst that created our region of space may not have been unique. Instead, right now, inflationary expansion in distant realms may be spawning universe upon universe and may continue to do so for all eternity. What's more, each of these ballooning universes has its own infinite spatial expanse, and hence contains infinitely many of the parallel worlds explored in Chapter 2. In Chapter 4, our trek turns to string theory. After a brief review of the basics, I'll provide a status report on this approach to unifying all of nature's laws. With that overview, in Chapters 5 and 6 we'll explore recent developments in string theory that suggest three new kinds of parallel universes. One is string theory's braneworld scenario, which posits that our universe is one of potentially numerous "slabs" floating in a higher-dimensional space, much like a slice of bread within a grander cosmic loaf. If we're lucky, it's an approach that may provide an observable signature at the Large Hadron Collider in Geneva, Switzerland, in the not too distant future. A second variety involves braneworlds that slam into one another, wiping away all they contain and initiating a new, fiery big-bang-like beginning in each. As if two giant hands were clapping, this could happen over and over--branes might collide, bounce apart, attract each other gravitationally, and then collide again, a cyclic process generating universes that are parallel not in space but in time. The third scenario is the string theory "landscape," founded on the enormous number of possible shapes and sizes for the theory's required extra spatial dimensions. We'll see that, when joined with the Inflationary Multiverse, the string landscape suggests a vast collection of universes in which every possible form for the extra dimensions is realized. In Chapter 6, we'll focus on how these considerations illuminate one of the most surprising observational results of the last century: space appears to be filled with a uniform diffuse energy, which may well be a version of Einstein's infamous cosmological constant. Indeed, this observation has inspired much of the recent research on parallel universes, and it's responsible for one of the most heated debates in decades on the nature of acceptable scientific explanations. Chapter 7 extends this theme by asking, more generally, whether consideration of hidden universes beyond our own can be rightly understood as a branch of science. Can we test these ideas? If we invoke them to solve outstanding problems, have we made progress, or have we merely swept the problems under a conveniently inaccessible cosmic rug? I've sought to lay bare the essentials of the clashing perspectives, while ultimately emphasizing my own view that, under certain specific conditions, parallel universes fall unequivocally within the purview of science. Quantum mechanics, with its Many Worlds version of parallel universes, is the subject of Chapter 8. I'll briefly remind you of the essential features of quantum mechanics, then focus on the formidable problem just referred to: how to extract definite outcomes from a theory whose basic paradigm allows for mutually contradictory realities to coexist in an amorphous, but mathematically precise, probabilistic haze. I'll carefully lead you through the reasoning that, in seeking an answer, proposes anchoring quantum reality in its own profusion of parallel worlds. Chapter 9 takes us yet further into quantum reality, leading to what I consider the strangest version of all parallel universes proposals. It's a proposal that emerged gradually over thirty years of theoretical studies spearheaded by luminaries including Stephen Hawking, Jacob Bekenstein, Gerardt Hooft, and Leonard Susskind on the quantum properties of black holes. The work culminated in the last decade, with a stunning result from string theory, and it suggests, remarkably, that all we experience is nothing but a holographic projection of processes taking place on some distant surface that surrounds us. You can pinch yourself, and what you feel will be real, but it mirrors a parallel process taking place in a different, distant reality. Finally, in Chapter 10 the yet more fanciful possibility of artificial universes takes center stage. The question of whether the laws of physics give us the capacity to create new universes will be our first order of business. We'll then turn to universes created not with hardware but with software--universes that might be simulated on a superadvanced computer--and investigate whether we can be confident that we're not now living in someone or something else's simulation. This will lead to the most unrestrained parallel universe proposal, originating in the philosophical community: that every possible reality is realized somewhere in what's surely the grandest of all multiverses. The discussion naturally unfolds into an inquiry about the role mathematics has in unraveling the mysteries of science and, ultimately, our ability, or lack thereof, to gain an ever-deeper understanding of the expanse of reality. The Cosmic Order The subject of parallel universes is highly speculative. No experiment or observation has established that any version of the idea is realized in nature. So my point in writing this book is not to convince you that we're part of a multiverse. I'm not convinced--and, speaking generally, no one should be convinced--of anything not supported by hard data. That said, I find it both curious and compelling that numerous developments in physics, if followed sufficiently far, bump into some variation on the parallel universe theme. Of particular note, it's not that physicists are standing ready, multiverse nets in their hands, seeking to snare any passing theory that might be slotted, however awkwardly, into a parallel- universe paradigm. Rather, all of the parallel-universe proposals that we will take seriously emerge unbidden from the mathematics of theories developed to explain conventional data and observations. My intention, then, is to lay out clearly and concisely the intellectual steps and the chain of theoretical insights that have led physicists, from a range of perspectives, to consider the possibility that ours is one of many universes. I want you to get a sense of how modern scientific investigations-- not untethered fantasies like the catoptric musings of my boyhood-- naturally suggest this astounding possibility. I want to show you how certain otherwise confounding observations can become eminently understandable within one or another parallel-universe framework; at the same time, I'll describe the critical unresolved questions that have, as yet, kept this explanatory approach from being fully realized. My aim is that when you leave this book, your sense of what might be-- your perspective on how the boundaries of reality may one day be redrawn by scientific developments now under way-- will be far more rich and vivid. Some people recoil at the notion of parallel worlds; as they see it, if we are part of a multiverse, our place and importance in the cosmos are marginalized. My take is different. I don't find merit in measuring significance by our relative abundance. Rather, what's gratifying about being human, what's exciting about being part of the scientific enterprise, is our ability to use analytical thought to bridge vast distances, journeying to outer and inner space and, if some of the ideas we'll encounter in this book prove correct, perhaps even beyond our universe. For me, it is the depth of our understanding, acquired from our lonely vantage point in the inky black stillness of a cold and forbidding cosmos, that reverberates across the expanse of reality and marks our arrival. Excerpted from The Hidden Reality: Parallel Universes and the Deep Laws of the Cosmos by Brian Greene All rights reserved by the original copyright owners. Excerpts are provided for display purposes only and may not be reproduced, reprinted or distributed without the written permission of the publisher.

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