Time reborn From the crisis in physics to the future of the universe

Lee Smolin, 1955-

Book - 2013

"From one of our foremost thinkers and public intellectuals, a radical new view of the nature of time and the cosmos What is time? This deceptively simple question is the single most important problem facing science as we probe more deeply into the fundamentals of the universe. All of the mysteries physicists and cosmologists face--from the Big Bang to the future of the universe, from the puzzles of quantum physics to the unification of forces and particles--come down to the nature of time. The fact that time is real may seem obvious. You experience it passing every day when you watch clocks tick, bread toast, and children grow. But most physicists, from Newton to Einstein to today's quantum theorists, have seen things differently.... The scientific case for time being an illusion is formidable. That is why the consequences of adopting the view that time is real are revolutionary. Lee Smolin, author of the controversial bestseller The Trouble with Physics, argues that a limited notion of time is holding physics back. It's time for a major revolution in scientific thought. The reality of time could be the key to the next big breakthrough in theoretical physics. What if the laws of physics themselves were not timeless? What if they could evolve? Time Reborn offers a radical new approach to cosmology that embraces the reality of time and opens up a whole new universe of possibilities. There are few ideas that, like our notion of time, shape our thinking about literally everything, with huge implications for physics and beyond--from climate change to the economic crisis. Smolin explains in lively and lucid prose how the true nature of time impacts our world"--

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Subjects
Published
Boston : Houghton Mifflin Harcourt 2013.
Language
English
Main Author
Lee Smolin, 1955- (-)
Physical Description
xxxi, 319 p. : ill. ; 24 cm
Bibliography
Includes bibliographical references (p. 295-297) and index.
ISBN
9780547511726
  • Preface
  • Introduction
  • Part I. Weight: The Expulsion of Time
  • 1. Falling
  • 2. The Disappearance of Time
  • 3. A Game of Catch
  • 4. Doing Physics in a Box
  • 5. The Expulsion of Novelty and Surprise
  • 6. Relativity and Timelessness
  • 7. Quantum Cosmology and the End of Time
  • Part II. Light: Time Reborn
  • Interlude: Einstein's Discontent
  • 8. The Cosmological Fallacy
  • 9. The Cosmological Challenge
  • 10. Principles for a New Cosmology
  • 11. The Evolution of Laws
  • 12. Quantum Mechanics and the Liberation of the Atom
  • 13. The Battle Between Relativity and the Quantum
Review by Choice Review

The author's goal with this book is to present the start of an argument, based in physics, that time is real. As Smolin (Perimeter Institute for Theoretical Physics; The Trouble with Physics, CH, May'07, 44-5107) notes, most philosophies of time that use physics lead to eternalism and the "unreality of time." Smolin's approach is interesting because he only relies on physics and does not resort to free will. He openly admits that much of what he presents is speculative, and he does not address many of the other approaches to time being real. The book is in two main parts. Part 1, "Weight," provides a good presentation of the history and development of the eternalist's position. Part 2, "Light," examines how modern cosmology may lead to problems for this position. Fundamentally, Smolin is challenging the reductionist approach of eternalism by questioning if the physics developed to explain parts of the universe can be applied to the universe as a whole. This is different than most challenges to reductionism because he relies on his belief that the real cosmological laws must have certain characteristics. Though the presentation is far from complete, due to unsolved problems in cosmology, Smolin presents intriguing ideas. Summing Up: Recommended. All academic and general audiences. E. Kincanon Gonzaga University

Copyright American Library Association, used with permission.
Review by New York Times Review

IN one of the more fanciful conceptions of nature, the British physicist and philosopher Julian Barbour proposed that the world is just a "heap of moments," each an instant of frozen time. There is no order to the moments, no sequence, no cause-and-effect relationship. We exist only from moment to moment. If we experience time passing, it's because this particular moment has memories of another moment woven into it. Some moments are interesting: they contain complexity, stars and planets, life. Others are boring: they contain only energy, or perhaps nothing at all. In his new book, "Time Reborn," Lee Smolin, a physicist and author of "The Life of the Cosmos" (1997) and "The Trouble With Physics" (2006), recounts Barbour's cosmology with some admiration and then goes on to offer even more radical ideas of his own. Smolin argues that the Now has been taken out of physics, and it is time to put it back in. For example, Smolin says that Newtonian physics expresses the notion that the future is determined by the past and so, in a sense, the future already exists. He rightly remarks that Einsteinian physics frames time as a relative concept in which the line between past and future varies with the observer. To remedy these perceived problems, he suggests major structural revisions to the two fundamental pillars of modern physics, relativity and quantum mechanics. His book, a mix of science, philosophy and science fiction, is at once entertaining, thought-provoking, fabulously ambitious and fabulously speculative. Although full of wonderful metaphors and analogies, it may prove heavy sledding for many readers. Twentieth-century physics has brought us two kinds of strangeness: strange things we more or less understand, and strange things we do not understand. The first category includes relativity and quantum mechanics. Relativity reveals that time is not absolute. Clocks in relative motion to each other tick at different rates. We don't notice relativity in daily life because the relative speed must be close to the speed of light before the effects are significant. Quantum mechanics presents a probabilistic picture of reality; subatomic particles act as if they occupy many places at once, and their locations can be described only in terms of probabilities. Although we can make accurate predictions about the average behavior of a large number of subatomic particles, we cannot predict the behavior of a single subatomic particle, or even a single atom. We don't feel quantum mechanics because its effects are significant only in the tiny realm of the atom. The category of strange things we do not understand includes the origin of the universe and the nature of the "dark energy" that pervades the cosmos. Over the last 40 years, physicists have realized that various universal parameters, like the mass of the electron (a type of subatomic particle) and the strength of the nuclear force (the force that holds the subatomic particles together within the centers of atoms), appear to be precisely calibrated. That is, if these parameters were a little larger or a little smaller than they actually are, the complex molecules needed for life could never have formed. Presumably, the values of these parameters were set at the origin of the universe. Fifteen years ago, astronomers discovered a previously unknown and still unexplained cosmic energy that fills the universe and acts as an antigravity-like force, pushing the galaxies apart. The density of this dark energy also appears to be extraordinarily fine-tuned. A little smaller or a little larger, and the life-giving stars would never have formed. THE haunting question is why these fundamental parameters lie in the narrow range required by life. What determined their values? One explanation offered by physicists, called the "anthropic principle," is that there are, in fact, a great many universes, with widely varying properties and parameters. In most other universes, the strength of the nuclear force, the density of the dark energy and so on are much different than in ours. Those universes would be lifeless and barren. By definition, we live in one of the universes with parameters that allow life, because otherwise we would not be here to ask the question. Smolin has his own theory to explain why we live in a life-supporting universe, which he calls "cosmological natural selection." He proposes that new universes are spawned at the centers of black holes. As in biological natural selection, those universes with the right parameters for producing new black holes have descendants; those that do not disappear. What's more, it turns out that some of the conditions needed to form black holes, such as the right parameters to form stars, are the same as those needed for life. Despite its appeal, there are several problems with Smolin's theory. First, there is no evidence that new universes are created at the centers of black holes. Second, even if such evidence existed, why would the parameters of a universe so created bear any resemblance to the parameters of its parent universe, as required by the theory? If the parameters differ by more than a little, the new universe would not have "survivable" characteristics. Cosmological natural selection does have one feature that relates to Smolin's dissatisfaction with the relativity of time. The succession of parent and descendant universes necessarily unfolds in time, and Smolin believes that this is "real" time (as opposed to what he calls the "unreal" and "inessential" conceptions of time in traditional physics). He goes on to propose a variety of revolutionary ideas to codify further his notion of "real time." In one, he suggests that every atom in the universe is causally connected to every other atom in the universe, no matter how many lightyears away. According to his notion, the failure of standard quantum mechanics to predict the behavior of individual atoms arises from the fact that it does not take into account the vast numbers of interconnections extending across the universe. Furthermore, this picture of the cosmos requires an absolute time (in violation of relativity), which he calls "preferred global time." One of Smolin's most astonishing ideas is something he calls the "principle of precedence," that repeated measurements of a particular phenomenon yield the same outcomes not because the phenomenon is subject to a law of nature but simply because the phenomenon has occurred in the past. "Such a principle," Smolin writes, "would explain all the instances in which determinism by laws work but without forbidding new measurements to yield new outcomes, not predictable from knowledge of the past." In Smolin's view such unconstrained outcomes are necessary for "real" time. Putting aside the sensational ideas proposed in "Time Reborn," it is a triumph of modern physics that we are even asking such questions as what determined the initial conditions of the universe. In previous centuries, these conditions were either accepted as given or attributed to the handiwork of the gods. A triumph, and also possibly a defeat. For if we must appeal to the existence of other universes - unknown and unknowable - to explain our universe, then science has progressed into a cul-de-sac with no scientific escape. Alan Lightman, a novelist and physicist, teaches at M.I.T. His next book, "The Accidental Universe," will be published in January.

Copyright (c) The New York Times Company [May 5, 2013]
Review by Booklist Review

*Starred Review* Was Einstein wrong? At least in his understanding of time, Smolin argues, the great theorist of relativity was dead wrong. What is worse, by firmly enshrining his error in scientific orthodoxy, Einstein trapped his successors in insoluble dilemmas as they try to devise timeless laws explaining the origins and structure of the cosmos. How, Smolin asks, can such laws account for the highly improbable set of conditions that triggered the big bang jump-starting the universe? How, Smolin further wants to know, can scientists ever empirically test their timeless cosmic hypotheses? With rare conceptual daring, Smolin beckons toward a new perspective for doing cosmological theory, a perspective allowing Leibniz's principle of sufficient reason to open surprising possibilities. This horizon not only readmits time as a reality; it enshrines time as the reality, the indispensable point of flux allowing everything else, including the laws of matter and energy, to evolve and change. Embracing time as real, Smolin asserts, will allow cosmologists to convert laws once regarded as timeless into the contingent data they need to develop testable new theories of galactic evolution. More immediately, Smolin anticipates that this paradigm shift will help climatologists understand global warming and economists to ameliorate financial turbulence. A thrilling intellectual ride!--Christensen, Bryce Copyright 2010 Booklist

From Booklist, Copyright (c) American Library Association. Used with permission.
Review by Publisher's Weekly Review

Contrary to Plato and Einstein, theoretical physicist Smolin (The Trouble with Physics) asserts that "not only is time real, but nothing we know or experience gets closer to the heart of nature than the reality of time." Though time has always been a quantity to measure, the author explains that in the 17th century, scientists began wondering whether "the world is in essence mathematical or it lives in time." Newton's laws of motion made time irrelevant, and "Einstein's two theories of relativity are, at their most basic, theories of time-or, better, timelessness." Galileo and Descartes, on the other hand, insisted that time should be regarded as another dimension, and in 1909, mathematician Hermann Minkowski developed the theory of "spacetime," a feature of the universe shaped by gravity. Smolin asserts that current-day cosmology has hit a wall because physicists refuse to understand that physical laws must "evolve in a real time." Changing that perspective, he says, will revolutionize everything from string theory to the stock market. Although the distinctions in point of view aren't always clear, Smolin makes an energetic case for a paradigm shift that could produce mind-boggling changes in the way we experience our world. Agent: John Brockman, Brockman Inc. (Apr. 23) (c) Copyright PWxyz, LLC. All rights reserved.

(c) Copyright PWxyz, LLC. All rights reserved
Review by Kirkus Book Review

A distinguished physicist delivers a thoughtful, complex re-evaluation of the role of time in the universe. Smolin (The Trouble with Physics: The Rise of String Theory, the Fall of a Science, and What Comes Next, 2006) points out that no one doubts that space is real. If the cosmos were empty, space would exist, but there would be no time. So time is inextricably bound up with the material universe, a real phenomenon at the heart of nature. This turns out to be controversial since the great thinkers from Plato to Newton to Einstein taught that time is an illusion that humans must transcend to achieve true understanding. Smolin disagrees, maintaining that embracing its reality is the key to solving the great problems in physics. He makes a case that Newton's paradigm--knowing the forces acting on any system allows us, following natural laws, to predict its future state--is a fallacy. It works for limited areas and short periods but fails on universal scales. In fact, natural laws themselves are less immutable than time. For a straightforward popular introduction to time, read Sean Carroll's From Eternity to Here (2010). Smolin has bigger fish to fry as he muses over great issues in his field as they relate to time, such as the stubborn refusal of relativity to mesh with quantum theory, pausing regularly for detours into cosmology, economics and climate change. This is a work as much of philosophy as science. Despite the absence of mathematics, it requires close attention, but readers who make the effort will absorb a flood of ideas from an imaginative thinker.]] Copyright Kirkus Reviews, used with permission.

Copyright (c) Kirkus Reviews, used with permission.

INTRODUCTION The scientific case for time being an illusion is formidable. That is why the consequences of adopting the view that time is real are revolutionary. The core of the physicists' case against time relies on the way we understand what a law of physics is. According to this dominant view, everything that happens in the universe is determined by a law, which dictates precisely how the future evolves out of the present. The law is absolute and, once present conditions are specified, there is no freedom or uncertainty in how the future will evolve. As Thomasina, the precocious heroine of Tom Stoppard's play Arcadia , explains to her tutor: "If you could stop every atom in its position and direction, and if your mind could comprehend all the actions thus suspended, then if you were really, really good at algebra you could write the formula for all the future; and although nobody can be so clever as to do it, the formula must exist just as if one could." I used to believe that my job as a theoretical physicist was to find that formula; I now see my faith in its existence as more mysticism than science. Were he writing lines for a modern character, Stoppard would have had Thomasina say that the universe is like a computer. The laws of physics are the program. When you give it an input -- the present positions of all the elementary particles in the universe -- the computer runs for an appropriate amount of time and gives you the output, which is all the positions of the elementary particles at some future time. Within this view of nature, nothing happens except the rearrangement of particles according to timeless laws, so according to these laws the future is already completely determined by the present, as the present was by the past. This view diminishes time in several ways.1 There can be no surprises, no truly novel phenomena, because all that happens is rearrangement of the atoms. The properties of the atoms themselves are timeless, as are the laws controlling them; neither ever changes. Any feature of the world at a future time can be computed from the configuration of the present. That is, the passage of time can be replaced by a computation, which means that the future is logically a consequence of the present. Einstein's theories of relativity make even stronger arguments that time is inessential to a fundamental description of the world, as I'll discuss in chapter 6. Relativity strongly suggests that the whole history of the world is a timeless unity; present, past, and future have no meaning apart from human subjectivity. Time is just another dimension of space, and the sense we have of experiencing moments passing is an illusion behind which is a timeless reality. These assertions may seem horrifying to anyone whose worldview includes a place for free will or human agency. This is not an argument I will engage in here; my case for the reality of time rests purely on science. My job will be to explain why the usual arguments for a predetermined future are wrong scientifically. In Part I, I will present the case from science for believing that time is an illusion. In Part II, I will demolish those arguments and show why time must be taken to be real if fundamental physics and cosmology are to overcome the crises they currently face. To frame the argument of Part I, I trace the development of the concepts of time used in physics, from Aristotle and Ptolemy through Galileo, Newton, Einstein, and on to our contemporary quantum cosmologists, and show how our concept of time was diminished, step by step, as physics progressed. Telling the story this way also allows me to gently introduce the material the lay reader needs for an understanding of the argument. Indeed, key points can be introduced by ordinary examples of balls falling and planets orbiting. Part II tells a more contemporary story, since the argument that time must be reinserted into the core of science arose as a result of recent developments. My argument starts with a simple observation: The success of scientific theories from Newton through the present day is based on their use of a particular framework of explanation invented by Newton. This framework views nature as consisting of nothing but particles with timeless properties, whose motions and interactions are determined by timeless laws. The properties of the particles, such as their masses and electric charges, never change, and neither do the laws that act on them. This framework is ideally suited to describe small parts of the universe, but it falls apart when we attempt to apply it to the universe as a whole. All the major theories of physics are about parts of the universe -- a radio, a ball in flight, a biological cell, the Earth, a galaxy. When we describe a part of the universe, we leave ourselves and our measuring tools outside the system. We leave out our role in selecting or preparing the system we study. We leave out the references that serve to establish where the system is. Most crucially for our concern with the nature of time, we leave out the clocks by which we measure change in the system. The attempt to extend physics to cosmology brings new challenges that require fresh thinking. A cosmological theory cannot leave anything out. To be complete, it must take into account everything in the universe, including ourselves as observers. It must account for our measuring instruments and clocks. When we do cosmology, we confront a novel circumstance: It is impossible to get outside the system we're studying when that system is the entire universe. Moreover, a cosmological theory must do without two important aspects of the methodology of science. A basic rule of science is that an experiment must be done many times to be sure of the result. But we cannot do this with the universe as a whole -- the universe only happens once. Nor can we prepare the system in different ways and study the consequences. These are very real handicaps, which make it much harder to do science at the level of the universe as a whole. Nonetheless, we want to extend physics to a science of cosmology. Our first instinct is to take the theories that worked so well when applied to small parts of the universe and scale them up describe the universe as a whole. As I'll show in chapters 8 and 9, this cannot work. The Newtonian framework of timeless laws acting on particles with timeless properties is unsuited to the task of describing the entire universe. Indeed, as I will show in detail, the very features that make these kinds of theories so successful when applied to small parts of the universe cause them to fail when we attempt to apply them to the universe as a whole. I realize that this assertion goes counter to the practice and hopes of many colleagues, but I ask only that the reader pay close attention to the case I make for it in Part II. There I will show in general, and illustrate by specific example, that when we attempt to scale up our standard theories to a cosmological theory, we are rewarded with dilemmas, paradoxes, and unanswerable questions. Among these are the failure of any standard theory to account for the choices made in the early universe -- choices of initial conditions and choices of the laws of nature themselves. Some of the literature of contemporary cosmology consists of the efforts of very smart people to wrestle with these dilemmas, paradoxes, and unanswerable questions. The notion that our universe is part of a vast or infinite multiverse is popular -- and understandably so, because it is based on a methodological error that is easy to fall into. Our current theories can work at the level of the universe only if our universe is a subsystem of a larger system. So we invent a fictional environment and fill it with other universes. This cannot lead to any real scientific progress, because we cannot confirm or falsify any hypothesis about universes causally disconnected from our own. The purpose of this book is to suggest that there is another way. We need to make a clean break and embark on a search for a new kind of theory that can be applied to the whole universe -- a theory that avoids the confusions and paradoxes, answers the unanswerable questions, and generates genuine physical predictions for cosmological observations. I do not have such a theory, but what I can offer is a set of principles to guide the search for it. These are presented in chapter 10. In the chapters that follow it, I will illustrate how the principles can inspire new hypotheses and models of the universe that point the way to a true cosmological theory. The central principle is that time must be real and physical laws must evolve in that real time. The idea of evolving laws is not new, nor is the idea that a cosmological science will require them.2 The American philosopher Charles Sanders Peirce wrote in 1891: To suppose universal laws of nature capable of being apprehended by the mind and yet having no reason for their special forms, but standing inexplicable and irrational, is hardly a justifiable position. Uniformities are precisely the sort of facts that need to be accounted for. . . . Law is par excellence the thing that wants a reason. Now the only possible way of accounting for the laws of nature and for uniformity in general is to suppose them results of evolution."3 The contemporary philosopher Roberto Mangabeira Unger has more recently proclaimed: You can trace the properties of the present universe back to properties it must have had at its beginning. But you cannot show that these are the only properties that any universe might have had. . . . Earlier or later universes might have had entirely different laws. . . . To state the laws of nature is not to describe or to explain all possible histories of all possible universes. Only a relative distinction exists between lawlike explanation and the narration of a one-time historical sequence."4 Paul Dirac, who ranks with Einstein and Niels Bohr as one of the most consequential physicists of the 20th century, speculated: "At the beginning of time the laws of Nature were probably very different from what they are now. Thus, we should consider the laws of Nature as continually changing with the epoch, instead of as holding uniformly throughout space-time."5 John Archibald Wheeler, one of the great American physicists, also imagined that laws evolved. He proposed that the Big Bang was one of a series of events within which the laws of physics were reprocessed. He also wrote, "There is no law except the law that there is no law."6 Even Richard Feynman, another of the great American physicists and Wheeler's student, once mused in an interview: "The only field which has not admitted any evolutionary question is physics. Here are the laws, we say, . . . but how did they get that way, in time? . . . So, it might turn out that they are not the same [laws] all the time and that there is a historical, evolutionary, question." In my 1997 book, The Life of the Cosmos , I proposed a mechanism for laws to evolve, which I modeled on biological evolution.8 I imagined that universes could reproduce by forming baby universes inside black holes, and I posited that whenever this happens, the laws of physics change slightly. In this theory, the laws played the role of genes in biology; a universe was seen as an expression of a choice of laws made at its formation, just as an organism is an expression of its genes. Like the genes, the laws could mutate randomly from generation to generation. Inspired by then-recent results of string theory, I imagined that the search for a fundamental unified theory would lead not to a single Theory of Everything but to a vast space of possible laws. I called this the landscape of theories, taking the language from population genetics, whose practitioners work with fitness landscapes. I will not say more about this here, as it is the subject of chapter 11, except to say that this theory, cosmological natural selection, makes several predictions that, remarkably, have held up despite several opportunities to falsify them in the years since. Over the last decade, many string theorists have embraced the concept of a landscape of theories. As a result, the question of how the universe chooses which laws to follow has become especially urgent. This, I will argue, is one of the questions that can be answered only within a new framework for cosmology in which time is real and laws evolve. Laws, then, are not imposed on the universe from outside it. No external entity, whether divine or mathematical, specifies in advance what the laws of nature are to be. Nor do the laws of nature wait, mute, outside of time for the universe to begin. Rather the laws of nature emerge from inside the universe and evolve in time with the universe they describe. It is even possible that, just as in biology, novel laws of physics may arise as regularities of new phenomena that emerge during the universe's history. Some might see the disavowal of eternal laws as a retreat from the goals of science. But I see it as the jettisoning of excess metaphysical baggage that weighs down our search for truth. In the coming chapters, I will provide examples illustrating how the idea of laws evolving in time leads to a more scientific cosmology -- by which I mean one more generative of predictions subject to experimental test. To my knowledge, the first scientist since the dawn of the Scientific Revolution to think really hard about how to make a theory of a whole universe was Gottfried Wilhelm Leibniz, who, among other things, was Newton's rival, famously in the matter of which of them was the first to invent the calculus. He also anticipated modern logic, developed a system of binary numbers, and much else. He has been called the smartest person who ever lived. Leibniz formulated a principle to frame cosmological theories called the principle of sufficient reason , which states that there must be a rational reason for every apparent choice made in the construction of the universe. Every query of the form, "Why is the universe like X rather than Y?" must have an answer. So if a God made the world, He could not have had any choice in the blueprint. Leibniz's principle has had a profound effect on the development of physics so far, and, as we will see, it continues to be reliable as a guide in our efforts to devise a cosmological theory. Leibniz had a vision of a world in which everything lives not in space but immersed in a network of relationships. These relationships define space, not the reverse. Today the idea of a universe of connected, networked entities pervades modern physics, as well as biology and computer science. In a relational world (which is what we call a world where relationships precede space), there are no spaces without things. Newton's concept of space was absolute: He saw atoms defined by where they are in space but space in no way affected by the motion of atoms. In a relational world, there are no such asymmetries. Things are defined by their relationships. Individuals exist, and they may be partly autonomous, but their possibilities are determined by the network of relationships. Individuals encounter and perceive one another through the links that connect them within the network, and the networks are dynamic and ever evolving. As I will explain in chapter 3, it follows from Leibniz's great principle that there can be no absolute time that ticks on blindly whatever happens in the world. Time must be a consequence of change; without alteration in the world, there can be no time. Philosophers say that time is relational -- it is an aspect of relations, such as causality, that govern change. Similarly, space must be relational; indeed, every property of an object in nature must be a reflection of dynamical relations between it and other things in the world. Leibniz's principles contradicted the basic ideas of Newtonian physics, so it took some time for them to be fully appreciated by working scientists. It was Einstein who embraced Leibniz's legacy and used his principles as major motivation for his overthrow of Newtonian physics and its replacement by general relativity, a theory of space, time, and gravity that goes far to instantiate Leibniz's relational view of space and time. Leibniz's principles are also realized in a different way in the parallel quantum revolution. I call the 20th-century revolution in physics the relational revolution. The problem of unifying physics and, in particular, bringing together quantum theory with general relativity into one framework is largely the task of completing the relational revolution in physics. The main message of this book is that this requires embracing the ideas that time is real and laws evolve. The relational revolution is already in full swing in the rest of science. Darwin's revolution in biology is one front, manifested both in the notion of a species being defined by its relation to all the other organisms in its environment and in the concept that a gene's action is defined only in the context of the network of genes regulating its action. As we are quickly coming to realize, biology is about information, and there is no more relational concept than information, relying as it does on a relationship between the sender and receiver at each end of a communications channel. In the social sphere, the liberal concept of a world of autonomous individuals (conceived by the philosopher John Locke as analogous to the physics of his friend Isaac Newton) is being challenged by a view of society as composed of interdependent individuals, only partly autonomous, whose lives are meaningful only within a skein of relationships. The new informational halo within which we are so recently enmeshed expresses the relational idea through the metaphor of the network. As social beings, we see ourselves as nodes in a network whose connections define us. Today the idea of a social system made up of connected, networked entities increasingly crops up in social theories formulated by everyone from feminist political philosophers to management gurus. How many users of Facebook are aware that their social lives are now organized by a potent scientific idea? The relational revolution is already far along. At the same time, it is clearly in crisis. On some fronts, it's stuck. Wherever it is in crisis, we find three kinds of questions under hot debate. What is an individual? How do novel kinds of systems and entities emerge? How are we to usefully understand the universe as a whole? The key to these puzzles is that neither individuals, systems, nor the universe as a whole can be thought of as things that simply are. They are all compounded by processes that take place in time. The missing element, without which we cannot answer these questions, is to see them as processes developing in time. I will argue that to succeed, the relational revolution must embrace the notion of time and the present moment as a fundamental aspect of reality. In the old way of thinking, individuals were just the smallest units in a system, and if you wanted to understand how a system worked you took it apart and studied how its parts behaved. But how are we to understand the properties of the most fundamental entities? They have no parts, so reductionism (as this method is called) gets us no further. The atomic viewpoint has no place to go here; it, too, is truly stuck. This is a great opportunity for the nascent relational program, for it can -- and indeed must -- seek the explanation for properties of elementary particles in the network of their relations. This is already happening in the unified theories we have so far. In the Standard Model of Particle Physics, which is the best theory we have so far of the elementary particles, the properties of an electron, such as its mass, are dynamically determined by the interactions in which it participates. The most basic property a particle can have is its mass, which determines how much force is needed to change its motion. In the Standard Model, all the particles' masses arise from their interactions with other particles and are determined primarily by one -- the Higgs particle. No longer are there absolutely "elementary" particles; everything that behaves like a particle is, to some extent, an emergent consequence of a network of interactions. Emergence is an important term in a relational world. A property of something made of parts is emergent if it would not make sense when attributed to any of the parts. Rocks are hard, and water flows, but the atoms they're made of are neither solid nor wet. An emergent property will often hold approximately, because it denotes an averaged or high-level description that leaves out much detail. As science progresses, aspects of nature once considered fundamental are revealed as emergent and approximate. We once thought that solids, liquids, and gases were fundamental states; now we know that these are emergent properties, which can be understood as different ways to arrange the atoms that make up everything. Most of the laws of nature once thought of as fundamental are now understood as emergent and approximate. Temperature is just the average energy of atoms in random motion, so the laws of thermodynamics that refer to temperature are emergent and approximate. I'm inclined to believe that just about everything we now think is fundamental will also eventually be understood as approximate and emergent: gravity and the laws of Newton and Einstein that govern it, the laws of quantum mechanics, even space itself. The fundamental physical theory we seek will not be about things moving in space. It will not have gravity or electricity or magnetism as fundamental forces. It will not be quantum mechanics. All these will emerge as approximate notions when our universe grows large enough. If space is emergent, does that mean that time is also emergent? If we go deep enough into the fundamentals of nature, does time disappear? In the last century, we have progressed to the point where many of my colleagues consider time to be emergent from a more fundamental description of nature in which time does not appear. I believe -- as strongly as one can believe anything in science -- that they're wrong. Time will turn out to be the only aspect of our everyday experience that is fundamental. The fact that it is always some moment in our perception, and that we experience that moment as one of a flow of moments, is not an illusion. It is the best clue we have to fundamental reality. Excerpted from Time Reborn: From the Crisis in Physics to the Future of the Universe by Lee Smolin 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.