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Three Roads To Quantum Gravity
It's difficult, writes Lee Smolin in this lucid overview of modern physics, to talk meaningfully about the big questions of space and time, given the limitations of our technology and perceptions. It's more difficult still given some of the contradictions and inconsistencies that obtain between quantum theory, which "was invented to explain why atoms are stable and do not instantly fall apart" but has little to say about space and time, and general relatively theory, which has everything to say about the big picture but tends to collapse when describing the behavior of atoms and their even smaller constituents. Whence the hero of Smolin's tale, the as-yet-incomplete quantum theory of gravity, which seeks to unify relativity and quantum theory--and, in the bargain, to move toward a "grand theory of everything." Smolin ably explains concepts that underlie quantum gravity, such as background independence, the superposition principle, and the notion of causal structure, and he traces the development of allied theories that have shaped modern physics and led to this new view of the universe.
Although he allows that "it has not been possible to test any of our new theories of quantum gravity experimentally," Smolin predicts that a solid framework will be established by 2015 at the outside. If he's correct, the years in between promise to be an exciting time for students of the physical sciences, and Smolin's book makes an engaging introduction to some of the big questions they'll be asking. --Gregory McNamee
Although he allows that "it has not been possible to test any of our new theories of quantum gravity experimentally," Smolin predicts that a solid framework will be established by 2015 at the outside. If he's correct, the years in between promise to be an exciting time for students of the physical sciences, and Smolin's book makes an engaging introduction to some of the big questions they'll be asking. --Gregory McNamee
260 pages, Kindle Edition
First published January 1, 2000
230 people are currently reading
7433 people want to read
About the author
Lee Smolin
12 books435 followersLee Smolin is a theoretical physicist who has made influential contributions to the search for a unification of physics. He is a founding faculty member of the Perimeter Institute for Theoretical Physics. His previous books include The Trouble with Physics, The Life of the Cosmos and Three Roads to Quantum Gravity.
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Displaying 1 - 30 of 117 reviews
May 7, 2009
Lee Smolin is one of the most interesting and controversial figures in modern physics. Establishment physicists often call him a maverick or worse. I am one of many laypeople who think that he's telling it like it is, and the mainstream people are full of s...trings.
When he wrote this book, around 1999, I think he was more part of the mainstream. He presents several different approaches to the very difficult problem of unifying gravity and quantum mechanics. It's clear that his heart belongs to Loop Quantum Gravity, but he tries to be as even-handed as possible. He ends up on an optimistic note, and says that he thinks there will be a real unified theory within the next 10-15 years. Something will work.
Alas, in The Trouble with Physics, seven years later, one of the first things he did was to retract his earlier prediction, and in the most categorical way possible. "We have failed." Sobering words.
When he wrote this book, around 1999, I think he was more part of the mainstream. He presents several different approaches to the very difficult problem of unifying gravity and quantum mechanics. It's clear that his heart belongs to Loop Quantum Gravity, but he tries to be as even-handed as possible. He ends up on an optimistic note, and says that he thinks there will be a real unified theory within the next 10-15 years. Something will work.
Alas, in The Trouble with Physics, seven years later, one of the first things he did was to retract his earlier prediction, and in the most categorical way possible. "We have failed." Sobering words.
October 15, 2021
Anyone who has been paying attention to physics in the last twenty years or so has heard of Lee Smolin. His stances are well known, particularly thanks to his most famous book, The Trouble with Physics, which was released a few years later than Three Roads to Quantum Gravity. In this book, he sets out to discuss possible ways to unite General Relativity and Quantum Mechanics into the so-called Theory of Quantum Gravity. He gives an accessible description of the different “roads” to achieve this, even if at times in a rather simplistic way. I must say that it’s quite interesting to see how optimistic he was in relation to both the state of physics at the time and the future of Quantum Gravity. I guess he ended up changing his mind (spoiler alert!), as the title of his next book (The Trouble with Physics) indicates.
November 26, 2020
Lots of great thoughts, but wordy like a thick hedge is dense. It’s not the scientific terms so much as not well-edited. If this were half as long and covered the same ideas, it would be twice as readable. I’ll be reading it again, but dreading some long passages, yet looking forward to the science and ideas.
After about a year of reading Rovelli over and over, I understood more of Smolin. It’s a good feeling to be learning. I’ll read this one again.
After about a year of reading Rovelli over and over, I understood more of Smolin. It’s a good feeling to be learning. I’ll read this one again.
June 18, 2023
The three roads discussed by Smolin in the book are loop quantum gravity, string theory, and a third approach called "causal dynamical triangulations."
Smolin provides an overview of each approach, explaining their underlying principles, mathematical frameworks, and the progress made in each area at the time of writing.
Loop quantum gravity is a candidate theory that quantizes space itself, describing it as a discrete network of interconnected loops. String theory, on the other hand, posits that elementary particles are not point-like objects but rather tiny strings or membranes vibrating in higher-dimensional space. The third approach, causal dynamical triangulations, explores the possibility of discretizing spacetime into triangular building blocks.
Throughout the book, Smolin discusses the advantages and challenges of each approach and provides insights into the deep conceptual and mathematical issues that arise in the pursuit of a theory of quantum gravity.
Smolin provides an overview of each approach, explaining their underlying principles, mathematical frameworks, and the progress made in each area at the time of writing.
Loop quantum gravity is a candidate theory that quantizes space itself, describing it as a discrete network of interconnected loops. String theory, on the other hand, posits that elementary particles are not point-like objects but rather tiny strings or membranes vibrating in higher-dimensional space. The third approach, causal dynamical triangulations, explores the possibility of discretizing spacetime into triangular building blocks.
Throughout the book, Smolin discusses the advantages and challenges of each approach and provides insights into the deep conceptual and mathematical issues that arise in the pursuit of a theory of quantum gravity.
September 24, 2017
a nice, easy intro into quantum gravity for the interested: http://homepages.ecs.vuw.ac.nz/~visse...
This book isn't too bad but I don't think I retain much. the feline analogy and cosmological evolution are cute ideas, and the black hole stuff is fascinating. but much of it is extremely speculative and cryptic rambling. Or maybe I just get more cynical of theoretical physics day by day. That's fine, and at least Lee Smolin acknowledges that it is speculative, but at least don't be so incredibly optimistic when you don't have a single suggestion for an experiment that can verify or falsify your theory.
Quantum mechanics and general relativity are both excellent theories, but when they combine, the infinities explode in your face. Quantum gravity has got physicists banging their heads into the wall for the last 50 years and his overt optimism slightly bugs me. Quantum physicists (including string theorists) adore their theory so much they're willing to mutilate general relativity one way or another to pursue their cause, general relativists hold GR so sacrosanct that they can curve quantum mechanics to fit their theory (sorry for the pun). Somewhere in the middle is lattice theorists who annoy both camps. So basically, nobody really knows exactly how to solve this conundrum.
I'm not hugely a fan of a theory that can't be tested. Stuff like Hawking radiation or gravitational wave might be extremely hard to detect, but at least physicists have built the acoustic equivalent of Hawking radiation (http://www.technologyreview.com/blog/...) and (arguably) figured out how to detect grav. waves. This guy has no similar suggestions of that sort, except for the deviations of photon paths across large distances. Hm...
He seems to have held favorable views of string theory at that time, on which he has changed his mind. Last month was the 25th year anniversary of the resurrection of string theory, and you can notice the lack of celebration in the string community. He does admit in chapter 11 that nobody even knows what string theory really IS or what its basic principles are, there are hundreds of consistent versions of it and "what we have is a long list of examples of solutions to the theory; what we do not yet have is the theory they are solutions of". The major problem with string theory is that it's so loose that whatever experiment data you come out with, some string theorist can claim he predicted it.
But Lee Smolin certainly taught me something very honorable about a theoretical physics career. That when you reach the forefront, you have to accept to take hazy paths that no one's taken and can be deemed ridiculous or obscure and perhaps risk wasting your entire career pursuing something wrong. And you will collaborate, compete, argue, disagree, be proven wrong, admit you're wrong, but that's an unavoidable part of progress, to put down the post "don't go there" on the wrong paths so some giant can find the right way to get there some day.
This book isn't too bad but I don't think I retain much. the feline analogy and cosmological evolution are cute ideas, and the black hole stuff is fascinating. but much of it is extremely speculative and cryptic rambling. Or maybe I just get more cynical of theoretical physics day by day. That's fine, and at least Lee Smolin acknowledges that it is speculative, but at least don't be so incredibly optimistic when you don't have a single suggestion for an experiment that can verify or falsify your theory.
Quantum mechanics and general relativity are both excellent theories, but when they combine, the infinities explode in your face. Quantum gravity has got physicists banging their heads into the wall for the last 50 years and his overt optimism slightly bugs me. Quantum physicists (including string theorists) adore their theory so much they're willing to mutilate general relativity one way or another to pursue their cause, general relativists hold GR so sacrosanct that they can curve quantum mechanics to fit their theory (sorry for the pun). Somewhere in the middle is lattice theorists who annoy both camps. So basically, nobody really knows exactly how to solve this conundrum.
I'm not hugely a fan of a theory that can't be tested. Stuff like Hawking radiation or gravitational wave might be extremely hard to detect, but at least physicists have built the acoustic equivalent of Hawking radiation (http://www.technologyreview.com/blog/...) and (arguably) figured out how to detect grav. waves. This guy has no similar suggestions of that sort, except for the deviations of photon paths across large distances. Hm...
He seems to have held favorable views of string theory at that time, on which he has changed his mind. Last month was the 25th year anniversary of the resurrection of string theory, and you can notice the lack of celebration in the string community. He does admit in chapter 11 that nobody even knows what string theory really IS or what its basic principles are, there are hundreds of consistent versions of it and "what we have is a long list of examples of solutions to the theory; what we do not yet have is the theory they are solutions of". The major problem with string theory is that it's so loose that whatever experiment data you come out with, some string theorist can claim he predicted it.
But Lee Smolin certainly taught me something very honorable about a theoretical physics career. That when you reach the forefront, you have to accept to take hazy paths that no one's taken and can be deemed ridiculous or obscure and perhaps risk wasting your entire career pursuing something wrong. And you will collaborate, compete, argue, disagree, be proven wrong, admit you're wrong, but that's an unavoidable part of progress, to put down the post "don't go there" on the wrong paths so some giant can find the right way to get there some day.
May 11, 2015
According to Smolin, there are three "roads" currently leading to a theory of quantum gravity: the first road begins from quantum theory and adds relativity (string theory), the second begins from general relativity and adds quantum theory (loop quantum gravity), and the third rejects both and tries to consider the question from first principles. (This third road is basically not discussed, and later in the book the third road becomes thermodynamics of black holes and the "holographic principle".) There are a few mentions of other approaches such as Alain Connes' non-commutative geometry and Roger Penrose's twistor theory, but none is actually explained. Smolin himself worked for a time on string theory, but today is identified with the loop quantum gravity approach. As of the time this book was written (i.e. about fifteen years ago; I haven't gotten to anything more recent yet, since I'm reading the library's astronomy and related physics books chronologically) about ninety percent of those working on quantum gravity were committed more or less strongly to string theory as the sole viable approach, so Smolin's views are in a minority, and much of his book is arguing that minority approaches should be encouraged (and funded). Looking on Amazon at his later books and the reviews of them, I get the impression that he has continued to move further from the mainstream.
Late last year, I read Smolin's Life of the Cosmos, and was very impressed by his approach and his use of philosophy, and the clearness of his explanations of the basic theories such as general relativity and quantum theory, the Anthropic Principle, and the questions which they raise, and though I was not convinced by his speculative theory of cosmological natural selection, I was intrigued by the idea. Of course, I'm very much a layman when it comes to physics and astronomy, so my opinions don't count for much except for my own view of the world. Much of my popular science reading in the past few months has favored string theory (e.g. the awful Hyperspace by Michio Kaku, and the excellent The Elegant Universe by Brian Greene) so I was looking forward to reading this account and learning about the alternative(s).
Unfortunately, this is a much less well-written book than Life of the Cosmos. It does cover many aspects of modern physics and cosmogony that I was unfamiliar with, and it begins well. In the first section, called "Points of Departure", Smolin emphasizes the relational aspects of space-time as constituted not by absolute space and time (he argues that many relativists ignore the basic breakthrough of relativity, using it to derive local geometries of space-time which are then treated as absolute backgrounds in a non-relativistic manner) nor even by relations among things (either particles or strings) but by relations among events or processes. (Surprisingly, he mentions Hegel and Heidegger but not Whitehead in this connection, but this is a much less philosophical book than the earlier one, at least in terms of discussing writers who would be called "philosophers".)
The second section, "What We Have Learned", discusses the history of loop quantum gravity theory (partly from a personal perspective) and has chapters on the entropy of black holes and a chapter on string theory as well. The problem is that I got no real understanding of what LQG is actually saying. He does tell us (over and over, the book is very repetitive) that space (and time? he doesn't discuss this) is discrete rather than continuous, and that the loops are also discrete. But he never really explained what they are, except that they are "like" the discrete lines of magnetic field in a superconductor. The "glossary" at the end of the book defines "loop" as "a circle drawn in space"! That's the whole definition of the most important concept in the book! The problem may be that he is so involved in the theory that he doesn't realize the lay reader (for whom the book is supposedly written; this is explicitly a popularization and not a book for physicists) has no idea of what LQG is, and probably doesn't know a lot about superconductors either, so he assumes that the analogy will make everything clear. It doesn't, at least to me. He claims that he has been very evenhanded in discussing the three "roads", and particularly that he is fairer to string theory than string theorists are to other approaches (this at least is true, since I've never read a book on string theory that mentioned any alternative except leaving the standard model of quantum theory as is), but the chapter on string theory basically is just about what's wrong with it (not background independent, not testable -- though neither is LCG, not unique) and I would not have understood it without having read other books on the subject. The chapters on black holes and their entropy were the most interesting part of the book, and the ones I got the most out of, but here again he alternates between beating the horse with simplistic analogies and just assuming advanced ideas without explanation. There is no math in the book, and this may be part of the problem, since these ideas make little sense in purely descriptive language.
The last part of the book explains the "holographic principle", whines a bit about how non-string-theorists aren't taken seriously enough (or paid well enough) and then gives his conclusions on what the final theory of quantum gravity will look like: LQG (no surprise) will be the basic framework; it will involve discrete space; it will make extensive use of the holographic principle, and generally will be based on what observers in different places can actually observe; it will borrow ideas from other approaches such as non-commutative geometry and twistors; string theories will turn out to be approximations to the true theory on the assumption of various fixed space-times. This will all be developed (and possibly empirically confirmed) by about 2010, or 2015 at the latest. (While I haven't read the latest developments, I am fairly sure we're not that far along -- which may be why his latest books all have phrases like "the crisis of physics" in the title.)
To sum up: an interesting book about an interesting subject, but not well written and not a good introduction to LQG, which is the main reason for reading it; I hope one of the later books on my list will give me a better idea of alternatives to string theory, as well as where we actually are now. (I know at least Penrose's book on twistor theory will cover that approach, IF I can understand the math -- he claims the book teaches all the math needed, but I'm skeptical, even though I was a math minor in college.)
Late last year, I read Smolin's Life of the Cosmos, and was very impressed by his approach and his use of philosophy, and the clearness of his explanations of the basic theories such as general relativity and quantum theory, the Anthropic Principle, and the questions which they raise, and though I was not convinced by his speculative theory of cosmological natural selection, I was intrigued by the idea. Of course, I'm very much a layman when it comes to physics and astronomy, so my opinions don't count for much except for my own view of the world. Much of my popular science reading in the past few months has favored string theory (e.g. the awful Hyperspace by Michio Kaku, and the excellent The Elegant Universe by Brian Greene) so I was looking forward to reading this account and learning about the alternative(s).
Unfortunately, this is a much less well-written book than Life of the Cosmos. It does cover many aspects of modern physics and cosmogony that I was unfamiliar with, and it begins well. In the first section, called "Points of Departure", Smolin emphasizes the relational aspects of space-time as constituted not by absolute space and time (he argues that many relativists ignore the basic breakthrough of relativity, using it to derive local geometries of space-time which are then treated as absolute backgrounds in a non-relativistic manner) nor even by relations among things (either particles or strings) but by relations among events or processes. (Surprisingly, he mentions Hegel and Heidegger but not Whitehead in this connection, but this is a much less philosophical book than the earlier one, at least in terms of discussing writers who would be called "philosophers".)
The second section, "What We Have Learned", discusses the history of loop quantum gravity theory (partly from a personal perspective) and has chapters on the entropy of black holes and a chapter on string theory as well. The problem is that I got no real understanding of what LQG is actually saying. He does tell us (over and over, the book is very repetitive) that space (and time? he doesn't discuss this) is discrete rather than continuous, and that the loops are also discrete. But he never really explained what they are, except that they are "like" the discrete lines of magnetic field in a superconductor. The "glossary" at the end of the book defines "loop" as "a circle drawn in space"! That's the whole definition of the most important concept in the book! The problem may be that he is so involved in the theory that he doesn't realize the lay reader (for whom the book is supposedly written; this is explicitly a popularization and not a book for physicists) has no idea of what LQG is, and probably doesn't know a lot about superconductors either, so he assumes that the analogy will make everything clear. It doesn't, at least to me. He claims that he has been very evenhanded in discussing the three "roads", and particularly that he is fairer to string theory than string theorists are to other approaches (this at least is true, since I've never read a book on string theory that mentioned any alternative except leaving the standard model of quantum theory as is), but the chapter on string theory basically is just about what's wrong with it (not background independent, not testable -- though neither is LCG, not unique) and I would not have understood it without having read other books on the subject. The chapters on black holes and their entropy were the most interesting part of the book, and the ones I got the most out of, but here again he alternates between beating the horse with simplistic analogies and just assuming advanced ideas without explanation. There is no math in the book, and this may be part of the problem, since these ideas make little sense in purely descriptive language.
The last part of the book explains the "holographic principle", whines a bit about how non-string-theorists aren't taken seriously enough (or paid well enough) and then gives his conclusions on what the final theory of quantum gravity will look like: LQG (no surprise) will be the basic framework; it will involve discrete space; it will make extensive use of the holographic principle, and generally will be based on what observers in different places can actually observe; it will borrow ideas from other approaches such as non-commutative geometry and twistors; string theories will turn out to be approximations to the true theory on the assumption of various fixed space-times. This will all be developed (and possibly empirically confirmed) by about 2010, or 2015 at the latest. (While I haven't read the latest developments, I am fairly sure we're not that far along -- which may be why his latest books all have phrases like "the crisis of physics" in the title.)
To sum up: an interesting book about an interesting subject, but not well written and not a good introduction to LQG, which is the main reason for reading it; I hope one of the later books on my list will give me a better idea of alternatives to string theory, as well as where we actually are now. (I know at least Penrose's book on twistor theory will cover that approach, IF I can understand the math -- he claims the book teaches all the math needed, but I'm skeptical, even though I was a math minor in college.)
February 17, 2009
Lee Smolin stormed his way onto my fantasy grandfather list the fateful summer of 2008 when I realized physics and I were more than just a fling. His The Trouble with Physics was a fatherly introduction to the current state of the edges of theoretical physics and I was hooked. Needless to see, I was ecstatic to find "Three Roads to Quantum Gravity" under my Christmas tree this year and devoured it on plane ride to Thailand soon after.
"Three Roads to Quantum Gravity" is Smolin's briefing to the public on several current approaches to the quest for the unification of quantum theory and gravity. It weaves a tale that passes through quantum information theory, cosmology, and many other delicious details but, importantly, begins by focusing on the fundamental qualities that he believes any current theory should possess. The book is openly biased against the somewhat publicly alluring string theory, and I recommend that any reader complement this dish with a side of Brian Greene's The Elegant Universe.
Smolin's criteria run something like this. The theory must be background-independent. It must be a physics based on relations, not on absolutes. Processes, not objects, must be fundamental. This gels with the idea of a human being as a pattern of information and not a specific set of matter (guess what percentage of your atoms are recycled every two weeks). The theory must accommodate many different observes. The finite age of the universe and special relativity's upper bound on speed mean that no one in the universe has access to all information available and each observer indeed has a different picture based on their location. Black holes place additional information boundaries throughout the universe. A single observer's "information space" might look somewhat like a sphere of Swiss cheese, the holes representing black holes, the cheese representing areas which the observer may receive information from, and "beyond the cheese" as the space from which information hasn't had time to reach the observer just yet.
This last problem has an interesting parallel in theories of the brain. Sensory information propagates to each of us at very different rates light faster than sound, sound faster than smells (particle diffusion), etc. Signals in the brain also travel at finite speeds (far slower than the speed of light). These finite speeds apply to both sensory information and "decisional" information other areas in the brain. This means that different parts of the brain have access to different information at any given time. Future theories of consciousness may very well have something powerful to say about about observer-dependent physics (and vice versa).
Continuing our discussion of information in the universe, Jakob Bekenstein's studies of black hole entropy have led to the recently popularized holographic principle - a surface bounding a region of space contains all the information contained within. Information is "projected" from the 3D interior onto the 2D boundary. Whether to view the 2D projection as fundamental and the 3D interior as "derived" or vice versa is still (as far as I know) an open question for theory. Bekenstein also placed a boundary of the possible amount of information represented, suggesting a quantization of space. In this picture, geometry can be viewed as defining the information channels of the universe.
One final fascinating theoretical nugget that Smolin presents is that accelerating observers are granted a window into the quantum fluctuations of space in the form of experiencing a hot photon gas whose temperature is proportional to their acceleration. The basic idea is that quantum fluctuations normally go undetected since they have no energy but when you accelerate "fast enough" your relative motion allows you to experience them as having an energy. You experience this random motion as heat.
"Three Roads to Quantum Gravity" is Smolin's briefing to the public on several current approaches to the quest for the unification of quantum theory and gravity. It weaves a tale that passes through quantum information theory, cosmology, and many other delicious details but, importantly, begins by focusing on the fundamental qualities that he believes any current theory should possess. The book is openly biased against the somewhat publicly alluring string theory, and I recommend that any reader complement this dish with a side of Brian Greene's The Elegant Universe.
Smolin's criteria run something like this. The theory must be background-independent. It must be a physics based on relations, not on absolutes. Processes, not objects, must be fundamental. This gels with the idea of a human being as a pattern of information and not a specific set of matter (guess what percentage of your atoms are recycled every two weeks). The theory must accommodate many different observes. The finite age of the universe and special relativity's upper bound on speed mean that no one in the universe has access to all information available and each observer indeed has a different picture based on their location. Black holes place additional information boundaries throughout the universe. A single observer's "information space" might look somewhat like a sphere of Swiss cheese, the holes representing black holes, the cheese representing areas which the observer may receive information from, and "beyond the cheese" as the space from which information hasn't had time to reach the observer just yet.
This last problem has an interesting parallel in theories of the brain. Sensory information propagates to each of us at very different rates light faster than sound, sound faster than smells (particle diffusion), etc. Signals in the brain also travel at finite speeds (far slower than the speed of light). These finite speeds apply to both sensory information and "decisional" information other areas in the brain. This means that different parts of the brain have access to different information at any given time. Future theories of consciousness may very well have something powerful to say about about observer-dependent physics (and vice versa).
Continuing our discussion of information in the universe, Jakob Bekenstein's studies of black hole entropy have led to the recently popularized holographic principle - a surface bounding a region of space contains all the information contained within. Information is "projected" from the 3D interior onto the 2D boundary. Whether to view the 2D projection as fundamental and the 3D interior as "derived" or vice versa is still (as far as I know) an open question for theory. Bekenstein also placed a boundary of the possible amount of information represented, suggesting a quantization of space. In this picture, geometry can be viewed as defining the information channels of the universe.
One final fascinating theoretical nugget that Smolin presents is that accelerating observers are granted a window into the quantum fluctuations of space in the form of experiencing a hot photon gas whose temperature is proportional to their acceleration. The basic idea is that quantum fluctuations normally go undetected since they have no energy but when you accelerate "fast enough" your relative motion allows you to experience them as having an energy. You experience this random motion as heat.
February 23, 2022
I am more invested in the frontiers of loop quantum gravity and string theory than I am in my own dating life
March 22, 2017
Since Lee Smolin has been one of the leading figures both in the string theory and in the theory of loop quantum gravity, I hoped this book would clarify some questions I was left with after reading Carlo Rovelli's Reality Is Not What It Seems: The Journey to Quantum Gravity. I think the main reason both the books failed to do the job is the fact that I lack the adequate background to understand what is really meant by ''strings'' and ''loops'' in the two main approaches to quantum gravity. I find the concept of the loop quantum gravity particularly interesting but it still remains unclear to me what is really meant by ''quanta of space''.
As for the third road, I found the chapters on the holographic principle, inspired by the black hole thermodynamics and the Bekenstein bound, highly interesting.
As for the third road, I found the chapters on the holographic principle, inspired by the black hole thermodynamics and the Bekenstein bound, highly interesting.
January 3, 2021
So this book is from 2000 and I read Smolin's 2006 "The Trouble With Physics" first, but I still found the social aspect of the different tracks the physicists are following interesting. I struggled to understand some of the actual physics he was explaining but feel comforted by the fact that apparently a lot of the physicists themselves do not understand or believe each other anyway. Ha! [Note: I prefer Brian Greene or Stephen Hawkings for explaining physics slowly to laypeople.]
May 6, 2015
Smolin describes his thinking about how quantum theory (micro level) might be linked to Einstein’s gravitational theory (macro level), to become “a quantum theory of gravity.” His argument is by no means easy for the lay reader to follow, so what follows may not be an accurate rendering.
At the minutest level of reality (spacetime on Planck scale) are strings (“a string is actually made of discrete pieces, called string bits, each of which carries a discrete amount of momentum and energy”). Particles come from the different vibrations of strings and particles interact with particles through “splitting and joining.” Smolin then argues that strings (actually, “string bits”) are more fundamental than particles and that, with such strings, “On the Planck scale, space appears to be composed of fundamental discrete units.” From that observation, Smolin goes on to say that at the core of subatomic reality there are no things in space. There are only interactions, relationships in motion, which are constant. Presumably, this means that things continuously come into and go out of being. These processes do not occur on or within a backdrop of spacetime. Rather, these processes create space (distance between interacting particles – via fields?) and time (the measure of distance between interacting particles). There is, in other words, no static point in spacetime: “Neither space nor time has any existence outside the system of evolving relationships that comprises the universe.”
Space is filled with the interactions described above in what Smolin calls the “atomic structure of space” through various forms of radiation (light traveling through space; cosmic rays; cosmic microwaves from the big bang). Although Smolin does not say this explicitly, all of this, collectively, appears to constitute the fabric of spacetime (related to dark matter and energy?) that is at the heart of Einstein’s general theory of relativity (larger masses depress spacetime and “attract” smaller bodies), though this gets confusing when Smolin states elsewhere that space is “empty” and, from Newton, that “gravity pulls on mass.”
Moving from the micro, atomic level, Smolin believes that all of space and time is a swirl of these relationships, with one thing causing (creating) another, in a perpetual process. There is never a moment in time or point in space; there’s only an event of the present that is preceded by events of the past and that cause (create) events of the future. This is described in Figure 10, P. 58. Each event has its own set of past and future linkages; outside of this “cone” of interaction, other separate events occur, each with its own set of past-future casual linkages. In Smolin’s words, “Time and change are not optional, for the universe is a story and it is composed of processes. In such a world, time and causality are synonymous. There is no meaning to the past of an event except the set of events that caused it. And there is no meaning to the future of an event except the set of events it will influence. When we are dealing with a causal universe, we can therefore shorten ‘causal past’ and ‘causal future’ to simply ‘past’ and ‘future’….There is time, but there is not really any notion of a moment of time.”*
*In elaborating, Smolin’s vision stands in stark contrast to Plato’s notion of the Real. “The idea of a state in Newtonian physics shares with classical sculpture and painting the illusion of the frozen moment,” Smolin writes. “This gives rise to the illusion that the world is composed of objects. If this were really the way the world is, then the primary description of something would be how it is, and change in it would be secondary. Change would be nothing but alterations in how something is. But relativity and quantum theory each tell us that this is not how the world is. They tell us – no, better, they scream at us – that our world is a history of processes. Motion and change are primary. Nothing is, except in a very approximate and temporary sense. How something is, or what its state is, is an illusion. It may be a useful illusion for some purposes, but if we want to think fundamentally we must not lose sight of the essential fact that ‘is’ is an illusion. So to speak the language of the new physics we must learn a vocabulary in which process is more important than, and prior to, stasis.”
At the minutest level of reality (spacetime on Planck scale) are strings (“a string is actually made of discrete pieces, called string bits, each of which carries a discrete amount of momentum and energy”). Particles come from the different vibrations of strings and particles interact with particles through “splitting and joining.” Smolin then argues that strings (actually, “string bits”) are more fundamental than particles and that, with such strings, “On the Planck scale, space appears to be composed of fundamental discrete units.” From that observation, Smolin goes on to say that at the core of subatomic reality there are no things in space. There are only interactions, relationships in motion, which are constant. Presumably, this means that things continuously come into and go out of being. These processes do not occur on or within a backdrop of spacetime. Rather, these processes create space (distance between interacting particles – via fields?) and time (the measure of distance between interacting particles). There is, in other words, no static point in spacetime: “Neither space nor time has any existence outside the system of evolving relationships that comprises the universe.”
Space is filled with the interactions described above in what Smolin calls the “atomic structure of space” through various forms of radiation (light traveling through space; cosmic rays; cosmic microwaves from the big bang). Although Smolin does not say this explicitly, all of this, collectively, appears to constitute the fabric of spacetime (related to dark matter and energy?) that is at the heart of Einstein’s general theory of relativity (larger masses depress spacetime and “attract” smaller bodies), though this gets confusing when Smolin states elsewhere that space is “empty” and, from Newton, that “gravity pulls on mass.”
Moving from the micro, atomic level, Smolin believes that all of space and time is a swirl of these relationships, with one thing causing (creating) another, in a perpetual process. There is never a moment in time or point in space; there’s only an event of the present that is preceded by events of the past and that cause (create) events of the future. This is described in Figure 10, P. 58. Each event has its own set of past and future linkages; outside of this “cone” of interaction, other separate events occur, each with its own set of past-future casual linkages. In Smolin’s words, “Time and change are not optional, for the universe is a story and it is composed of processes. In such a world, time and causality are synonymous. There is no meaning to the past of an event except the set of events that caused it. And there is no meaning to the future of an event except the set of events it will influence. When we are dealing with a causal universe, we can therefore shorten ‘causal past’ and ‘causal future’ to simply ‘past’ and ‘future’….There is time, but there is not really any notion of a moment of time.”*
*In elaborating, Smolin’s vision stands in stark contrast to Plato’s notion of the Real. “The idea of a state in Newtonian physics shares with classical sculpture and painting the illusion of the frozen moment,” Smolin writes. “This gives rise to the illusion that the world is composed of objects. If this were really the way the world is, then the primary description of something would be how it is, and change in it would be secondary. Change would be nothing but alterations in how something is. But relativity and quantum theory each tell us that this is not how the world is. They tell us – no, better, they scream at us – that our world is a history of processes. Motion and change are primary. Nothing is, except in a very approximate and temporary sense. How something is, or what its state is, is an illusion. It may be a useful illusion for some purposes, but if we want to think fundamentally we must not lose sight of the essential fact that ‘is’ is an illusion. So to speak the language of the new physics we must learn a vocabulary in which process is more important than, and prior to, stasis.”
April 27, 2016
this book is so dumbed-down that i seriously considered putting it on the "non-fiction for humans" shelf. the absolute nadir came when he used as his analogy for the superposition principle of quantum mechanics a mouse which, when eaten by a cat, might turn out to be either "tasty" or "yukky". Yukky? Yukky? forget that it's universally spelled "yucky". but he hammers away at his analogy and the reader is subjected to the word "yukky" several times over a few pages.
but thank the lord most of the fingernails-on-the-chalkboard stuff like that is in the first 60 pages, and after that the book is pretty informative, although he does have some rough spots.
also mildly interesting were some of his narrative sections about his own work and the culture of theoretical scientists. sadly, he seems ridiculously optimistic about how soon he and his colleagues will finally work out the correct theory of all fundamental physics.
but thank the lord most of the fingernails-on-the-chalkboard stuff like that is in the first 60 pages, and after that the book is pretty informative, although he does have some rough spots.
also mildly interesting were some of his narrative sections about his own work and the culture of theoretical scientists. sadly, he seems ridiculously optimistic about how soon he and his colleagues will finally work out the correct theory of all fundamental physics.
July 25, 2017
Excellent book describing how the routes to quantum gravity work in rather precise but laymen terms. The human elements are also very clearly done. However, there is clear "side" taken in making loop quantum gravity sound "better" than string theory, which from what I know on technical level they are both stuck in equally critical stalemate (maybe I am wrong). But otherwise it is a good exposition, especially when Smolin laid clear the "philosophy" behind doing science - what are our biases, etc.
April 11, 2018
My professor asked me to starting reading literature for writing my master thesis, so I perused the library for some interesting reads. And oh boy, did I hit gold. Masterfully written by one of the people deeply invested in solving the problem of Quantum Gravity, Smolin takes a broad view of the possibilities. His writing is awkward when trying to do philosophical science but when he gets to the gritty areas, his analogies are beautiful. He talks about Loop Quantum Gravity, String Theory and other approaches as "the three roads". My biggest lesson was that these roads are not exclusive but complementary. Bridging ideas and successes from wide approaches is the key to understanding quantum gravity. I have learned deep lessons and acquired good writing material from this book. Would recommend to anyone vested in the problem of quantum gravity. While Smolin comes off as a sanguine person (he predicts the final form for QG to be settled by 2010 and at most 2015; the book was written in 2002), his lessons are key to understanding nature.
August 3, 2018
Not the typical quantum trip down the garden path leading from Aristotle, Galileo and Newton to Einstein, Bohr and Heisenberg. Instead Smolin waves his hand out the window as he Ferraris by classical and early mechanics gardens to take us for a spin on each of the three roads that will get us to his horizon point, quantum gravity being taught in high school classrooms by the end of the 21st century. To get up to speed, he takes the cat out of the Schrödingerian box and gives them some mice to eat, talks of strings, loops and knots (dangled in front of the cat, no doubt, with a tasty mouse in its mouth) before screeching into a hard turn with his holographic principle. I’d like to claim I have understood what it means to only have access to what on the screen, the circular base of a light cone, while the event (aka The Thing) remains out of reach at the cone’s vortex. Perhaps the grandchild students of my current elementary students will be able to talk M Theory like it ain’t no thing, but if we can create virtual particles, possibly even virtual light, then who’s to say there ever was or will be the Thing. Anyhoo, lots more that I want to learn about holographs and the shape of reality. Looking forward to finding out what Smolin’s sailing buddy Rovelli has to say. He probably drives a Lamborghini!
July 9, 2022
brilliant
Lee Smolin has surely accomplished his objective. Explaining as clearly as possible without the math what the theory of Loop Quantum Gravity is all about and how it relates to String Theory. My sincere thanks because I finally get what the loops are and how they are different from the strings. To get it too you’ll have to read this excellent book. Slowly and carefully. ( And then add 5 to 10 years of deep study and research if you really want to get it - and have the time and the cash to do so. And decide to prioritize this over thousands of other deep and interesting questions. )
Like most obviously great minds the author is clearly as optimistic as he is voraciously curious. He makes some predictions for the future of these lines of research. Written in 2000.
1. There would be a more or less complete theory by 2015. To the best of my knowledge. No. A bit too optimistic.
2. That by the end of the 21st century The principles of quantum gravity would be taught in High Schools. Wow. I certainly hope so.
Lee Smolin has surely accomplished his objective. Explaining as clearly as possible without the math what the theory of Loop Quantum Gravity is all about and how it relates to String Theory. My sincere thanks because I finally get what the loops are and how they are different from the strings. To get it too you’ll have to read this excellent book. Slowly and carefully. ( And then add 5 to 10 years of deep study and research if you really want to get it - and have the time and the cash to do so. And decide to prioritize this over thousands of other deep and interesting questions. )
Like most obviously great minds the author is clearly as optimistic as he is voraciously curious. He makes some predictions for the future of these lines of research. Written in 2000.
1. There would be a more or less complete theory by 2015. To the best of my knowledge. No. A bit too optimistic.
2. That by the end of the 21st century The principles of quantum gravity would be taught in High Schools. Wow. I certainly hope so.
January 26, 2022
Three Roads To Quantum Gravity contains interesting thoughts, but leaves a somewhat empty feeling, like something's incomplete. Perhaps intentionally because the theory the author describes the roads to is incomplete?
Still, worth noting is that this requires knowledge of the key concepts ahead, since it doesn't explain much of general relativity, EPR, interpretations of quantum mechanics. On the other hand, it doesn't go deep into explanations and meaning of discussed theories. Perhaps it's at its best when talking about black holes and entropy, but final chapters are mostly about stating which physicists in period from 1970s produced what theory, but rarely going into the details of what the theory explicitly says, what it would mean if it were true, nor how would we test if it were correct.
Still, worth noting is that this requires knowledge of the key concepts ahead, since it doesn't explain much of general relativity, EPR, interpretations of quantum mechanics. On the other hand, it doesn't go deep into explanations and meaning of discussed theories. Perhaps it's at its best when talking about black holes and entropy, but final chapters are mostly about stating which physicists in period from 1970s produced what theory, but rarely going into the details of what the theory explicitly says, what it would mean if it were true, nor how would we test if it were correct.
June 12, 2008
Either I'm getting progressively dumber, or the books I'm reading are getting progressively harder for me to understand. Hopefully it's the latter of the two. I enjoyed this book in principle, however there was a lot that I had trouble understanding. I think I was able to grasp the basic ideas behind most of the theories mentioned, but some of the finer details may have been lost on me.
Still, Smolin does give very detailed explanations for the different versions of String Theory, Loop Quantum Gravity, M Theory, The Holographic Theory and other ideas such as Spin Networks and Spin Foam.
If you've got a basic understanding of the ideas of quantum physics then I think you'll enjoy this book. If you know nothing about quantum physics, then save this book for a later date.
Still, Smolin does give very detailed explanations for the different versions of String Theory, Loop Quantum Gravity, M Theory, The Holographic Theory and other ideas such as Spin Networks and Spin Foam.
If you've got a basic understanding of the ideas of quantum physics then I think you'll enjoy this book. If you know nothing about quantum physics, then save this book for a later date.
May 1, 2012
It's a complicated subject, no doubt. And Smolin does his best to make it narratively accessible. That being said, this book is disjointed and a bit impenetrable, not because Smolin doesn't understand the subject matter. He clearly does! But because his explanations of that subject matter don't seem to answer some basic "why?" and "how?" questions.
But then again, I'm not a physicist so I am probably not the best person to judge.
But then again, I'm not a physicist so I am probably not the best person to judge.
August 29, 2014
Do you know a similar book with a little more technical detail? This was an excellent popular treatment of quantum gravity and related topics but I have read several popular treatments now and find myself wanting to dust off my old math texts and go a little deeper. So if you know something that would challenge someone with a math background comparable to a math major in his junior year, please let me know.
September 21, 2015
Not bad. This book talks about the possibilities of Quantum Gravity as a candidate to be the Unifying Theory of Physics, the Holy Grail if you will. Smolin speaks of his time as an undergraduate and as a postdoc and all of this other stuff of how the theory was developed. It borrows some things from Quantum Chromodynamics and all of that, but it isn't too bad.
I probably won't read it again, but maybe I will read more stuff by Lee Smolin.
I probably won't read it again, but maybe I will read more stuff by Lee Smolin.
December 28, 2010
Can a physicist, however brilliant, explain string theory, M-theory and loop quantum gravity to the lay reader in a 240-page book? I don't think so. However, he can boost the reader's self-esteem by giving the reader the impression that he (the reader) understands these three theoretical frameworks.
May 30, 2022
Smolin neatly explains properties the theory of everything must have and the logical necessities of having the observer be a part of the system (Topos logic?). And this is the first thing in my (limited) reading stating that both time and space are quantized. Spin networks which describe spacetime as graphs is also worth digging into.
July 17, 2023
This books premise was to give an insight on the work that has/is being done to unify the Theory of Relativity to that of Quantum Theory (arguably the single largest problem yet to be solved in the history of physics). The author presents the answer to this problem as the Quantum Theory of Gravity and gives details on three possible solutions of Quantum Gravity so far: Black Hole Thermodynamics, Loop Quantum Gravity, and String Theory. Furthermore, he splits the book into three sections that I have roughly outlined below:
Part I: Points of Departure:
In Part I the author spends some time re-iterating lessons learned through Einstein’s Theory of Relativity (evolving network relationships, light-speed and time relations and the general sense that space nor time has any existence outside the system that demonstrates these relationships). He also touches on Newtonian mechanics and present theories that drive the world as we know it today. Proceeding he makes three (3) main points that he will circle back to in Parts II and III.
1. No outside observers – In classic physical problems we often assume a clean boundary condition where the observer is outside the system, the author points this out as a fundamental problem since nothing can exist outside the universe; Therefore, the observer must be considered.
2. Absolving Background Dependence – In classical Newtonian physics, we consider the background in which the physical act or process occurs to be fixed, aka it is unchanging. The author points this out as another fundamental problem and is in direct contrast in which the Theory of Relativity states that the background is an evolving network of relationships. The author throughout the entirety of the book maintains that the solution of Quantum Gravity cannot use a fixed background.
3. Multiple observers – The author states we must accept that there are many different observers, and that each observer indirectly has a certain amount of information of the world. Here he tries his hand at an alternative Schrodinger’s cat example, which for me was not the best effort. I developed my own example that tries to demonstrate this principle:
A leaf exists in two states:
State A: Attached to a tree
State B: Fallen (Detached from the tree)
Observer 1 walks by the tree and sees the leaf in state A. Their reality in space-time is that the leaf is attached to the tree. Observer 2 walks by the tree and sees the leaf falling and transitioning from State A to State B. Their reality is a superposition of both states, somewhere between A and B. Finally, Observer 3 walks by and sees the leaf on the ground in state B. Their reality is that the leaf is detached from the tree.
If all three of the above were observed, but at different space-time points, then all can be true, but each observer has an interpretation of the past different to one another.
Part II: What We Have Learned:
In Part II the author presents some relatively new information learned at the latter half of the 20th century and its implications on the quantum realm. Most of his time is spent discussing Black Hole Thermodynamics here with the tail end being an introduction to Quantum Loop and String theory. I am not even going to try to summarize the latter half so I will just stick to some key points of Black Hole Thermodynamics:
1. The event horizon area is directly related to the entropy of a Black Hole. As entropy increases within the black hole (the author presents this as more information lost within the black hole) then the Area of the event horizon increases.
2. Quantum observation via constant acceleration: This is a relatively new theory tying the quantum realm to black holes. But basically, if an observer accelerates to a constant speed above the event horizon in complete empty space, then the constant acceleration will cause the observer to be surrounded by a gas of photons and other particles. This acceleration will cause a reading in temperature increase that is directly proportional to acceleration (to be noted that this has never been directly observed). The author communicates that the formula that is used for this measurement has a plank constant tied in so without quantum theory then the plank constant would go to zero (0) and temperature would not increase with this acceleration. Ergo, if we can run this experiment, then it should either confirm or deny existence of Quantum Theory. If the experiment registers temperature changes proportional to acceleration, then bingo quantum theory confirmed, if no temperature change is noted then it is denied.
Part III: The Present Frontiers:
This is where things get out of hand and for the most part over my head, but to generally summarize this section. The author presents the pros and cons of Quantum Loop and String theorem and their strengths and downfalls. He is opinionated in the fact that the answer to a general theory of everything (Quantum Gravity) lies within a theorem that both Quantum Loop and String can be derived from (as I tend to agree since both Quantum Loop and String Theory can be used to solve real life physical problems). He introduces the Holographic Principle which is arguably one of the first tries at developing a theory of everything.
Part I: Points of Departure:
In Part I the author spends some time re-iterating lessons learned through Einstein’s Theory of Relativity (evolving network relationships, light-speed and time relations and the general sense that space nor time has any existence outside the system that demonstrates these relationships). He also touches on Newtonian mechanics and present theories that drive the world as we know it today. Proceeding he makes three (3) main points that he will circle back to in Parts II and III.
1. No outside observers – In classic physical problems we often assume a clean boundary condition where the observer is outside the system, the author points this out as a fundamental problem since nothing can exist outside the universe; Therefore, the observer must be considered.
2. Absolving Background Dependence – In classical Newtonian physics, we consider the background in which the physical act or process occurs to be fixed, aka it is unchanging. The author points this out as another fundamental problem and is in direct contrast in which the Theory of Relativity states that the background is an evolving network of relationships. The author throughout the entirety of the book maintains that the solution of Quantum Gravity cannot use a fixed background.
3. Multiple observers – The author states we must accept that there are many different observers, and that each observer indirectly has a certain amount of information of the world. Here he tries his hand at an alternative Schrodinger’s cat example, which for me was not the best effort. I developed my own example that tries to demonstrate this principle:
A leaf exists in two states:
State A: Attached to a tree
State B: Fallen (Detached from the tree)
Observer 1 walks by the tree and sees the leaf in state A. Their reality in space-time is that the leaf is attached to the tree. Observer 2 walks by the tree and sees the leaf falling and transitioning from State A to State B. Their reality is a superposition of both states, somewhere between A and B. Finally, Observer 3 walks by and sees the leaf on the ground in state B. Their reality is that the leaf is detached from the tree.
If all three of the above were observed, but at different space-time points, then all can be true, but each observer has an interpretation of the past different to one another.
Part II: What We Have Learned:
In Part II the author presents some relatively new information learned at the latter half of the 20th century and its implications on the quantum realm. Most of his time is spent discussing Black Hole Thermodynamics here with the tail end being an introduction to Quantum Loop and String theory. I am not even going to try to summarize the latter half so I will just stick to some key points of Black Hole Thermodynamics:
1. The event horizon area is directly related to the entropy of a Black Hole. As entropy increases within the black hole (the author presents this as more information lost within the black hole) then the Area of the event horizon increases.
2. Quantum observation via constant acceleration: This is a relatively new theory tying the quantum realm to black holes. But basically, if an observer accelerates to a constant speed above the event horizon in complete empty space, then the constant acceleration will cause the observer to be surrounded by a gas of photons and other particles. This acceleration will cause a reading in temperature increase that is directly proportional to acceleration (to be noted that this has never been directly observed). The author communicates that the formula that is used for this measurement has a plank constant tied in so without quantum theory then the plank constant would go to zero (0) and temperature would not increase with this acceleration. Ergo, if we can run this experiment, then it should either confirm or deny existence of Quantum Theory. If the experiment registers temperature changes proportional to acceleration, then bingo quantum theory confirmed, if no temperature change is noted then it is denied.
Part III: The Present Frontiers:
This is where things get out of hand and for the most part over my head, but to generally summarize this section. The author presents the pros and cons of Quantum Loop and String theorem and their strengths and downfalls. He is opinionated in the fact that the answer to a general theory of everything (Quantum Gravity) lies within a theorem that both Quantum Loop and String can be derived from (as I tend to agree since both Quantum Loop and String Theory can be used to solve real life physical problems). He introduces the Holographic Principle which is arguably one of the first tries at developing a theory of everything.
August 19, 2022
More likely that one will find in its pages the very mysticism this book argues against than come away understanding the concepts of loop quantum gravity and string theory. Nonetheless, it is a fairly effective "layman's introduction."
October 13, 2012
I love Smolin's style of writing. A worthwhile read for those interested in the diversity of the field and the questions being tackled.
June 10, 2015
There is some description of the physics mistakes clearly.
It is a disqualification as a physics manual.
It is a disqualification as a physics manual.
October 23, 2022
There is a lot wrong with Three Roads. It presupposes decent familiarity with the basics of not just general relativity and quantum mechanics but also string or loop quantum theories. It was published over a couple of decades ago, which makes it dated, and this is not fixable with just a couple of later-day post scripts. Its earliest projections have been proven comprehensively wrong. Plus, some may find it overly simplistic. Or excessively speculative. Or too verbose. Or often with rather tacky analogies, etc., etc.
And yet, this is a must-read for the non-experts after they have gone through a few more basic, popular books. I have read a few dozen books on these subjects over the last few decades, and I could still find a large collection of new concepts and understandings in this book, which is something I cannot say about even the most recently published ones:
The author is a renowned scientist with ideas that are not generally accepted by the majority in his fraternity. One can almost see why even in the book. The author is a dreamer and loves to speculate what the world's structure could be, even when what he speculates is thoroughly untestable for the foreseeable future.
This is most obvious when the author tries to find a middle ground between his favorite loop quantum gravity (LQG) and the more popular rival string theories. The rapprochement, as per the author, is if the world is constituted of strings that have their background in a lattice of far tinier loops (with the strings also made of the same, tiny loops). The same romanticism is present in the assumption of baby universes behind the black hole event horizons, the expectations of expanding black holes creating their big bangs, or even the invalidated hope of an all-agreed quantum gravity theory in a decade.
The reviewer would like to conclude with one side note on the author's argument that the LQG has a far higher chance of being right because it is a unique, self-sufficient theory. The author states that string theories come in multiple self-sufficient versions. If only strings and nothing else were at the base of our world, our world could only be one of these versions' manifestations. And if that proves to be the case, it would either mean somebody from outside - say, a God - randomly selected this version, or we have to assume a world bubbling with other manifestations with our universe only one of those multiple worlds. The author uses this argument to argue that a bottom-up, self-sufficient LQG may come in only one variety and may not require either of these assumptions.
If this reviewer understood this argument well, it contains a substantial logical fallacy which means there is no true invalidation of the presumption that the world might be one of the string theory manifestations (or something different). We already know that there are completely self-contained theories that do not represent our world. In zero dimensions, such a model would be one of "nothing." The author talks about how scientists have discovered one and two dimensions, self-contained mathematical models that also do not represent our world. One way or the other, our world is, at best, one mathematical model with many others left out. This might be LQG (assuming it is not a specific case of anything else, as the author believes) or a string theory with arbitrary parameters/selections thrown in. It will be impossible to prove - a conjecture - that there is only one mathematical set of equations that can result in a universe/world, while no other set will be fully complete or manifestable.
A lot of words there. In conclusion, the book is worth reading as it provides a lot of new material to think about. But, this one is not for anyone picking up a popular book to understand the basics or anyone who does not like wild, almost mystical conjectures, however smart.
And yet, this is a must-read for the non-experts after they have gone through a few more basic, popular books. I have read a few dozen books on these subjects over the last few decades, and I could still find a large collection of new concepts and understandings in this book, which is something I cannot say about even the most recently published ones:
Observer-dependence realities and the need for the final quantum gravity theory to include the observer as a part of the observed
How a final, decohered reality could imply a superimposition of various histories, with some that different observers might have experienced differently
Black hole thermodynamics and Bekenstein bound that support the atomic or quantized structure of space-time
Potentially different light speeds (or the upper bound) for waves/particles of different frequencies
Background independent nature of general relativity versus the dependency of quantum and string theories
Other details in how the atomic structure of space could be connected to the entropy of blackhole, the event horizon relationships' links to the holographic principles, relational framework of loop quantum theory to explain the atomic structure of space-time, and at least a handful more
The author is a renowned scientist with ideas that are not generally accepted by the majority in his fraternity. One can almost see why even in the book. The author is a dreamer and loves to speculate what the world's structure could be, even when what he speculates is thoroughly untestable for the foreseeable future.
This is most obvious when the author tries to find a middle ground between his favorite loop quantum gravity (LQG) and the more popular rival string theories. The rapprochement, as per the author, is if the world is constituted of strings that have their background in a lattice of far tinier loops (with the strings also made of the same, tiny loops). The same romanticism is present in the assumption of baby universes behind the black hole event horizons, the expectations of expanding black holes creating their big bangs, or even the invalidated hope of an all-agreed quantum gravity theory in a decade.
The reviewer would like to conclude with one side note on the author's argument that the LQG has a far higher chance of being right because it is a unique, self-sufficient theory. The author states that string theories come in multiple self-sufficient versions. If only strings and nothing else were at the base of our world, our world could only be one of these versions' manifestations. And if that proves to be the case, it would either mean somebody from outside - say, a God - randomly selected this version, or we have to assume a world bubbling with other manifestations with our universe only one of those multiple worlds. The author uses this argument to argue that a bottom-up, self-sufficient LQG may come in only one variety and may not require either of these assumptions.
If this reviewer understood this argument well, it contains a substantial logical fallacy which means there is no true invalidation of the presumption that the world might be one of the string theory manifestations (or something different). We already know that there are completely self-contained theories that do not represent our world. In zero dimensions, such a model would be one of "nothing." The author talks about how scientists have discovered one and two dimensions, self-contained mathematical models that also do not represent our world. One way or the other, our world is, at best, one mathematical model with many others left out. This might be LQG (assuming it is not a specific case of anything else, as the author believes) or a string theory with arbitrary parameters/selections thrown in. It will be impossible to prove - a conjecture - that there is only one mathematical set of equations that can result in a universe/world, while no other set will be fully complete or manifestable.
A lot of words there. In conclusion, the book is worth reading as it provides a lot of new material to think about. But, this one is not for anyone picking up a popular book to understand the basics or anyone who does not like wild, almost mystical conjectures, however smart.
July 31, 2016
Writing about complex topics, not to mention quantum theoretical physics, is tremendously challenging. Distilling dense, abstruse, and highly mathematized information down to the comprehension level of the average reader is a feat in itself. This is why good popular science- writing that can be accessed and enjoyed by that layperson- is scarce. Far too many academics fall prey to the so-called “curse of knowledge,” or the inability of the expert to condense and summarize information to novices. Perhaps they fail to understand the material well enough- if they can’t explain it simply, can they even explain it at all? As Einstein once stated, “if you can’t explain it simply, you don’t understand it well enough.”
Lee Smolin, a theoretical physicist at the Perimeter Institute, wrote Three Roads to Quantum Gravity several years back to bring to the public eye recent developments in theoretical physics. Discovering quantum gravity has been an especially troubling problem for physicists; reconciling gravity with quantum mechanics is the largest obstacle to completing the Standard Model. Smolin, writing in 2000, argues that there are realizable solutions to this quantum mystery. He finds three “roads” to reconciliation. The intent of this work is to demonstrate them to the average intelligent reader.
The first road is loop quantum gravity (LQG). It conceives of a complex configuration of quantized loops, captured through the mind-numbing formulations of the so-called spin network. A spin network is formed when loops are combined, producing a shape. Smolin played a large role in fleshing out LQG; in fact, several pages recount his formulation of the theory, along with his fellow colleagues.
The second road is the more commonly known string theory. This theory, while sharing some similarities with its LQG counterpart, is premised on a different theoretical structure. In order for this conception to work, space-time must be absolute rather than relative. In other words, it assumes a fixed background for the equations to work. Smolin disagrees with this notion- his first chapters are devoted to undermining this absolutist view of the universe. Smolin argues that the universe is entirely relational. This means nothing exists outside of it, no backdrop on which to impose order. Space cannot be defined without considering its contents. He likens the geometry of the universe to that of a sentence, writing that, as “a sentence has no structure and no existence apart from the relationships between the words, space has no existence apart from the relationships that old between the things in the universe.” This is called “background independence.”
The final road Smolin describes, albeit briefly, is the one of the renegade. The followers of this path reject the assumptions of the first two; they find themselves rejecting the entire mathematical edifice, while laboring over the larger philosophical questions of ‘What is time?’ or ‘Why do we exist?.” Smolin says that few travel this path; it is much easier to work with established theories and models rather than reject them wholesale.
Smolin vigorously treks the first path. At times, he goes out of his way to criticize the members of the string theory field for dwelling on incorrect assumptions. Yet he argues that more collaboration is needed. The way he describes the formative years of each field, from the mid-80s to the mid-90s, suggests an almost tribal mentality among members of each group. “Each group was successful in solving problems it set for itself,” he writes. Each side played lip service to the other. What they were not doing was collaborating. “During this whole period, for example, there was not a single person who worked on both theories. Many seemed to make the understandable mistake of confusing the solution of part of the problem of quantum gravity with the solution of the whole problem.”
Despite his critical remarks about the closed mentalities of both fields, Smolin is by nature an optimist. He believes we are on the cusp of figuring out how to reconcile gravity with quantum reality. By the end of this century, he predicts a unified theory will be a fixture in high school physics classes.
Generally, Three Roads to Quantum Gravity straddles the line between polished academic writing and engaging popular science written for the lay individual. In the end, it accomplishes neither. What results is an eclectic assembly of thoughts, theories, and personal history, interlaced with not-so-descriptive models and overly simplified analogies. There is no unified theme in the book: an introduction to the “three roads” is described in the preface, and he only goes on to write about the first two. I had to go back and find where he mentions the third path.
The writing is mostly dry- it is plain boring academic writing severely lacking in humor or vivid imagery. Smolin is no Brian Greene. Greene’s use of elaborate analogies and colorful imagery makes him one of the most respected writers in the field of popular physics. Smolin, on the other hand, struggles to come up with engaging explanations and analogies. For example, he describes quantum superposition with a cat eating either a tasty or a “yukky" - yes he uses that spelling- mouse. In his discussion on the holographic principle, he describes the interaction between a “Thing” and a “Screen.” Judging by these sorry examples, Smolin could learn a thing or two from Greene’s writing style.
This book also reads like an assemblage of notes, packed into three semi-cohesive sections. He lingers on black holes and thermodynamics in a few chapters, skips to quantum field dynamics in another, and then goes off the rails when discussing the holographic principle. He notes that the book was writer for “any interested reader,” yet takes the liberty to include mathematical equations and excessively complex models in the chapters. In the end, the final product is a hodgepodge of his own personal research, long-winded plugs for his beloved LQG and general but not too immersive discussions of topics on the cutting edge of the theoretical physicist’s equation sheet. In the end, where there should have been a meticulously-tied arc of consistency and coherence throughout the book, is instead a poorly knotted bow with several loose ends.
Smolin does an average job of connecting with the reader. His writing is generally insipid, and contains a few too many complicated models and aggressively simplified analogies. At times he tries to hard to engage the reader, and other times his work is lifted off into abstraction and arcane digression. In other words, he falls prey to the curse of knowledge. On the whole, I am glad to say that I can understand some of the more recent developments in the quest to complete the Standard Model. Smolin’s optimistic temperament provides some hope that it will be accomplished soon.
Lee Smolin, a theoretical physicist at the Perimeter Institute, wrote Three Roads to Quantum Gravity several years back to bring to the public eye recent developments in theoretical physics. Discovering quantum gravity has been an especially troubling problem for physicists; reconciling gravity with quantum mechanics is the largest obstacle to completing the Standard Model. Smolin, writing in 2000, argues that there are realizable solutions to this quantum mystery. He finds three “roads” to reconciliation. The intent of this work is to demonstrate them to the average intelligent reader.
The first road is loop quantum gravity (LQG). It conceives of a complex configuration of quantized loops, captured through the mind-numbing formulations of the so-called spin network. A spin network is formed when loops are combined, producing a shape. Smolin played a large role in fleshing out LQG; in fact, several pages recount his formulation of the theory, along with his fellow colleagues.
The second road is the more commonly known string theory. This theory, while sharing some similarities with its LQG counterpart, is premised on a different theoretical structure. In order for this conception to work, space-time must be absolute rather than relative. In other words, it assumes a fixed background for the equations to work. Smolin disagrees with this notion- his first chapters are devoted to undermining this absolutist view of the universe. Smolin argues that the universe is entirely relational. This means nothing exists outside of it, no backdrop on which to impose order. Space cannot be defined without considering its contents. He likens the geometry of the universe to that of a sentence, writing that, as “a sentence has no structure and no existence apart from the relationships between the words, space has no existence apart from the relationships that old between the things in the universe.” This is called “background independence.”
The final road Smolin describes, albeit briefly, is the one of the renegade. The followers of this path reject the assumptions of the first two; they find themselves rejecting the entire mathematical edifice, while laboring over the larger philosophical questions of ‘What is time?’ or ‘Why do we exist?.” Smolin says that few travel this path; it is much easier to work with established theories and models rather than reject them wholesale.
Smolin vigorously treks the first path. At times, he goes out of his way to criticize the members of the string theory field for dwelling on incorrect assumptions. Yet he argues that more collaboration is needed. The way he describes the formative years of each field, from the mid-80s to the mid-90s, suggests an almost tribal mentality among members of each group. “Each group was successful in solving problems it set for itself,” he writes. Each side played lip service to the other. What they were not doing was collaborating. “During this whole period, for example, there was not a single person who worked on both theories. Many seemed to make the understandable mistake of confusing the solution of part of the problem of quantum gravity with the solution of the whole problem.”
Despite his critical remarks about the closed mentalities of both fields, Smolin is by nature an optimist. He believes we are on the cusp of figuring out how to reconcile gravity with quantum reality. By the end of this century, he predicts a unified theory will be a fixture in high school physics classes.
Generally, Three Roads to Quantum Gravity straddles the line between polished academic writing and engaging popular science written for the lay individual. In the end, it accomplishes neither. What results is an eclectic assembly of thoughts, theories, and personal history, interlaced with not-so-descriptive models and overly simplified analogies. There is no unified theme in the book: an introduction to the “three roads” is described in the preface, and he only goes on to write about the first two. I had to go back and find where he mentions the third path.
The writing is mostly dry- it is plain boring academic writing severely lacking in humor or vivid imagery. Smolin is no Brian Greene. Greene’s use of elaborate analogies and colorful imagery makes him one of the most respected writers in the field of popular physics. Smolin, on the other hand, struggles to come up with engaging explanations and analogies. For example, he describes quantum superposition with a cat eating either a tasty or a “yukky" - yes he uses that spelling- mouse. In his discussion on the holographic principle, he describes the interaction between a “Thing” and a “Screen.” Judging by these sorry examples, Smolin could learn a thing or two from Greene’s writing style.
This book also reads like an assemblage of notes, packed into three semi-cohesive sections. He lingers on black holes and thermodynamics in a few chapters, skips to quantum field dynamics in another, and then goes off the rails when discussing the holographic principle. He notes that the book was writer for “any interested reader,” yet takes the liberty to include mathematical equations and excessively complex models in the chapters. In the end, the final product is a hodgepodge of his own personal research, long-winded plugs for his beloved LQG and general but not too immersive discussions of topics on the cutting edge of the theoretical physicist’s equation sheet. In the end, where there should have been a meticulously-tied arc of consistency and coherence throughout the book, is instead a poorly knotted bow with several loose ends.
Smolin does an average job of connecting with the reader. His writing is generally insipid, and contains a few too many complicated models and aggressively simplified analogies. At times he tries to hard to engage the reader, and other times his work is lifted off into abstraction and arcane digression. In other words, he falls prey to the curse of knowledge. On the whole, I am glad to say that I can understand some of the more recent developments in the quest to complete the Standard Model. Smolin’s optimistic temperament provides some hope that it will be accomplished soon.
Want to read
December 19, 2024Here’s a simple bullet-point summary of *Three Roads to Quantum Gravity* by Lee Smolin:
- **Focus**:
- Explores the quest to unify quantum mechanics and general relativity into a single theory of quantum gravity.
- **Key Ideas**:
- **Three Approaches to Quantum Gravity**:
1. **String Theory**: Proposes that fundamental particles are one-dimensional "strings" vibrating at different frequencies.
2. **Loop Quantum Gravity**: Focuses on quantizing spacetime itself, suggesting that space is made up of discrete loops or networks.
3. **Black Hole Thermodynamics**: Examines the relationship between gravity, quantum mechanics, and thermodynamics, particularly through black holes.
- These three approaches may ultimately converge into a unified framework for understanding quantum gravity.
- **Themes**:
- The nature of space and time: Suggests that spacetime is not continuous but discrete at the smallest scales.
- The limits of current physics: Highlights the need to go beyond Einstein’s general relativity and quantum mechanics.
- The philosophical implications of quantum gravity: Raises questions about the nature of reality and our ability to understand it.
- **Style**:
- Written for a general audience, with clear explanations of complex ideas.
- Blends scientific theory with philosophical reflections.
- **Overall**:
- A thought-provoking exploration of cutting-edge physics, offering insights into the ongoing search for a theory that unifies the fundamental forces of nature.
- **Focus**:
- Explores the quest to unify quantum mechanics and general relativity into a single theory of quantum gravity.
- **Key Ideas**:
- **Three Approaches to Quantum Gravity**:
1. **String Theory**: Proposes that fundamental particles are one-dimensional "strings" vibrating at different frequencies.
2. **Loop Quantum Gravity**: Focuses on quantizing spacetime itself, suggesting that space is made up of discrete loops or networks.
3. **Black Hole Thermodynamics**: Examines the relationship between gravity, quantum mechanics, and thermodynamics, particularly through black holes.
- These three approaches may ultimately converge into a unified framework for understanding quantum gravity.
- **Themes**:
- The nature of space and time: Suggests that spacetime is not continuous but discrete at the smallest scales.
- The limits of current physics: Highlights the need to go beyond Einstein’s general relativity and quantum mechanics.
- The philosophical implications of quantum gravity: Raises questions about the nature of reality and our ability to understand it.
- **Style**:
- Written for a general audience, with clear explanations of complex ideas.
- Blends scientific theory with philosophical reflections.
- **Overall**:
- A thought-provoking exploration of cutting-edge physics, offering insights into the ongoing search for a theory that unifies the fundamental forces of nature.
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