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Superstring Theory: The DNA of Reality

Superstring Theory: The DNA of Reality

Professor S. James Gates Jr., Ph.D.
University of Maryland, College Park

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Superstring Theory: The DNA of Reality

Course No. 1284
Professor S. James Gates Jr., Ph.D.
University of Maryland, College Park
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3.4 out of 5
116 Reviews
51% of reviewers would recommend this series
Course No. 1284
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Course Overview

One of the most exciting scientific adventures of all time is the search for the ultimate nature of physical reality, a hunt that in the past century has yielded such breakthroughs as Einstein's theory of relativity and quantum mechanics, two theories that radically altered our picture of space, time, gravity, and the fundamental building blocks of matter.

The latest advance in this epic quest is string theory—known as superstring or M-theory in its most recent versions. The "M" of M-theory is an arbitrary label, but some physicists believe it stands for mysterious or magical. Marvelous also qualifies, because there is something quite wonderful about this beautiful and startling idea.

Based on the concept that all matter is composed of inconceivably tiny filaments of vibrating energy, string theory has potentially staggering implications for our understanding of the universe.

Wouldn't you love to understand string theory at a deeper level than is available from popular articles or even book-length treatments? Aren't you eager to look over the shoulder of a prominent string theorist at work—one who has a gift for explaining the subject to nonscientists and who has created computer-generated images to help make the concepts clear?

A Challenging Course in a Fascinating Field

The Teaching Company offers just such a guide in Professor S. James Gates Jr., director of the Center for String and Particle Theory at the University of Maryland. Professor Gates is an old hand in this very young field. In 1977 he wrote the Massachusetts Institute of Technology's first-ever doctoral dissertation on supersymmetry, the precursor to string theory.

In the midst of teaching, pursuing research, and writing scores of scientific papers over the past two decades, Dr. Gates has also presented nearly 100 public talks on string theory, honing a set of visual aids designed to convey the difficult mathematical ideas that underlie this subject to a lay audience.

The 24 lectures in Superstring Theory: The DNA of Reality incorporate Dr. Gates's field testing of this matchless set of graphics, which are the most technically lavish that The Teaching Company has ever presented. Prepare to be intrigued, enlightened, and amazed.

Because the goal of string theory is to unite relativity and quantum mechanics in a comprehensive "theory of everything," this course nicely complements two other Teaching Company courses: Professor Richard Wolfson's Einstein's Relativity and the Quantum Revolution: Modern Physics for Non-Scientists, 2nd Edition, and Professor Steven Pollack's Particle Physics for Non-Physicists: A Tour of the Microcosmos.

Combined with Superstring Theory: The DNA of Reality, this trio of Teaching Company courses traces the development of physics in the 20th century—from well-tested theories such as relativity and quantum mechanics, to the more abstract research of late 20th-century particle physics, to the strange world of string theory, which is still in an intense state of flux.

Spaghetti Strands

The essence of string theory is that the smallest, most fundamental objects in the universe are not little balls knocking around like billiards, as had been thought for about 2,000 years. Instead, these small objects are supermicroscopic filaments—like tiny strands of spaghetti—whose different vibrational modes produce the multitude of particles that are observed in the laboratory.

So when a string vibrates in one way, it might appear to be an electron. If it vibrates in a different manner, it would look like a quark. It could vibrate in a third way and display the properties of a photon. Or perhaps it vibrates in a fourth mode and physicists say, "That's a graviton!" This gives strings an inherent ability to unify phenomena that had always been assumed to be different. If string theory ultimately proves correct, then strings are truly the DNA of reality.

One of the most celebrated features of the string approach is that it predicts more dimensions than the three of our familiar spatial world plus one of time. Currently, the most comprehensive version of string theory—M-theory—calls for a total of 11 dimensions. These extra dimensions could be hidden away, compacted into exotic shapes like the "Calabi-Yau manifold," or they could be forever out of reach in high-dimensional membranelike objects called branes.

But some physicists—Dr. Gates among them—see strings as entirely consistent with the four-dimensional world as we experience it. He explains this intriguing interpretation in Lecture 16.

Explore Ideas through Images

Each lecture draws on the illustrative power of computer-generated imagery (CGI). For years Dr. Gates has been asked to write a nontechnical book on string theory, but he has always declined, convinced that words alone cannot convey to the public the mathematical ideas that provide the foundation of this field. But these video lectures can. "The format of courses followed by The Teaching Company provides an exquisite platform for the utilization of CGI technology to augment conventional static lectures and books," he says.

Here are some of the mathematical ideas that you will explore through images in this course:

  • Dark matter: Two animations of galaxies in the process of forming show that something is wrong with the scene that is based on the observable mass of an average galaxy: There is not enough matter for it to hold its shape. On the other hand, the galaxy with added "dark" matter does just fine. String theory accounts for the existence of this dark matter.
  • What would happen if the sun disappeared? If the sun suddenly vanished, Earth would have 8 minutes before going dark, since it takes that long for the sun's light to reach us. But what about the sun's gravity? Would there be a similar delay, or would Earth go flying out of its orbit immediately? The answer to this question inspired one of the major theoretical goals of string theory.
  • Designer atoms: The configuration of subatomic particles in an atom is specified by a set of equations. These can be visualized, showing that if you alter the equations to change one type of particle into another, the atom collapses, rendering all life impossible.
  • Sizzling black holes: Physicist Stephen Hawking proposed that black holes do more than just bend light around them; they also give off a "sizzle" of static. Even though a black hole is itself invisible, these effects can be detected and visualized with computer graphics. Hawking's brilliant insight eventually led others to develop the first string theory.
  • Einstein's hypotenuse: Many of the ideas developed by Einstein, including E = mc², can be understood by analyzing a geometric figure called Einstein's hypotenuse. Use of this concept in early versions of string theory led to a bizarre particle called the tachyon.

This course is an immensely rich experience, filled with unexpected delights and mysterious encounters. You will often feel like a tourist in an exotic country, where the sights, sounds, aromas, and incidents are at times baffling but always invigorating and educational, leaving you with a desire to understand this complex world better.

If you've ever wanted to know what string theory is all about; or what theoretical physicists discuss over dinner; or how mathematical ideas guide our exploration of inconceivably tiny realms; or if you've ever wanted a glimpse of cutting-edge ideas about the fundamental structure of reality—then, by all means, we invite you to let Professor Gates be your guide into the amazing world of strings.

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24 lectures
 |  30 minutes each
  • 1
    The Macro/Micro/Mathematical Connection
    Professor Gates opens with a survey of the goals of the series and introduces the concept of strings, which are incredibly tiny objects that may be the most fundamental objects in the universe. String theory is not yet experimental physics; it is theoretical physics, based on sophisticated mathematical ideas. x
  • 2
    Who Is Afraid of Music?
    Mathematics will play an important role in this course because string theory is purely mathematical. But instead of studying equations, you will explore the mathematics of strings through computer images and animations. These are comparable to the music generated by notes on a musical score. x
  • 3
    Apropos Einstein's Perfect Brainstorm Year
    This lecture explores Einstein's general theory of relativity, which led to a new understanding of gravity and sparked Einstein's quest for a "theory of everything." Building a mathematical theory of everything is like confronting a complicated toy on Christmas Eve, whose box states, "some assembly required." x
  • 4
    Honey, I Shrunk to the Quantum World—Part I
    In the first of two lectures on the quantum world, you start at the level of the atom and dig deeper, discovering the following: leptons (electronlike objects); nuclear matter (protons, neutrons); quarks (subnuclear matter); and force carriers (photons, gluons, W and Z bosons, and gravitons). x
  • 5
    Honey, I Shrunk to the Quantum World—Part II
    You investigate more properties of the quantum world, including spin, the Pauli exclusion principle, quantization, vacuum polarization, and quantum tunneling. You are also introduced to the Higgs boson, sometimes called the "God particle" for its apparent role in imparting mass to other particles. x
  • 6
    Dr. Hawking's Dilemma
    Any object that possesses a temperature above absolute zero must give off thermal radiation. But how is this possible with a black hole, which is so massive that not even light can escape from it? In 1975, Stephen Hawking forced a crisis in theoretical physics with a stunning theory addressing this problem. x
  • 7
    I'd Like to See a Cosmos Sing in Perfect Harmony
    In trying to explain black holes in a way consistent with Hawking's 1975 theory, scientists had to combine two pillars of physics—quantum theory and the general theory relativity. The resulting mathematics predicted a surprising form of matter: strings. x
  • 8
    Einstein's Hypotenuse and Strings—Part I
    String theory may involve extra dimensions beyond the familiar three of space plus one of time. But how are physicists able to think about extra dimensions? The Pythagorean theorem provides a model, showing that it's possible to calculate the properties of objects in higher dimensions without having to visualize them. x
  • 9
    Einstein's Hypotenuse and Strings—Part II
    Einstein incorporated the fourth dimension of time into the Pythagorean theorem and came up with an idea known as the Einstein hypotenuse. This led to the famous equation E = mc2, which can be interpreted as a statement about areas in a four-dimensional world. You see how Einstein's hypotenuse led to an object that could have destroyed the world of physics: the tachyon. x
  • 10
    Tying Up the Tachyon Monster with Spinning Strings
    This lecture explores the phenomenon of spin, which is ubiquitous in the quantum world. Spin was well known to particle physicists in the 1970s, but it presented problems for the first generation of string theory. A new generation of spinning strings solved the problem and also dealt with the tachyon threat. x
  • 11
    The Invasion of the Anti-Commuting Numbers
    Starting with the frustum (a truncated pyramid) on the back of a dollar bill, you explore some intriguing properties of numbers, including anti-commuting Grassman numbers. Anticommutivity is useful in quantum mechanics and manages to banish the tachyon from certain versions of string theory. x
  • 12
    It's a Bird—A Plane—No, It's Superstring!
    In 1977 three physicists—Gliozzi, Sherk, and Olive—observed that it is supersymmetry (the equality of bosons and fermions) that kills the tachyon monster. Supersymmetry is the child of string theory and the parent of superstrings. But why are there five versions of superstrings. x
  • 13
    Gauge Theory—A Brief Return to the Real World
    While working on supersymmetry around 1982, physicists Schwarz and Green found a solution that required 496 charges, implying a world in which there are 32 possible ways to rotate. The resulting string was called the SO(32) superstring, and was the world's first unified field theory, achieving a dream of Einstein. x
  • 14
    Princeton String Quartet Concerti—Part I
    Circular polarization of light possesses a mathematical property useful in superstring theory. Standing waves, left-moving waves, and right-moving waves are introduced in this lecture. Recognition that all three exist in superstring theory led to a new "heterotic" string constructed by a group of four physicists at Princeton in 1984. x
  • 15
    Princeton String Quartet Concerti—Part II
    The initial work of the "Princeton String Quartet" led to two strings from different dimensions: a left-moving superstring and the old bosonic right-moving string. But this work did not incorporate the requisite 496 charges. This lecture explores a new description of the heterotic string that produces that magic number. x
  • 16
    Extra Dimensions—Ether-like or Quark-like?
    It is often said that string theory requires extra dimensions, but that's not quite true. The mathematics of the heterotic string can be interpreted with extra dimensions or without. What appear to be extra dimensions can be understood as angular variables associated with the change of force-carrying particles. x
  • 17
    The Fundamental Forces Strung Out
    This lecture shows how superstring theory provides mathematical support for Hawking's theory of black-hole radiation, which was discussed earlier in the course. Observational proof of string theory may come not by looking at nature's smallest structures but by looking at its largest: the universe itself. x
  • 18
    Do-See-Do and Swing Your Superpartner—Part I
    Why does the universe observe a dichotomy, in which beams of matter obey the Pauli exclusion principle but beams of energy do not? The universe may be more symmetrical than this model suggests. Here, you look at evidence for supersymmetry that points to the existence of superpartners for ordinary matter. x
  • 19
    Do-See-Do and Swing Your Superpartner—Part II
    Supersymmetry implies that every known matter particle has a superpartner that has yet to be observed in the laboratory. In fact, it is much more likely that superpartners will be discovered indirectly than in the lab. This lecture covers a technique for detecting them. x
  • 20
    A Superpartner for Dr. Einstein's Graviton
    Can physicists find a consistent way to introduce mass to the superpartners so that they become very heavy while ordinary matter remains very light? The Higgs mechanism is one such method and may offer an explanation for the mysterious dark matter that is key to the formation of galaxies. x
  • 21
    Can 4D Forces (without Gravity) Love Strings?
    This lecture follows current attempts to use concepts from string theory to understand the forces and structures of matter inside the proton and neutron. You also visit the strange world of branes, and explore the type IIB string, which is one of five types of superstrings. x
  • 22
    If You Knew SUSY
    If you were to pick up a physics journal from the last 20 years, you would likely come across the word SUSY, which means supersymmetric. In this lecture, you study an unusual aspect of SUSY, superspace, and learn how it accounts for the five types of superstrings. x
  • 23
    Can I Have that Extra Dimension in the Window?
    Strings supposedly describe everything. But if that's true, how can there be five different "everythings"? This lecture investigates a possible solution in 11-dimensional supergravity, which may be part of a larger and even more mysterious construct, M-theory. x
  • 24
    Is String Theory the Theory of Our Universe?
    String theory weaves together an amazing story with contributions by several generations of mathematicians and physicists. Professor Gates closes with a review of the current state of the field, and he looks at some denizens of the world of supersymmetry that he and his colleagues have recently identified. x

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DVD Includes:
  • 24 lectures on 4 DVDs
  • 192-page printed course guidebook

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  • 192-page printed course guidebook
  • Suggested readings
  • Questions to consider
  • Timeline

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Your professor

S. James Gates Jr.

About Your Professor

S. James Gates Jr., Ph.D.
University of Maryland, College Park
Dr. S. James Gates Jr. is the John S. Toll Professor of Physics and Director of the Center for String and Particle Theory at the University of Maryland at College Park. He earned two B.S. degrees in mathematics and physics and earned his Ph.D. in the studies of elementary particle physics and quantum field theory at the Massachusetts Institute of Technology. Dr. Gates's first post was a Junior Fellow in the Harvard Society of...
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Superstring Theory: The DNA of Reality is rated 3.3 out of 5 by 116.
Rated 5 out of 5 by from Daunting Subject Made Understandable Doctor Gates made the very complex subject of the String Theory of Physics understandable to a non-scientific mind - mine! His generous use of graphics and genial teaching style are very effective teaching tools.
Date published: 2017-10-12
Rated 4 out of 5 by from Great lecture and great teacher. In this series, I have only watched 4 lectures so far. I've gathered that what I've watched so far is just foundational information one needs to know before really getting into the super string theory part. What I have seen so far has been very enlightening; however, one has to really concentrate and try to remember their geometry and higher math they learned in school which they've pretty much forgotten I consider myself pretty knowledgeable, but some of it was over my head. Nevertheless, I'm still enjoying it.
Date published: 2017-10-04
Rated 5 out of 5 by from Superbly taught I am no mathematician and have only a cursory knowledge of particle physics, but I found Prof. Gates' course very engaging. He explained quantum mechanics and string theory using some superb video and very little maths (sigh of relief!). I was expecting to view the first few lectures and then concede defeat, but I found myself binge-watching all 24 lectures over five days. Magnificent!
Date published: 2017-07-13
Rated 5 out of 5 by from A Compelling Presentation on a Complex Subject Dr. Gates has really done the impossible here; namely, explaining superstring theory, along with the underlying, fundamentals of quantum physics, without any math. What makes this so spectacular is that superstring theory is really all about the math, the same way in which music theory is all about the notes. Imagine trying to explain the inner workings of a Bach fugue and its ornate counterpoint without being able to show any of the notes, or giving a lecture on linguistics without being able to show any ancient words. Ancient Egyptian hieroglyphics without any pictures of them? Forget it! And yet, Dr. Gates did it. No math! Instead, he took all of the knotty math equations and rendered them into computer graphics--brilliant!--making the observation that, by allowing the computer to act as a "math translator" for us, perhaps someday even a math genius, without any training in numbers, would be able to use a computer to communicate the ideas behind the underlying equations. Although the lecture dates back to 2006, the material is still solid, overall. The graphics, while not as beautiful as we might render today, are also amazingly illustrative and well done. I'm torn about all of it. Having studied lots of physics and math in engineering school. I often learned the material only from the math side--one endless round of derived equations after another--and so, to be able to see the equations rendered into graphical form so beautifully was oftentimes eye opening and insightful. On the other hand, without the math, some portions of the lectures didn't quite make as much sense, and other portions would have tied together much better had they been supported by the equations and at least how some of them are derived. Dr. Gates was well aware of this and repeatedly referenced the fact that this material was "all about the math," and yet, in essence, he wasn't able to show any of it. I understand the producers' concern that a lay audience might be afraid of or bored by math and equations way over their heads. On the other hand, there are plenty of people watching, such as myself, who do have a math background and would appreciate seeing it to really bring everything together. It certainly wouldn't hurt to at least provide more screenshots of the formulas and walk through some of them. Those without the background could simply skip ahead if they didn't have the patience to watch. In any case, Dr. Gates has a pleasant personality, a nice speaking voice, and does the best job anyone could do under the circumstances. He also did a fantastic job of providing the background needed to understand the central ideas. I really enjoyed this course, and it motivated me to take the next step of supplementing it with--you guessed it--the actual math.
Date published: 2017-06-11
Rated 4 out of 5 by from Complex topic made simple Dr. Gates makes a great attempt at simplifying this exceptionally complex topic, without relying heavily on mathematical constructs. This is particularly challenging given the fact the basic premise of the topic lies solely within the realm of mathematics currently.
Date published: 2017-06-01
Rated 5 out of 5 by from A clear description of string theory. I am still working on it. I have read Greene's book. These lectures make a difficult subject and the relationships much clearer.
Date published: 2017-05-07
Date published: 2017-02-13
Rated 4 out of 5 by from A picture is worth a thousand words This course includes many visuals that greatly enhance the lecture and promote easier understanding.
Date published: 2017-01-16
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