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M-theory

January 01, 1970

For a more accessible and less technical introduction to this topic, see Introduction to M-theory.

M-theory is a theory in physics that unifies all consistent versions of superstring theory. Edward Witten first conjectured the existence of such a theory at a string theory conference at the University of Southern California in 1995. Witten's announcement initiated a flurry of research activity known as the second superstring revolution. Prior to Witten's announcement, string theorists had identified five versions of superstring theory. Although these theories initially appeared to be very different, work by many physicists showed that the theories were related in intricate and nontrivial ways. Physicists found that apparently distinct theories could be unified by mathematical transformations called S-duality and T-duality. Witten's conjecture was based in part on the existence of these dualities and in part on the relationship of the string theories to a field theory called eleven-dimensional supergravity.

Although a complete formulation of M-theory is not known, such a formulation should describe two- and five-dimensional objects called branes and should be approximated by eleven-dimensional supergravity at low energies. Modern attempts to formulate M-theory are typically based on matrix theory or the AdS/CFT correspondence. According to Witten, M should stand for "magic", "mystery" or "membrane" according to taste, and the true meaning of the title should be decided when a more fundamental formulation of the theory is known.[1]

Investigations of the mathematical structure of M-theory have spawned important theoretical results in physics and mathematics. More speculatively, M-theory may provide a framework for developing a unified theory of all of the fundamental forces of nature. Attempts to connect M-theory to experiment typically focus on compactifying its extra dimensions to construct candidate models of the four-dimensional world, although so far none has been verified to give rise to physics as observed in high-energy physics experiments.

Background edit

Quantum gravity and strings edit

Main articles: Quantum gravity and String theory
 
The fundamental objects of string theory are open and closed strings.

One of the deepest problems in modern physics is the problem of quantum gravity. The current understanding of gravity is based on Albert Einstein's general theory of relativity, which is formulated within the framework of classical physics. However, nongravitational forces are described within the framework of quantum mechanics, a radically different formalism for describing physical phenomena based on probability.[a] A quantum theory of gravity is needed in order to reconcile general relativity with the principles of quantum mechanics,[b] but difficulties arise when one attempts to apply the usual prescriptions of quantum theory to the force of gravity.[c]

String theory is a theoretical framework that attempts to reconcile gravity and quantum mechanics. In string theory, the point-like particles of particle physics are replaced by one-dimensional objects called strings. String theory describes how strings propagate through space and interact with each other. In a given version of string theory, there is only one kind of string, which may look like a small loop or segment of ordinary string, and it can vibrate in different ways. On distance scales larger than the string scale, a string will look just like an ordinary particle, with its mass, charge, and other properties determined by the vibrational state of the string. In this way, all of the different elementary particles may be viewed as vibrating strings. One of the vibrational states of a string gives rise to the graviton, a quantum mechanical particle that carries gravitational force.[d]

There are several versions of string theory: type I, type IIA, type IIB, and two flavors of heterotic string theory (SO(32) and E8×E8). The different theories allow different types of strings, and the particles that arise at low energies exhibit different symmetries. For example, the type I theory includes both open strings (which are segments with endpoints) and closed strings (which form closed loops), while types IIA and IIB include only closed strings.[2] Each of these five string theories arises as a special limiting case of M-theory. This theory, like its string theory predecessors, is an example of a quantum theory of gravity. It describes a force just like the familiar gravitational force subject to the rules of quantum mechanics.[3]

Number of dimensions edit

Main articles: Extra dimensions and Compactification (physics)
 
An example of compactification: At large distances, a two-dimensional surface with one circular dimension looks one-dimensional.

In everyday life, there are three familiar dimensions of space: height, width and depth. Einstein's general theory of relativity treats time as a dimension on par with the three spatial dimensions; in general relativity, space and time are not modeled as separate entities but are instead unified to a four-dimensional spacetime, three spatial dimensions and one time dimension. In this framework, the phenomenon of gravity is viewed as a consequence of the geometry of spacetime.[4]

In spite of the fact that the universe is well described by four-dimensional spacetime, there are several reasons why physicists consider theories in other dimensions. In some cases, by modeling spacetime in a different number of dimensions, a theory becomes more mathematically tractable, and one can perform calculations and gain general insights more easily.[e] There are also situations where theories in two or three spacetime dimensions are useful for describing phenomena in condensed matter physics.[5] Finally, there exist scenarios in which there could actually be more than four dimensions of spacetime which have nonetheless managed to escape detection.[6]

One notable feature of string theory and M-theory is that these theories require extra dimensions of spacetime for their mathematical consistency. In string theory, spacetime is ten-dimensional (nine spatial dimensions, and one time dimension), while in M-theory it is eleven-dimensional (ten spatial dimensions, and one time dimension). In order to describe real physical phenomena using these theories, one must therefore imagine scenarios in which these extra dimensions would not be observed in experiments.[7]

Compactification is one way of modifying the number of dimensions in a physical theory.[f] In compactification, some of the extra dimensions are assumed to "close up" on themselves to form circles.[8] In the limit where these curled-up dimensions become very small, one obtains a theory in which spacetime has effectively a lower number of dimensions. A standard analogy for this is to consider a multidimensional object such as a garden hose. If the hose is viewed from a sufficient distance, it appears to have only one dimension, its length. However, as one approaches the hose, one discovers that it contains a second dimension, its circumference. Thus, an ant crawling on the surface of the hose would move in two dimensions.[g]

Dualities edit

Main articles: String duality, S-duality, and T-duality
 
A diagram of string theory dualities. Yellow arrows indicate S-duality. Blue arrows indicate T-duality. These dualities may be combined to obtain equivalences of any of the five theories with M-theory.[9]

Theories that arise as different limits of M-theory turn out to be related in highly nontrivial ways. One of the relationships that can exist between these different physical theories is called S-duality. This is a relationship which says that a collection of strongly interacting particles in one theory can, in some cases, be viewed as a collection of weakly interacting particles in a completely different theory. Roughly speaking, a collection of particles is said to be strongly interacting if they combine and decay often and weakly interacting if they do so infrequently. Type I string theory turns out to be equivalent by S-duality to the SO(32) heterotic string theory. Similarly, type IIB string theory is related to itself in a nontrivial way by S-duality.[10]

Another relationship between different string theories is T-duality. Here one considers strings propagating around a circular extra dimension. T-duality states that a string propagating around a circle of radius R is equivalent to a string propagating around a circle of radius 1/R in the sense that all observable quantities in one description are identified with quantities in the dual description. For example, a string has momentum as it propagates around a circle, and it can also wind around the circle one or more times. The number of times the string winds around a circle is called the winding number. If a string has momentum p and winding number n in one description, it will have momentum n and winding number p in the dual description. For example, type IIA string theory is equivalent to type IIB string theory via T-duality, and the two versions of heterotic string theory are also related by T-duality.[10]

In general, the term duality refers to a situation where two seemingly different physical systems turn out to be equivalent in a nontrivial way. If two theories are related by a duality, it means that one theory can be transformed in some way so that it ends up looking just like the other theory. The two theories are then said to be dual to one another under the transformation. Put differently, the two theories are mathematically different descriptions of the same phenomena.[11]

Supersymmetry edit

Main article: Supersymmetry

Another important theoretical idea that plays a role in M-theory is supersymmetry. This is a mathematical relation that exists in certain physical theories between a class of particles called bosons and a class of particles called fermions. Roughly speaking, fermions are the constituents of matter, while bosons mediate interactions between particles. In theories with supersymmetry, each boson has a counterpart which is a fermion, and vice versa. When supersymmetry is imposed as a local symmetry, one automatically obtains a quantum mechanical theory that includes gravity. Such a theory is called a supergravity theory.[12]

A theory of strings that incorporates the idea of supersymmetry is called a superstring theory. There are several different versions of superstring theory which are all subsumed within the M-theory framework. At low energies, the superstring theories are approximated by supergravity in ten spacetime dimensions. Similarly, M-theory is approximated at low energies by supergravity in eleven dimensions.[3]

Branes edit

Main article: Brane

In string theory and related theories such as supergravity theories, a brane is a physical object that generalizes the notion of a point particle to higher dimensions. For example, a point particle can be viewed as a brane of dimension zero, while a string can be viewed as a brane of dimension one. It is also possible to consider higher-dimensional branes. In dimension p, these are called p-branes. Branes are dynamical objects which can propagate through spacetime according to the rules of quantum mechanics. They can have mass and other attributes such as charge. A p-brane sweeps out a (p + 1)-dimensional volume in spacetime called its worldvolume. Physicists often study fields analogous to the electromagnetic field which live on the worldvolume of a brane. The word brane comes from the word "membrane" which refers to a two-dimensional brane.[13]

In string theory, the fundamental objects that give rise to elementary particles are the one-dimensional strings. Although the physical phenomena described by M-theory are still poorly understood, physicists know that the theory describes two- and five-dimensional branes. Much of the current research in M-theory attempts to better understand the properties of these branes.[h]

History and development edit

Main article: History of string theory

Kaluza–Klein theory edit

Main article: Kaluza–Klein theory

In the early 20th century, physicists and mathematicians including Albert Einstein and Hermann Minkowski pioneered the use of four-dimensional geometry for describing the physical world.[14] These efforts culminated in the formulation of Einstein's general theory of relativity, which relates gravity to the geometry of four-dimensional spacetime.[15]

The success of general relativity led to efforts to apply higher dimensional geometry to explain other forces. In 1919, work by Theodor Kaluza showed that by passing to five-dimensional spacetime, one can unify gravity and electromagnetism into a single force.[15] This idea was improved by physicist Oskar Klein, who suggested that the additional dimension proposed by Kaluza could take the form of a circle with radius around 10−30 cm.[16]

The Kaluza–Klein theory and subsequent attempts by Einstein to develop unified field theory were never completely successful. In part this was because Kaluza–Klein theory predicted a particle (the radion), that has never been shown to exist, and in part because it was unable to correctly predict the ratio of an electron's mass to its charge. In addition, these theories were being developed just as other physicists were beginning to discover quantum mechanics, which would ultimately prove successful in describing known forces such as electromagnetism, as well as new nuclear forces that were being discovered throughout the middle part of the century. Thus it would take almost fifty years for the idea of new dimensions to be taken seriously again.[17]

Early work on supergravity edit

Main article: Supergravity
 
In the 1980s, Edward Witten contributed to the understanding of supergravity theories. In 1995, he introduced M-theory, sparking the second superstring revolution.

New concepts and mathematical tools provided fresh insights into general relativity, giving rise to a period in the 1960s–70s now known as the golden age of general relativity.[18] In the mid-1970s, physicists began studying higher-dimensional theories combining general relativity with supersymmetry, the so-called supergravity theories.[19]

General relativity does not place any limits on the possible dimensions of spacetime. Although the theory is typically formulated in four dimensions, one can write down the same equations for the gravitational field in any number of dimensions. Supergravity is more restrictive because it places an upper limit on the number of dimensions.[12] In 1978, work by Werner Nahm showed that the maximum spacetime dimension in which one can formulate a consistent supersymmetric theory is eleven.[20] In the same year, Eugène Cremmer, Bernard Julia, and Joël Scherk of the École Normale Supérieure showed that supergravity not only permits up to eleven dimensions but is in fact most elegant in this maximal number of dimensions.[21][22]

Initially, many physicists hoped that by compactifying eleven-dimensional supergravity, it might be possible to construct realistic models of our four-dimensional world. The hope was that such models would provide a unified description of the four fundamental forces of nature: electromagnetism, the strong and weak nuclear forces, and gravity. Interest in eleven-dimensional supergravity soon waned as various flaws in this scheme were discovered. One of the problems was that the laws of physics appear to distinguish between clockwise and counterclockwise, a phenomenon known as chirality. Edward Witten and others observed this chirality property cannot be readily derived by compactifying from eleven dimensions.[22]

In the first superstring revolution in 1984, many physicists turned to string theory as a unified theory of particle physics and quantum gravity. Unlike supergravity theory, string theory was able to accommodate the chirality of the standard model, and it provided a theory of gravity consistent with quantum effects.[22] Another feature of string theory that many physicists were drawn to in the 1980s and 1990s was its high degree of uniqueness. In ordinary particle theories, one can consider any collection of elementary particles whose classical behavior is described by an arbitrary Lagrangian. In string theory, the possibilities are much more constrained: by the 1990s, physicists had argued that there were only five consistent supersymmetric versions of the theory.[22]

Relationships between string theories edit

Although there were only a handful of consistent superstring theories, it remained a mystery why there was not just one consistent formulation.[22] However, as physicists began to examine string theory more closely, they realized that these theories are related in intricate and nontrivial ways.[23]

In the late 1970s, Claus Montonen and David Olive had conjectured a special property of certain physical theories.[24] A sharpened version of their conjecture concerns a theory called N = 4 supersymmetric Yang–Mills theory, which describes theoretical particles formally similar to the quarks and gluons that make up atomic nuclei. The strength with which the particles of this theory interact is measured by a number called the coupling constant. The result of Montonen and Olive, now known as Montonen–Olive duality, states that N = 4 supersymmetric Yang–Mills theory with coupling constant g is equivalent to the same theory with coupling constant 1/g. In other words, a system of strongly interacting particles (large coupling constant) has an equivalent description as a system of weakly interacting particles (small coupling constant) and vice versa[25] by spin-moment.

In the 1990s, several theorists generalized Montonen–Olive duality to the S-duality relationship, which connects different string theories. Ashoke Sen studied S-duality in the context of heterotic strings in four dimensions.[26][27] Chris Hull and Paul Townsend showed that type IIB string theory with a large coupling constant is equivalent via S-duality to the same theory with small coupling constant.[28] Theorists also found that different string theories may be related by T-duality. This duality implies that strings propagating on completely different spacetime geometries may be physically equivalent.[29]

Membranes and fivebranes edit

String theory extends ordinary particle physics by replacing zero-dimensional point particles by one-dimensional objects called strings. In the late 1980s, it was natural for theorists to attempt to formulate other extensions in which particles are replaced by two-dimensional supermembranes or by higher-dimensional objects called branes. Such objects had been considered as early as 1962 by Paul Dirac,[30] and they were reconsidered by a small but enthusiastic group of physicists in the 1980s.[22]

Supersymmetry severely restricts the possible number of dimensions of a brane. In 1987, Eric Bergshoeff, Ergin Sezgin, and Paul Townsend showed that eleven-dimensional supergravity includes two-dimensional branes.[31] Intuitively, these objects look like sheets or membranes propagating through the eleven-dimensional spacetime. Shortly after this discovery, Michael Duff, Paul Howe, Takeo Inami, and Kellogg Stelle considered a particular compactification of eleven-dimensional supergravity with one of the dimensions curled up into a circle.[32] In this setting, one can imagine the membrane wrapping around the circular dimension. If the radius of the circle is sufficiently small, then this membrane looks just like a string in ten-dimensional spacetime. In fact, Duff and his collaborators showed that this construction reproduces exactly the strings appearing in type IIA superstring theory.[25]

In 1990, Andrew Strominger published a similar result which suggested that strongly interacting strings in ten dimensions might have an equivalent description in terms of weakly interacting five-dimensional branes.[33] Initially, physicists were unable to prove this relationship for two important reasons. On the one hand, the Montonen–Olive duality was still unproven, and so Strominger's conjecture was even more tenuous. On the other hand, there were many technical issues related to the quantum properties of five-dimensional branes.[34] The first of these problems was solved in 1993 when Ashoke Sen established that certain physical theories require the existence of objects with both electric and magnetic charge which were predicted by the work of Montonen and Olive.[35]

In spite of this progress, the relationship between strings and five-dimensional branes remained conjectural because theorists were unable to quantize the branes. Starting in 1991, a team of researchers including Michael Duff, Ramzi Khuri, Jianxin Lu, and Ruben Minasian considered a special compactification of string theory in which four of the ten dimensions curl up. If one considers a five-dimensional brane wrapped around these extra dimensions, then the brane looks just like a one-dimensional string. In this way, the conjectured relationship between strings and branes was reduced to a relationship between strings and strings, and the latter could be tested using already established theoretical techniques.[29]

Second superstring revolution edit

 
A schematic illustration of the relationship between M-theory, the five superstring theories, and eleven-dimensional supergravity. The shaded region represents a family of different physical scenarios that are possible in M-theory. In certain limiting cases corresponding to the cusps, it is natural to describe the physics using one of the six theories labeled there.
Main article: Second superstring revolution

Speaking at the string theory conference at the University of Southern California in 1995, Edward Witten of the Institute for Advanced Study made the surprising suggestion that all five superstring theories were in fact just different limiting cases of a single theory in eleven spacetime dimensions. Witten's announcement drew together all of the previous results on S- and T-duality and the appearance of two- and five-dimensional branes in string theory.[36] In the months following Witten's announcement, hundreds of new papers appeared on the Internet confirming that the new theory involved membranes in an important way.[37] Today this flurry of work is known as the second superstring revolution.[38]

One of the important developments following Witten's announcement was Witten's work in 1996 with string theorist Petr Hořava.[39][40] Witten and Hořava studied M-theory on a special spacetime geometry with two ten-dimensional boundary components. Their work shed light on the mathematical structure of M-theory and suggested possible ways of connecting M-theory to real world physics.[41]

Origin of the term edit

Initially, some physicists suggested that the new theory was a fundamental theory of membranes, but Witten was skeptical of the role of membranes in the theory. In a paper from 1996, Hořava and Witten wrote

As it has been proposed that the eleven-dimensional theory is a supermembrane theory but there are some reasons to doubt that interpretation, we will non-committally call it the M-theory, leaving to the future the relation of M to membranes.[39]

In the absence of an understanding of the true meaning and structure of M-theory, Witten has suggested that the M should stand for "magic", "mystery", or "membrane" according to taste, and the true meaning of the title should be decided when a more fundamental formulation of the theory is known.[1] Years later, he would state, "I thought my colleagues would understand that it really stood for membrane. Unfortunately, it got people confused."[42]

Matrix theory edit

BFSS matrix model edit

Main article: Matrix theory (physics)

In mathematics, a matrix is a rectangular array of numbers or other data. In physics, a matrix model is a particular kind of physical theory whose mathematical formulation involves the notion of a matrix in an important way. A matrix model describes the behavior of a set of matrices within the framework of quantum mechanics.[43][44]

One important[why?] example of a matrix model is the BFSS matrix model proposed by Tom Banks, Willy Fischler, Stephen Shenker, and Leonard Susskind in 1997. This theory describes the behavior of a set of nine large matrices. In their original paper, these authors showed, among other things, that the low energy limit of this matrix model is described by eleven-dimensional supergravity. These calculations led them to propose that the BFSS matrix model is exactly equivalent to M-theory. The BFSS matrix model can therefore be used as a prototype for a correct formulation of M-theory and a tool for investigating the properties of M-theory in a relatively simple setting.[43][clarification needed]

Noncommutative geometry edit

Main articles: Noncommutative geometry and Noncommutative quantum field theory

In geometry, it is often useful to introduce coordinates. For example, in order to study the geometry of the Euclidean plane, one defines the coordinates x and y as the distances between any point in the plane and a pair of axes. In ordinary geometry, the coordinates of a point are numbers, so they can be multiplied, and the product of two coordinates does not depend on the order of multiplication. That is, xy = yx. This property of multiplication is known as the commutative law, and this relationship between geometry and the commutative algebra of coordinates is the starting point for much of modern geometry.[45]

Noncommutative geometry is a branch of mathematics that attempts to generalize this situation. Rather than working with ordinary numbers, one considers some similar objects, such as matrices, whose multiplication does not satisfy the commutative law (that is, objects for which xy is not necessarily equal to yx). One imagines that these noncommuting objects are coordinates on some more general notion of "space" and proves theorems about these generalized spaces by exploiting the analogy with ordinary geometry.[46]

In a paper from 1998, Alain Connes, Michael R. Douglas, and Albert Schwarz showed that some aspects of matrix models and M-theory are described by a noncommutative quantum field theory, a special kind of physical theory in which the coordinates on spacetime do not satisfy the commutativity property.[44] This established a link between matrix models and M-theory on the one hand, and noncommutative geometry on the other hand. It quickly led to the discovery of other important links between noncommutative geometry and various physical theories.[47][48]

AdS/CFT correspondence edit

Overview edit

Main article: AdS/CFT correspondence
 
A tessellation of the hyperbolic plane by triangles and squares

The application of quantum mechanics to physical objects such as the electromagnetic field, which are extended in space and time, is known as quantum field theory.[i] In particle physics, quantum field theories form the basis for our understanding of elementary particles, which are modeled as excitations in the fundamental fields. Quantum field theories are also used throughout condensed matter physics to model particle-like objects called quasiparticles.[j]

One approach to formulating M-theory and studying its properties is provided by the anti-de Sitter/conformal field theory (AdS/CFT) correspondence. Proposed by Juan Maldacena in late 1997, the AdS/CFT correspondence is a theoretical result which implies that M-theory is in some cases equivalent to a quantum field theory.[49] In addition to providing insights into the mathematical structure of string and M-theory, the AdS/CFT correspondence has shed light on many aspects of quantum field theory in regimes where traditional calculational techniques are ineffective.[50]

In the AdS/CFT correspondence, the geometry of spacetime is described in terms of a certain vacuum solution of Einstein's equation called anti-de Sitter space.[51] In very elementary terms, anti-de Sitter space is a mathematical model of spacetime in which the notion of distance between points (the metric) is different from the notion of distance in ordinary Euclidean geometry. It is closely related to hyperbolic space, which can be viewed as a disk as illustrated on the left.[52] This image shows a tessellation of a disk by triangles and squares. One can define the distance between points of this disk in such a way that all the triangles and squares are the same size and the circular outer boundary is infinitely far from any point in the interior.[53]

 
Three-dimensional anti-de Sitter space is like a stack of hyperbolic disks, each one representing the state of the universe at a given time. One can study theories of quantum gravity such as M-theory in the resulting spacetime.

Now imagine a stack of hyperbolic disks where each disk represents the state of the universe at a given time. The resulting geometric object is three-dimensional anti-de Sitter space.[52] It looks like a solid cylinder in which any cross section is a copy of the hyperbolic disk. Time runs along the vertical direction in this picture. The surface of this cylinder plays an important role in the AdS/CFT correspondence. As with the hyperbolic plane, anti-de Sitter space is curved in such a way that any point in the interior is actually infinitely far from this boundary surface.[53]

This construction describes a hypothetical universe with only two space dimensions and one time dimension, but it can be generalized to any number of dimensions. Indeed, hyperbolic space can have more than two dimensions and one can "stack up" copies of hyperbolic space to get higher-dimensional models of anti-de Sitter space.[52]

An important feature of anti-de Sitter space is its boundary (which looks like a cylinder in the case of three-dimensional anti-de Sitter space). One property of this boundary is that, within a small region on the surface around any given point, it looks just like Minkowski space, the model of spacetime used in nongravitational physics.[54] One can therefore consider an auxiliary theory in which "spacetime" is given by the boundary of anti-de Sitter space. This observation is the starting point for AdS/CFT correspondence, which states that the boundary of anti-de Sitter space can be regarded as the "spacetime" for a quantum field theory. The claim is that this quantum field theory is equivalent to the gravitational theory on the bulk anti-de Sitter space in the sense that there is a "dictionary" for translating entities and calculations in one theory into their counterparts in the other theory. For example, a single particle in the gravitational theory might correspond to some collection of particles in the boundary theory. In addition, the predictions in the two theories are quantitatively identical so that if two particles have a 40 percent chance of colliding in the gravitational theory, then the corresponding collections in the boundary theory would also have a 40 percent chance of colliding.[55]

6D (2,0) superconformal field theory edit

Main article: 6D (2,0) superconformal field theory
 
The six-dimensional (2,0)-theory has been used to understand results from the mathematical theory of knots.

One particular realization of the AdS/CFT correspondence states that M-theory on the product space AdS7×S4 is equivalent to the so-called (2,0)-theory on the six-dimensional boundary.[49] Here "(2,0)" refers to the particular type of supersymmetry that appears in the theory. In this example, the spacetime of the gravitational theory is effectively seven-dimensional (hence the notation AdS7), and there are four additional "compact" dimensions (encoded by the S4 factor). In the real world, spacetime is four-dimensional, at least macroscopically, so this version of the correspondence does not provide a realistic model of gravity. Likewise, the dual theory is not a viable model of any real-world system since it describes a world with six spacetime dimensions.[k]

Nevertheless, the (2,0)-theory has proven to be important for studying the general properties of quantum field theories. Indeed, this theory subsumes many mathematically interesting effective quantum field theories and points to new dualities relating these theories. For example, Luis Alday, Davide Gaiotto, and Yuji Tachikawa showed that by compactifying this theory on a surface, one obtains a four-dimensional quantum field theory, and there is a duality known as the AGT correspondence which relates the physics of this theory to certain physical concepts associated with the surface itself.[56] More recently, theorists have extended these ideas to study the theories obtained by compactifying down to three dimensions.[57]

In addition to its applications in quantum field theory, the (2,0)-theory has spawned important results in pure mathematics. For example, the existence of the (2,0)-theory was used by Witten to give a "physical" explanation for a conjectural relationship in mathematics called the geometric Langlands correspondence.[58] In subsequent work, Witten showed that the (2,0)-theory could be used to understand a concept in mathematics called Khovanov homology.[59] Developed by Mikhail Khovanov around 2000, Khovanov homology provides a tool in knot theory, the branch of mathematics that studies and classifies the different shapes of knots.[60] Another application of the (2,0)-theory in mathematics is the work of Davide Gaiotto, Greg Moore, and Andrew Neitzke, which used physical ideas to derive new results in hyperkähler geometry.[61]

ABJM superconformal field theory edit

Main article: ABJM superconformal field theory

Another realization of the AdS/CFT correspondence states that M-theory on AdS4×S7 is equivalent to a quantum field theory called the ABJM theory in three dimensions. In this version of the correspondence, seven of the dimensions of M-theory are curled up, leaving four non-compact dimensions. Since the spacetime of our universe is four-dimensional, this version of the correspondence provides a somewhat more realistic description of gravity.[62]

The ABJM theory appearing in this version of the correspondence is also interesting for a variety of reasons. Introduced by Aharony, Bergman, Jafferis, and Maldacena, it is closely related to another quantum field theory called Chern–Simons theory. The latter theory was popularized by Witten in the late 1980s because of its applications to knot theory.[63] In addition, the ABJM theory serves as a semi-realistic simplified model for solving problems that arise in condensed matter physics.[62]

Phenomenology edit

Overview edit

Main article: String phenomenology
 
A cross section of a Calabi–Yau manifold

In addition to being an idea of considerable theoretical interest, M-theory provides a framework for constructing models of real world physics that combine general relativity with the standard model of particle physics. Phenomenology is the branch of theoretical physics in which physicists construct realistic models of nature from more abstract theoretical ideas. String phenomenology is the part of string theory that attempts to construct realistic models of particle physics based on string and M-theory.[64]

Typically, such models are based on the idea of compactification.[l] Starting with the ten- or eleven-dimensional spacetime of string or M-theory, physicists postulate a shape for the extra dimensions. By choosing this shape appropriately, they can construct models roughly similar to the standard model of particle physics, together with additional undiscovered particles,[65] usually supersymmetric partners to analogues of known particles. One popular way of deriving realistic physics from string theory is to start with the heterotic theory in ten dimensions and assume that the six extra dimensions of spacetime are shaped like a six-dimensional Calabi–Yau manifold. This is a special kind of geometric object named after mathematicians Eugenio Calabi and Shing-Tung Yau.[66] Calabi–Yau manifolds offer many ways of extracting realistic physics from string theory. Other similar methods can be used to construct models with physics resembling to some extent that of our four-dimensional world based on M-theory.[67]

Partly because of theoretical and mathematical difficulties and partly because of the extremely high energies (beyond what is technologically possible for the foreseeable future) needed to test these theories experimentally, there is so far no experimental evidence that would unambiguously point to any of these models being a correct fundamental description of nature. This has led some in the community to criticize these approaches to unification and question the value of continued research on these problems.[68]

Compactification on G2 manifolds edit

In one approach to M-theory phenomenology, theorists assume that the seven extra dimensions of M-theory are shaped like a G2 manifold. This is a special kind of seven-dimensional shape constructed by mathematician Dominic Joyce of the University of Oxford.[69] These G2 manifolds are still poorly understood mathematically, and this fact has made it difficult for physicists to fully develop this approach to phenomenology.[70]

For example, physicists and mathematicians often assume that space has a mathematical property called smoothness, but this property cannot be assumed in the case of a G2 manifold if one wishes to recover the physics of our four-dimensional world. Another problem is that G2 manifolds are not complex manifolds, so theorists are unable to use tools from the branch of mathematics known as complex analysis. Finally, there are many open questions about the existence, uniqueness, and other mathematical properties of G2 manifolds, and mathematicians lack a systematic way of searching for these manifolds.[70]

Heterotic M-theory edit

Because of the difficulties with G2 manifolds, most attempts to construct realistic theories of physics based on M-theory have taken a more indirect approach to compactifying eleven-dimensional spacetime. One approach, pioneered by Witten, Hořava, Burt Ovrut, and others, is known as heterotic M-theory. In this approach, one imagines that one of the eleven dimensions of M-theory is shaped like a circle. If this circle is very small, then the spacetime becomes effectively ten-dimensional. One then assumes that six of the ten dimensions form a Calabi–Yau manifold. If this Calabi–Yau manifold is also taken to be small, one is left with a theory in four-dimensions.[70]

Heterotic M-theory has been used to construct models of brane cosmology in which the observable universe is thought to exist on a brane in a higher dimensional ambient space. It has also spawned alternative theories of the early universe that do not rely on the theory of cosmic inflation.[70]

References edit

Notes edit

  1. ^ For a standard introduction to quantum mechanics, see Griffiths 2004.
  2. ^ The necessity of a quantum mechanical description of gravity follows from the fact that one cannot consistently couple a classical system to a quantum one. See Wald 1984, p. 382.
  3. ^ From a technical point of view, the problem is that the theory one gets in this way is not renormalizable and therefore cannot be used to make meaningful physical predictions. See Zee 2010, p. 72 for a discussion of this issue.
  4. ^ For an accessible introduction to string theory, see Greene 2000.
  5. ^ For example, in the context of the AdS/CFT correspondence, theorists often formulate and study theories of gravity in unphysical numbers of spacetime dimensions.
  6. ^ Dimensional reduction is another way of modifying the number of dimensions.
  7. ^ This analogy is used for example in Greene 2000, p. 186.
  8. ^ For example, see the subsections on the 6D (2,0) superconformal field theory and ABJM superconformal field theory.
  9. ^ A standard text is Peskin and Schroeder 1995.
  10. ^ For an introduction to the applications of quantum field theory to condensed matter physics, see Zee 2010.
  11. ^ For a review of the (2,0)-theory, see Moore 2012.
  12. ^ Brane world scenarios provide an alternative way of recovering real world physics from string theory. See Randall and Sundrum 1999.

Citations edit

  1. ^ a b Duff 1996, sec. 1
  2. ^ Zwiebach 2009, p. 324
  3. ^ a b Becker, Becker, and Schwarz 2007, p. 12
  4. ^ Wald 1984, p. 4
  5. ^ Zee 2010, Parts V and VI
  6. ^ Zwiebach 2009, p. 9
  7. ^ Zwiebach 2009, p. 8
  8. ^ Yau and Nadis 2010, Ch. 6
  9. ^ Becker, Becker, and Schwarz 2007, pp. 339–347
  10. ^ a b Becker, Becker, and Schwarz 2007
  11. ^ Zwiebach 2009, p. 376
  12. ^ a b Duff 1998, p. 64
  13. ^ Moore 2005
  14. ^ Yau and Nadis 2010, p. 9
  15. ^ a b Yau and Nadis 2010, p. 10
  16. ^ Yau and Nadis 2010, p. 12
  17. ^ Yau and Nadis 2010, p. 13
  18. ^ Wald 1984, p. 3
  19. ^ van Nieuwenhuizen 1981
  20. ^ Nahm 1978
  21. ^ Cremmer, Julia, and Scherk 1978
  22. ^ a b c d e f Duff 1998, p. 65
  23. ^ Duff 1998
  24. ^ Montonen and Olive 1977
  25. ^ a b Duff 1998, p. 66
  26. ^ Sen 1994a
  27. ^ Sen 1994b
  28. ^ Hull and Townsend 1995
  29. ^ a b Duff 1998, p. 67
  30. ^ Dirac 1962
  31. ^ Bergshoeff, Sezgin, and Townsend 1987
  32. ^ Duff et al. 1987
  33. ^ Strominger 1990
  34. ^ Duff 1998, pp 66–67
  35. ^ Sen 1993
  36. ^ Witten 1995
  37. ^ Duff 1998, pp. 67–68
  38. ^ Becker, Becker, and Schwarz 2007, p. 296
  39. ^ a b Hořava and Witten 1996a
  40. ^ Hořava and Witten 1996b
  41. ^ Duff 1998, p. 68
  42. ^ Gefter, Amanda (2014). Trespassing on Einstein's Lawn: A Father, a Daughter, the Meaning of Nothing and the Beginning of Everything. Random House. ISBN 978-0-345-531438. at 345
  43. ^ a b Banks et al. 1997
  44. ^ a b Connes, Douglas, and Schwarz 1998
  45. ^ Connes 1994, p. 1
  46. ^ Connes 1994
  47. ^ Nekrasov and Schwarz 1998
  48. ^ Seiberg and Witten 1999
  49. ^ a b Maldacena 1998
  50. ^ Klebanov and Maldacena 2009
  51. ^ Klebanov and Maldacena 2009, p. 28
  52. ^ a b c Maldacena 2005, p. 60
  53. ^ a b Maldacena 2005, p. 61
  54. ^ Zwiebach 2009, p. 552
  55. ^ Maldacena 2005, pp. 61–62
  56. ^ Alday, Gaiotto, and Tachikawa 2010
  57. ^ Dimofte, Gaiotto, and Gukov 2010
  58. ^ Witten 2009
  59. ^ Witten 2012
  60. ^ Khovanov 2000
  61. ^ Gaiotto, Moore, and Neitzke 2013
  62. ^ a b Aharony et al. 2008
  63. ^ Witten 1989
  64. ^ Dine 2000
  65. ^ Candelas et al. 1985
  66. ^ Yau and Nadis 2010, p. ix
  67. ^ Yau and Nadis 2010, pp. 147–150
  68. ^ Woit 2006
  69. ^ Yau and Nadis 2010, p. 149
  70. ^ a b c d Yau and Nadis 2010, p. 150

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Popularization edit

  • BBC Horizon: "Parallel Universes" – 2002 feature documentary by BBC Horizon, episode "Parallel Universes" focuses on the history and emergence of M-theory, and scientists involved
  • [1] PBS.org-NOVA: The Elegant Universe] – 2003 Emmy Award-winning, three-hour miniseries by Nova with Brian Greene, adapted from his The Elegant Universe book (original PBS broadcast dates: October 28, 8–10 p.m. and November 4, 8–9 p.m., 2003)

See also edit

External links edit

  • Superstringtheory.com – The "Official String Theory Web Site", created by Patricia Schwarz. References on string theory and M-theory for the layperson and expert.
  • Not Even Wrong – Peter Woit's blog on physics in general, and string theory in particular.
  • M-Theory - Edward Witten (1995)  - Witten's 1995 lecture introducing M-Theory.

January 01, 1970
theory, more, accessible, less, technical, introduction, this, topic, introduction, theory, physics, that, unifies, consistent, versions, superstring, theory, edward, witten, first, conjectured, existence, such, theory, string, theory, conference, university, . For a more accessible and less technical introduction to this topic see Introduction to M theory M theory is a theory in physics that unifies all consistent versions of superstring theory Edward Witten first conjectured the existence of such a theory at a string theory conference at the University of Southern California in 1995 Witten s announcement initiated a flurry of research activity known as the second superstring revolution Prior to Witten s announcement string theorists had identified five versions of superstring theory Although these theories initially appeared to be very different work by many physicists showed that the theories were related in intricate and nontrivial ways Physicists found that apparently distinct theories could be unified by mathematical transformations called S duality and T duality Witten s conjecture was based in part on the existence of these dualities and in part on the relationship of the string theories to a field theory called eleven dimensional supergravity Although a complete formulation of M theory is not known such a formulation should describe two and five dimensional objects called branes and should be approximated by eleven dimensional supergravity at low energies Modern attempts to formulate M theory are typically based on matrix theory or the AdS CFT correspondence According to Witten M should stand for magic mystery or membrane according to taste and the true meaning of the title should be decided when a more fundamental formulation of the theory is known 1 Investigations of the mathematical structure of M theory have spawned important theoretical results in physics and mathematics More speculatively M theory may provide a framework for developing a unified theory of all of the fundamental forces of nature Attempts to connect M theory to experiment typically focus on compactifying its extra dimensions to construct candidate models of the four dimensional world although so far none has been verified to give rise to physics as observed in high energy physics experiments Contents 1 Background 1 1 Quantum gravity and strings 1 2 Number of dimensions 1 3 Dualities 1 4 Supersymmetry 1 5 Branes 2 History and development 2 1 Kaluza Klein theory 2 2 Early work on supergravity 2 3 Relationships between string theories 2 4 Membranes and fivebranes 2 5 Second superstring revolution 2 6 Origin of the term 3 Matrix theory 3 1 BFSS matrix model 3 2 Noncommutative geometry 4 AdS CFT correspondence 4 1 Overview 4 2 6D 2 0 superconformal field theory 4 3 ABJM superconformal field theory 5 Phenomenology 5 1 Overview 5 2 Compactification on G2 manifolds 5 3 Heterotic M theory 6 References 6 1 Notes 6 2 Citations 6 3 Bibliography 7 Popularization 8 See also 9 External linksBackground editQuantum gravity and strings edit Main articles Quantum gravity and String theory nbsp The fundamental objects of string theory are open and closed strings One of the deepest problems in modern physics is the problem of quantum gravity The current understanding of gravity is based on Albert Einstein s general theory of relativity which is formulated within the framework of classical physics However nongravitational forces are described within the framework of quantum mechanics a radically different formalism for describing physical phenomena based on probability a A quantum theory of gravity is needed in order to reconcile general relativity with the principles of quantum mechanics b but difficulties arise when one attempts to apply the usual prescriptions of quantum theory to the force of gravity c String theory is a theoretical framework that attempts to reconcile gravity and quantum mechanics In string theory the point like particles of particle physics are replaced by one dimensional objects called strings String theory describes how strings propagate through space and interact with each other In a given version of string theory there is only one kind of string which may look like a small loop or segment of ordinary string and it can vibrate in different ways On distance scales larger than the string scale a string will look just like an ordinary particle with its mass charge and other properties determined by the vibrational state of the string In this way all of the different elementary particles may be viewed as vibrating strings One of the vibrational states of a string gives rise to the graviton a quantum mechanical particle that carries gravitational force d There are several versions of string theory type I type IIA type IIB and two flavors of heterotic string theory SO 32 and E8 E8 The different theories allow different types of strings and the particles that arise at low energies exhibit different symmetries For example the type I theory includes both open strings which are segments with endpoints and closed strings which form closed loops while types IIA and IIB include only closed strings 2 Each of these five string theories arises as a special limiting case of M theory This theory like its string theory predecessors is an example of a quantum theory of gravity It describes a force just like the familiar gravitational force subject to the rules of quantum mechanics 3 Number of dimensions edit Main articles Extra dimensions and Compactification physics nbsp An example of compactification At large distances a two dimensional surface with one circular dimension looks one dimensional In everyday life there are three familiar dimensions of space height width and depth Einstein s general theory of relativity treats time as a dimension on par with the three spatial dimensions in general relativity space and time are not modeled as separate entities but are instead unified to a four dimensional spacetime three spatial dimensions and one time dimension In this framework the phenomenon of gravity is viewed as a consequence of the geometry of spacetime 4 In spite of the fact that the universe is well described by four dimensional spacetime there are several reasons why physicists consider theories in other dimensions In some cases by modeling spacetime in a different number of dimensions a theory becomes more mathematically tractable and one can perform calculations and gain general insights more easily e There are also situations where theories in two or three spacetime dimensions are useful for describing phenomena in condensed matter physics 5 Finally there exist scenarios in which there could actually be more than four dimensions of spacetime which have nonetheless managed to escape detection 6 One notable feature of string theory and M theory is that these theories require extra dimensions of spacetime for their mathematical consistency In string theory spacetime is ten dimensional nine spatial dimensions and one time dimension while in M theory it is eleven dimensional ten spatial dimensions and one time dimension In order to describe real physical phenomena using these theories one must therefore imagine scenarios in which these extra dimensions would not be observed in experiments 7 Compactification is one way of modifying the number of dimensions in a physical theory f In compactification some of the extra dimensions are assumed to close up on themselves to form circles 8 In the limit where these curled up dimensions become very small one obtains a theory in which spacetime has effectively a lower number of dimensions A standard analogy for this is to consider a multidimensional object such as a garden hose If the hose is viewed from a sufficient distance it appears to have only one dimension its length However as one approaches the hose one discovers that it contains a second dimension its circumference Thus an ant crawling on the surface of the hose would move in two dimensions g Dualities edit Main articles String duality S duality and T duality nbsp A diagram of string theory dualities Yellow arrows indicate S duality Blue arrows indicate T duality These dualities may be combined to obtain equivalences of any of the five theories with M theory 9 Theories that arise as different limits of M theory turn out to be related in highly nontrivial ways One of the relationships that can exist between these different physical theories is called S duality This is a relationship which says that a collection of strongly interacting particles in one theory can in some cases be viewed as a collection of weakly interacting particles in a completely different theory Roughly speaking a collection of particles is said to be strongly interacting if they combine and decay often and weakly interacting if they do so infrequently Type I string theory turns out to be equivalent by S duality to the SO 32 heterotic string theory Similarly type IIB string theory is related to itself in a nontrivial way by S duality 10 Another relationship between different string theories is T duality Here one considers strings propagating around a circular extra dimension T duality states that a string propagating around a circle of radius R is equivalent to a string propagating around a circle of radius 1 R in the sense that all observable quantities in one description are identified with quantities in the dual description For example a string has momentum as it propagates around a circle and it can also wind around the circle one or more times The number of times the string winds around a circle is called the winding number If a string has momentum p and winding number n in one description it will have momentum n and winding number p in the dual description For example type IIA string theory is equivalent to type IIB string theory via T duality and the two versions of heterotic string theory are also related by T duality 10 In general the term duality refers to a situation where two seemingly different physical systems turn out to be equivalent in a nontrivial way If two theories are related by a duality it means that one theory can be transformed in some way so that it ends up looking just like the other theory The two theories are then said to be dual to one another under the transformation Put differently the two theories are mathematically different descriptions of the same phenomena 11 Supersymmetry edit Main article Supersymmetry Another important theoretical idea that plays a role in M theory is supersymmetry This is a mathematical relation that exists in certain physical theories between a class of particles called bosons and a class of particles called fermions Roughly speaking fermions are the constituents of matter while bosons mediate interactions between particles In theories with supersymmetry each boson has a counterpart which is a fermion and vice versa When supersymmetry is imposed as a local symmetry one automatically obtains a quantum mechanical theory that includes gravity Such a theory is called a supergravity theory 12 A theory of strings that incorporates the idea of supersymmetry is called a superstring theory There are several different versions of superstring theory which are all subsumed within the M theory framework At low energies the superstring theories are approximated by supergravity in ten spacetime dimensions Similarly M theory is approximated at low energies by supergravity in eleven dimensions 3 Branes edit Main article Brane In string theory and related theories such as supergravity theories a brane is a physical object that generalizes the notion of a point particle to higher dimensions For example a point particle can be viewed as a brane of dimension zero while a string can be viewed as a brane of dimension one It is also possible to consider higher dimensional branes In dimension p these are called p branes Branes are dynamical objects which can propagate through spacetime according to the rules of quantum mechanics They can have mass and other attributes such as charge A p brane sweeps out a p 1 dimensional volume in spacetime called its worldvolume Physicists often study fields analogous to the electromagnetic field which live on the worldvolume of a brane The word brane comes from the word membrane which refers to a two dimensional brane 13 In string theory the fundamental objects that give rise to elementary particles are the one dimensional strings Although the physical phenomena described by M theory are still poorly understood physicists know that the theory describes two and five dimensional branes Much of the current research in M theory attempts to better understand the properties of these branes h History and development editMain article History of string theory Kaluza Klein theory edit Main article Kaluza Klein theory In the early 20th century physicists and mathematicians including Albert Einstein and Hermann Minkowski pioneered the use of four dimensional geometry for describing the physical world 14 These efforts culminated in the formulation of Einstein s general theory of relativity which relates gravity to the geometry of four dimensional spacetime 15 The success of general relativity led to efforts to apply higher dimensional geometry to explain other forces In 1919 work by Theodor Kaluza showed that by passing to five dimensional spacetime one can unify gravity and electromagnetism into a single force 15 This idea was improved by physicist Oskar Klein who suggested that the additional dimension proposed by Kaluza could take the form of a circle with radius around 10 30 cm 16 The Kaluza Klein theory and subsequent attempts by Einstein to develop unified field theory were never completely successful In part this was because Kaluza Klein theory predicted a particle the radion that has never been shown to exist and in part because it was unable to correctly predict the ratio of an electron s mass to its charge In addition these theories were being developed just as other physicists were beginning to discover quantum mechanics which would ultimately prove successful in describing known forces such as electromagnetism as well as new nuclear forces that were being discovered throughout the middle part of the century Thus it would take almost fifty years for the idea of new dimensions to be taken seriously again 17 Early work on supergravity edit Main article Supergravity nbsp In the 1980s Edward Witten contributed to the understanding of supergravity theories In 1995 he introduced M theory sparking the second superstring revolution New concepts and mathematical tools provided fresh insights into general relativity giving rise to a period in the 1960s 70s now known as the golden age of general relativity 18 In the mid 1970s physicists began studying higher dimensional theories combining general relativity with supersymmetry the so called supergravity theories 19 General relativity does not place any limits on the possible dimensions of spacetime Although the theory is typically formulated in four dimensions one can write down the same equations for the gravitational field in any number of dimensions Supergravity is more restrictive because it places an upper limit on the number of dimensions 12 In 1978 work by Werner Nahm showed that the maximum spacetime dimension in which one can formulate a consistent supersymmetric theory is eleven 20 In the same year Eugene Cremmer Bernard Julia and Joel Scherk of the Ecole Normale Superieure showed that supergravity not only permits up to eleven dimensions but is in fact most elegant in this maximal number of dimensions 21 22 Initially many physicists hoped that by compactifying eleven dimensional supergravity it might be possible to construct realistic models of our four dimensional world The hope was that such models would provide a unified description of the four fundamental forces of nature electromagnetism the strong and weak nuclear forces and gravity Interest in eleven dimensional supergravity soon waned as various flaws in this scheme were discovered One of the problems was that the laws of physics appear to distinguish between clockwise and counterclockwise a phenomenon known as chirality Edward Witten and others observed this chirality property cannot be readily derived by compactifying from eleven dimensions 22 In the first superstring revolution in 1984 many physicists turned to string theory as a unified theory of particle physics and quantum gravity Unlike supergravity theory string theory was able to accommodate the chirality of the standard model and it provided a theory of gravity consistent with quantum effects 22 Another feature of string theory that many physicists were drawn to in the 1980s and 1990s was its high degree of uniqueness In ordinary particle theories one can consider any collection of elementary particles whose classical behavior is described by an arbitrary Lagrangian In string theory the possibilities are much more constrained by the 1990s physicists had argued that there were only five consistent supersymmetric versions of the theory 22 Relationships between string theories edit Although there were only a handful of consistent superstring theories it remained a mystery why there was not just one consistent formulation 22 However as physicists began to examine string theory more closely they realized that these theories are related in intricate and nontrivial ways 23 In the late 1970s Claus Montonen and David Olive had conjectured a special property of certain physical theories 24 A sharpened version of their conjecture concerns a theory called N 4 supersymmetric Yang Mills theory which describes theoretical particles formally similar to the quarks and gluons that make up atomic nuclei The strength with which the particles of this theory interact is measured by a number called the coupling constant The result of Montonen and Olive now known as Montonen Olive duality states that N 4 supersymmetric Yang Mills theory with coupling constant g is equivalent to the same theory with coupling constant 1 g In other words a system of strongly interacting particles large coupling constant has an equivalent description as a system of weakly interacting particles small coupling constant and vice versa 25 by spin moment In the 1990s several theorists generalized Montonen Olive duality to the S duality relationship which connects different string theories Ashoke Sen studied S duality in the context of heterotic strings in four dimensions 26 27 Chris Hull and Paul Townsend showed that type IIB string theory with a large coupling constant is equivalent via S duality to the same theory with small coupling constant 28 Theorists also found that different string theories may be related by T duality This duality implies that strings propagating on completely different spacetime geometries may be physically equivalent 29 Membranes and fivebranes edit String theory extends ordinary particle physics by replacing zero dimensional point particles by one dimensional objects called strings In the late 1980s it was natural for theorists to attempt to formulate other extensions in which particles are replaced by two dimensional supermembranes or by higher dimensional objects called branes Such objects had been considered as early as 1962 by Paul Dirac 30 and they were reconsidered by a small but enthusiastic group of physicists in the 1980s 22 Supersymmetry severely restricts the possible number of dimensions of a brane In 1987 Eric Bergshoeff Ergin Sezgin and Paul Townsend showed that eleven dimensional supergravity includes two dimensional branes 31 Intuitively these objects look like sheets or membranes propagating through the eleven dimensional spacetime Shortly after this discovery Michael Duff Paul Howe Takeo Inami and Kellogg Stelle considered a particular compactification of eleven dimensional supergravity with one of the dimensions curled up into a circle 32 In this setting one can imagine the membrane wrapping around the circular dimension If the radius of the circle is sufficiently small then this membrane looks just like a string in ten dimensional spacetime In fact Duff and his collaborators showed that this construction reproduces exactly the strings appearing in type IIA superstring theory 25 In 1990 Andrew Strominger published a similar result which suggested that strongly interacting strings in ten dimensions might have an equivalent description in terms of weakly interacting five dimensional branes 33 Initially physicists were unable to prove this relationship for two important reasons On the one hand the Montonen Olive duality was still unproven and so Strominger s conjecture was even more tenuous On the other hand there were many technical issues related to the quantum properties of five dimensional branes 34 The first of these problems was solved in 1993 when Ashoke Sen established that certain physical theories require the existence of objects with both electric and magnetic charge which were predicted by the work of Montonen and Olive 35 In spite of this progress the relationship between strings and five dimensional branes remained conjectural because theorists were unable to quantize the branes Starting in 1991 a team of researchers including Michael Duff Ramzi Khuri Jianxin Lu and Ruben Minasian considered a special compactification of string theory in which four of the ten dimensions curl up If one considers a five dimensional brane wrapped around these extra dimensions then the brane looks just like a one dimensional string In this way the conjectured relationship between strings and branes was reduced to a relationship between strings and strings and the latter could be tested using already established theoretical techniques 29 Second superstring revolution edit nbsp A schematic illustration of the relationship between M theory the five superstring theories and eleven dimensional supergravity The shaded region represents a family of different physical scenarios that are possible in M theory In certain limiting cases corresponding to the cusps it is natural to describe the physics using one of the six theories labeled there Main article Second superstring revolution Speaking at the string theory conference at the University of Southern California in 1995 Edward Witten of the Institute for Advanced Study made the surprising suggestion that all five superstring theories were in fact just different limiting cases of a single theory in eleven spacetime dimensions Witten s announcement drew together all of the previous results on S and T duality and the appearance of two and five dimensional branes in string theory 36 In the months following Witten s announcement hundreds of new papers appeared on the Internet confirming that the new theory involved membranes in an important way 37 Today this flurry of work is known as the second superstring revolution 38 One of the important developments following Witten s announcement was Witten s work in 1996 with string theorist Petr Horava 39 40 Witten and Horava studied M theory on a special spacetime geometry with two ten dimensional boundary components Their work shed light on the mathematical structure of M theory and suggested possible ways of connecting M theory to real world physics 41 Origin of the term edit Initially some physicists suggested that the new theory was a fundamental theory of membranes but Witten was skeptical of the role of membranes in the theory In a paper from 1996 Horava and Witten wrote As it has been proposed that the eleven dimensional theory is a supermembrane theory but there are some reasons to doubt that interpretation we will non committally call it the M theory leaving to the future the relation of M to membranes 39 In the absence of an understanding of the true meaning and structure of M theory Witten has suggested that the M should stand for magic mystery or membrane according to taste and the true meaning of the title should be decided when a more fundamental formulation of the theory is known 1 Years later he would state I thought my colleagues would understand that it really stood for membrane Unfortunately it got people confused 42 Matrix theory editBFSS matrix model edit Main article Matrix theory physics In mathematics a matrix is a rectangular array of numbers or other data In physics a matrix model is a particular kind of physical theory whose mathematical formulation involves the notion of a matrix in an important way A matrix model describes the behavior of a set of matrices within the framework of quantum mechanics 43 44 One important why example of a matrix model is the BFSS matrix model proposed by Tom Banks Willy Fischler Stephen Shenker and Leonard Susskind in 1997 This theory describes the behavior of a set of nine large matrices In their original paper these authors showed among other things that the low energy limit of this matrix model is described by eleven dimensional supergravity These calculations led them to propose that the BFSS matrix model is exactly equivalent to M theory The BFSS matrix model can therefore be used as a prototype for a correct formulation of M theory and a tool for investigating the properties of M theory in a relatively simple setting 43 clarification needed Noncommutative geometry edit Main articles Noncommutative geometry and Noncommutative quantum field theory In geometry it is often useful to introduce coordinates For example in order to study the geometry of the Euclidean plane one defines the coordinates x and y as the distances between any point in the plane and a pair of axes In ordinary geometry the coordinates of a point are numbers so they can be multiplied and the product of two coordinates does not depend on the order of multiplication That is xy yx This property of multiplication is known as the commutative law and this relationship between geometry and the commutative algebra of coordinates is the starting point for much of modern geometry 45 Noncommutative geometry is a branch of mathematics that attempts to generalize this situation Rather than working with ordinary numbers one considers some similar objects such as matrices whose multiplication does not satisfy the commutative law that is objects for which xy is not necessarily equal to yx One imagines that these noncommuting objects are coordinates on some more general notion of space and proves theorems about these generalized spaces by exploiting the analogy with ordinary geometry 46 In a paper from 1998 Alain Connes Michael R Douglas and Albert Schwarz showed that some aspects of matrix models and M theory are described by a noncommutative quantum field theory a special kind of physical theory in which the coordinates on spacetime do not satisfy the commutativity property 44 This established a link between matrix models and M theory on the one hand and noncommutative geometry on the other hand It quickly led to the discovery of other important links between noncommutative geometry and various physical theories 47 48 AdS CFT correspondence editOverview edit Main article AdS CFT correspondence nbsp A tessellation of the hyperbolic plane by triangles and squares The application of quantum mechanics to physical objects such as the electromagnetic field which are extended in space and time is known as quantum field theory i In particle physics quantum field theories form the basis for our understanding of elementary particles which are modeled as excitations in the fundamental fields Quantum field theories are also used throughout condensed matter physics to model particle like objects called quasiparticles j One approach to formulating M theory and studying its properties is provided by the anti de Sitter conformal field theory AdS CFT correspondence Proposed by Juan Maldacena in late 1997 the AdS CFT correspondence is a theoretical result which implies that M theory is in some cases equivalent to a quantum field theory 49 In addition to providing insights into the mathematical structure of string and M theory the AdS CFT correspondence has shed light on many aspects of quantum field theory in regimes where traditional calculational techniques are ineffective 50 In the AdS CFT correspondence the geometry of spacetime is described in terms of a certain vacuum solution of Einstein s equation called anti de Sitter space 51 In very elementary terms anti de Sitter space is a mathematical model of spacetime in which the notion of distance between points the metric is different from the notion of distance in ordinary Euclidean geometry It is closely related to hyperbolic space which can be viewed as a disk as illustrated on the left 52 This image shows a tessellation of a disk by triangles and squares One can define the distance between points of this disk in such a way that all the triangles and squares are the same size and the circular outer boundary is infinitely far from any point in the interior 53 nbsp Three dimensional anti de Sitter space is like a stack of hyperbolic disks each one representing the state of the universe at a given time One can study theories of quantum gravity such as M theory in the resulting spacetime Now imagine a stack of hyperbolic disks where each disk represents the state of the universe at a given time The resulting geometric object is three dimensional anti de Sitter space 52 It looks like a solid cylinder in which any cross section is a copy of the hyperbolic disk Time runs along the vertical direction in this picture The surface of this cylinder plays an important role in the AdS CFT correspondence As with the hyperbolic plane anti de Sitter space is curved in such a way that any point in the interior is actually infinitely far from this boundary surface 53 This construction describes a hypothetical universe with only two space dimensions and one time dimension but it can be generalized to any number of dimensions Indeed hyperbolic space can have more than two dimensions and one can stack up copies of hyperbolic space to get higher dimensional models of anti de Sitter space 52 An important feature of anti de Sitter space is its boundary which looks like a cylinder in the case of three dimensional anti de Sitter space One property of this boundary is that within a small region on the surface around any given point it looks just like Minkowski space the model of spacetime used in nongravitational physics 54 One can therefore consider an auxiliary theory in which spacetime is given by the boundary of anti de Sitter space This observation is the starting point for AdS CFT correspondence which states that the boundary of anti de Sitter space can be regarded as the spacetime for a quantum field theory The claim is that this quantum field theory is equivalent to the gravitational theory on the bulk anti de Sitter space in the sense that there is a dictionary for translating entities and calculations in one theory into their counterparts in the other theory For example a single particle in the gravitational theory might correspond to some collection of particles in the boundary theory In addition the predictions in the two theories are quantitatively identical so that if two particles have a 40 percent chance of colliding in the gravitational theory then the corresponding collections in the boundary theory would also have a 40 percent chance of colliding 55 6D 2 0 superconformal field theory edit Main article 6D 2 0 superconformal field theory nbsp The six dimensional 2 0 theory has been used to understand results from the mathematical theory of knots One particular realization of the AdS CFT correspondence states that M theory on the product space AdS7 S4 is equivalent to the so called 2 0 theory on the six dimensional boundary 49 Here 2 0 refers to the particular type of supersymmetry that appears in the theory In this example the spacetime of the gravitational theory is effectively seven dimensional hence the notation AdS7 and there are four additional compact dimensions encoded by the S4 factor In the real world spacetime is four dimensional at least macroscopically so this version of the correspondence does not provide a realistic model of gravity Likewise the dual theory is not a viable model of any real world system since it describes a world with six spacetime dimensions k Nevertheless the 2 0 theory has proven to be important for studying the general properties of quantum field theories Indeed this theory subsumes many mathematically interesting effective quantum field theories and points to new dualities relating these theories For example Luis Alday Davide Gaiotto and Yuji Tachikawa showed that by compactifying this theory on a surface one obtains a four dimensional quantum field theory and there is a duality known as the AGT correspondence which relates the physics of this theory to certain physical concepts associated with the surface itself 56 More recently theorists have extended these ideas to study the theories obtained by compactifying down to three dimensions 57 In addition to its applications in quantum field theory the 2 0 theory has spawned important results in pure mathematics For example the existence of the 2 0 theory was used by Witten to give a physical explanation for a conjectural relationship in mathematics called the geometric Langlands correspondence 58 In subsequent work Witten showed that the 2 0 theory could be used to understand a concept in mathematics called Khovanov homology 59 Developed by Mikhail Khovanov around 2000 Khovanov homology provides a tool in knot theory the branch of mathematics that studies and classifies the different shapes of knots 60 Another application of the 2 0 theory in mathematics is the work of Davide Gaiotto Greg Moore and Andrew Neitzke which used physical ideas to derive new results in hyperkahler geometry 61 ABJM superconformal field theory edit Main article ABJM superconformal field theory Another realization of the AdS CFT correspondence states that M theory on AdS4 S7 is equivalent to a quantum field theory called the ABJM theory in three dimensions In this version of the correspondence seven of the dimensions of M theory are curled up leaving four non compact dimensions Since the spacetime of our universe is four dimensional this version of the correspondence provides a somewhat more realistic description of gravity 62 The ABJM theory appearing in this version of the correspondence is also interesting for a variety of reasons Introduced by Aharony Bergman Jafferis and Maldacena it is closely related to another quantum field theory called Chern Simons theory The latter theory was popularized by Witten in the late 1980s because of its applications to knot theory 63 In addition the ABJM theory serves as a semi realistic simplified model for solving problems that arise in condensed matter physics 62 Phenomenology editOverview edit Main article String phenomenology nbsp A cross section of a Calabi Yau manifold In addition to being an idea of considerable theoretical interest M theory provides a framework for constructing models of real world physics that combine general relativity with the standard model of particle physics Phenomenology is the branch of theoretical physics in which physicists construct realistic models of nature from more abstract theoretical ideas String phenomenology is the part of string theory that attempts to construct realistic models of particle physics based on string and M theory 64 Typically such models are based on the idea of compactification l Starting with the ten or eleven dimensional spacetime of string or M theory physicists postulate a shape for the extra dimensions By choosing this shape appropriately they can construct models roughly similar to the standard model of particle physics together with additional undiscovered particles 65 usually supersymmetric partners to analogues of known particles One popular way of deriving realistic physics from string theory is to start with the heterotic theory in ten dimensions and assume that the six extra dimensions of spacetime are shaped like a six dimensional Calabi Yau manifold This is a special kind of geometric object named after mathematicians Eugenio Calabi and Shing Tung Yau 66 Calabi Yau manifolds offer many ways of extracting realistic physics from string theory Other similar methods can be used to construct models with physics resembling to some extent that of our four dimensional world based on M theory 67 Partly because of theoretical and mathematical difficulties and partly because of the extremely high energies beyond what is technologically possible for the foreseeable future needed to test these theories experimentally there is so far no experimental evidence that would unambiguously point to any of these models being a correct fundamental description of nature This has led some in the community to criticize these approaches to unification and question the value of continued research on these problems 68 Compactification on G2 manifolds edit In one approach to M theory phenomenology theorists assume that the seven extra dimensions of M theory are shaped like a G2 manifold This is a special kind of seven dimensional shape constructed by mathematician Dominic Joyce of the University of Oxford 69 These G2 manifolds are still poorly understood mathematically and this fact has made it difficult for physicists to fully develop this approach to phenomenology 70 For example physicists and mathematicians often assume that space has a mathematical property called smoothness but this property cannot be assumed in the case of a G2 manifold if one wishes to recover the physics of our four dimensional world Another problem is that G2 manifolds are not complex manifolds so theorists are unable to use tools from the branch of mathematics known as complex analysis Finally there are many open questions about the existence uniqueness and other mathematical properties of G2 manifolds and mathematicians lack a systematic way of searching for these manifolds 70 Heterotic M theory edit Because of the difficulties with G2 manifolds most attempts to construct realistic theories of physics based on M theory have taken a more indirect approach to compactifying eleven dimensional spacetime One approach pioneered by Witten Horava Burt Ovrut and others is known as heterotic M theory In this approach one imagines that one of the eleven dimensions of M theory is shaped like a circle If this circle is very small then the spacetime becomes effectively ten dimensional One then assumes that six of the ten dimensions form a Calabi Yau manifold If this Calabi Yau manifold is also taken to be small one is left with a theory in four dimensions 70 Heterotic M theory has been used to construct models of brane cosmology in which the observable universe is thought to exist on a brane in a higher dimensional ambient space It has also spawned alternative theories of the early universe that do not rely on the theory of cosmic inflation 70 References editNotes edit For a standard introduction to quantum mechanics see Griffiths 2004 The necessity of a quantum mechanical description of gravity follows from the fact that one cannot consistently couple a classical system to a quantum one See Wald 1984 p 382 From a technical point of view the problem is that the theory one gets in this way is not renormalizable and therefore cannot be used to make meaningful physical predictions See Zee 2010 p 72 for a discussion of this issue For an accessible introduction to string theory see Greene 2000 For example in the context of the AdS CFT correspondence theorists often formulate and study theories of gravity in unphysical numbers of spacetime dimensions Dimensional reduction is another way of modifying the number of dimensions This analogy is used for example in Greene 2000 p 186 For example see the subsections on the 6D 2 0 superconformal field theory and ABJM superconformal field theory A standard text is Peskin and Schroeder 1995 For an introduction to the applications of quantum field theory to condensed matter physics see Zee 2010 For a review of the 2 0 theory see Moore 2012 Brane world scenarios provide an alternative way of recovering real world physics from string theory See Randall and Sundrum 1999 Citations edit a b Duff 1996 sec 1 Zwiebach 2009 p 324 a b Becker Becker and Schwarz 2007 p 12 Wald 1984 p 4 Zee 2010 Parts V and VI Zwiebach 2009 p 9 Zwiebach 2009 p 8 Yau and Nadis 2010 Ch 6 Becker Becker and Schwarz 2007 pp 339 347 a b Becker Becker and Schwarz 2007 Zwiebach 2009 p 376 a b Duff 1998 p 64 Moore 2005 Yau and Nadis 2010 p 9 a b Yau and Nadis 2010 p 10 Yau and Nadis 2010 p 12 Yau and Nadis 2010 p 13 Wald 1984 p 3 van Nieuwenhuizen 1981 Nahm 1978 Cremmer Julia and Scherk 1978 a b c d e f Duff 1998 p 65 Duff 1998 Montonen and Olive 1977 a b Duff 1998 p 66 Sen 1994a Sen 1994b Hull and Townsend 1995 a b Duff 1998 p 67 Dirac 1962 Bergshoeff Sezgin and Townsend 1987 Duff et al 1987 Strominger 1990 Duff 1998 pp 66 67 Sen 1993 Witten 1995 Duff 1998 pp 67 68 Becker Becker and Schwarz 2007 p 296 a b Horava and Witten 1996a Horava and Witten 1996b Duff 1998 p 68 Gefter Amanda 2014 Trespassing on Einstein s Lawn A Father a Daughter the Meaning of Nothing and the Beginning of Everything Random House ISBN 978 0 345 531438 at 345 a b Banks et al 1997 a b Connes Douglas and Schwarz 1998 Connes 1994 p 1 Connes 1994 Nekrasov and Schwarz 1998 Seiberg and Witten 1999 a b Maldacena 1998 Klebanov and Maldacena 2009 Klebanov and Maldacena 2009 p 28 a b c Maldacena 2005 p 60 a b Maldacena 2005 p 61 Zwiebach 2009 p 552 Maldacena 2005 pp 61 62 Alday Gaiotto and Tachikawa 2010 Dimofte Gaiotto and Gukov 2010 Witten 2009 Witten 2012 Khovanov 2000 Gaiotto Moore and Neitzke 2013 a b Aharony et al 2008 Witten 1989 Dine 2000 Candelas et al 1985 Yau and Nadis 2010 p ix Yau and Nadis 2010 pp 147 150 Woit 2006 Yau and Nadis 2010 p 149 a b c d Yau and Nadis 2010 p 150 Bibliography edit Aharony Ofer Bergman Oren Jafferis Daniel Louis Maldacena Juan 2008 N 6 superconformal Chern Simons matter theories M2 branes and their gravity duals Journal of High Energy Physics 2008 10 091 arXiv 0806 1218 Bibcode 2008JHEP 10 091A doi 10 1088 1126 6708 2008 10 091 S2CID 16987793 Alday Luis Gaiotto Davide Tachikawa Yuji 2010 Liouville correlation functions from four dimensional gauge theories Letters in Mathematical Physics 91 2 167 197 arXiv 0906 3219 Bibcode 2010LMaPh 91 167A doi 10 1007 s11005 010 0369 5 S2CID 15459761 Banks Tom Fischler Willy Schenker Stephen Susskind Leonard 1997 M theory as a matrix model A conjecture Physical Review D 55 8 5112 5128 arXiv hep th 9610043 Bibcode 1997PhRvD 55 5112B doi 10 1103 physrevd 55 5112 S2CID 13073785 Becker Katrin Becker Melanie Schwarz John 2007 String theory and M theory A modern introduction Cambridge University Press ISBN 978 0 521 86069 7 Bergshoeff Eric Sezgin Ergin Townsend Paul 1987 Supermembranes and eleven dimensional supergravity PDF Physics Letters B 189 1 75 78 Bibcode 1987PhLB 189 75B doi 10 1016 0370 2693 87 91272 X S2CID 123289423 Candelas Philip Horowitz Gary Strominger Andrew Witten Edward 1985 Vacuum configurations for superstrings Nuclear Physics B 258 46 74 Bibcode 1985NuPhB 258 46C doi 10 1016 0550 3213 85 90602 9 Connes Alain 1994 Noncommutative Geometry Academic Press ISBN 978 0 12 185860 5 Connes Alain Douglas Michael Schwarz Albert 1998 Noncommutative geometry and matrix theory Journal of High Energy Physics 19981 2 003 arXiv hep th 9711162 Bibcode 1998JHEP 02 003C doi 10 1088 1126 6708 1998 02 003 S2CID 7562354 Cremmer Eugene Julia Bernard Scherk Joel 1978 Supergravity theory in eleven dimensions Physics Letters B 76 4 409 412 Bibcode 1978PhLB 76 409C doi 10 1016 0370 2693 78 90894 8 Dimofte Tudor Gaiotto Davide Gukov Sergei 2010 Gauge theories labelled by three manifolds Communications in Mathematical Physics 325 2 367 419 arXiv 1108 4389 Bibcode 2014CMaPh 325 367D doi 10 1007 s00220 013 1863 2 S2CID 10882599 Archived from the original on 2020 09 18 Retrieved 2017 07 04 Dine Michael 2000 TASI Lectures on M Theory Phenomenology Strings Branes and Gravity 545 612 arXiv hep th 0003175 doi 10 1142 9789812799630 0006 ISBN 978 981 02 4774 4 S2CID 17851652 Dirac Paul 1962 An extensible model of the electron Proceedings of the Royal Society of London A Mathematical and Physical Sciences 268 1332 57 67 Bibcode 1962RSPSA 268 57D doi 10 1098 rspa 1962 0124 S2CID 122728729 Duff Michael 1996 M theory the theory formerly known as strings International Journal of Modern Physics A 11 32 6523 41 arXiv hep th 9608117 Bibcode 1996IJMPA 11 5623D doi 10 1142 S0217751X96002583 S2CID 17432791 Duff Michael 1998 The theory formerly known as strings Scientific American 278 2 64 9 Bibcode 1998SciAm 278b 64D doi 10 1038 scientificamerican0298 64 Duff Michael Howe Paul Inami Takeo Stelle Kellogg 1987 Superstrings in D 10 from supermembranes in D 11 Nuclear Physics B 191 1 70 74 Bibcode 1987PhLB 191 70D doi 10 1016 0370 2693 87 91323 2 Gaiotto Davide Moore Gregory Neitzke Andrew 2013 Wall 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13889163 Khovanov Mikhail 2000 A categorification of the Jones polynomial Duke Mathematical Journal 1011 3 359 426 arXiv math 9908171 doi 10 1215 S0012 7094 00 10131 7 S2CID 119585149 Klebanov Igor Maldacena Juan 2009 Solving Quantum Field Theories via Curved Spacetimes PDF Physics Today 62 1 28 Bibcode 2009PhT 62a 28K doi 10 1063 1 3074260 Archived from the original on 2010 06 10 a href Template Cite journal html title Template Cite journal cite journal a CS1 maint bot original URL status unknown link Maldacena Juan 1998 The Large N limit of superconformal field theories and supergravity Advances in Theoretical and Mathematical Physics 2 2 231 252 arXiv hep th 9711200 Bibcode 1998AdTMP 2 231M doi 10 4310 ATMP 1998 V2 N2 A1 Maldacena Juan 2005 The Illusion of Gravity PDF Scientific American 293 5 56 63 Bibcode 2005SciAm 293e 56M doi 10 1038 scientificamerican1105 56 PMID 16318027 Archived from the original on 2013 11 10 a href Template Cite journal html title Template Cite journal cite journal a CS1 maint bot original URL status unknown link Montonen Claus Olive David 1977 Magnetic monopoles as gauge particles Physics Letters B 72 1 117 120 Bibcode 1977PhLB 72 117M doi 10 1016 0370 2693 77 90076 4 Moore Gregory 2005 What is a Brane PDF Notices of the AMS 52 214 Retrieved 6 August 2016 Moore Gregory 2012 Lecture Notes for Felix Klein Lectures PDF Retrieved 14 August 2013 Nahm Walter 1978 Supersymmetries and their representations Nuclear Physics B 135 1 149 166 Bibcode 1978NuPhB 135 149N doi 10 1016 0550 3213 78 90218 3 Nekrasov Nikita Schwarz Albert 1998 Instantons on noncommutative R4 and 2 0 superconformal six dimensional theory Communications in Mathematical Physics 198 3 689 703 arXiv hep th 9802068 Bibcode 1998CMaPh 198 689N doi 10 1007 s002200050490 S2CID 14125789 Peskin Michael Schroeder Daniel 1995 An Introduction to Quantum Field Theory Westview Press ISBN 978 0 201 50397 5 Randall Lisa Sundrum Raman 1999 An alternative to compactification Physical Review Letters 83 23 4690 4693 arXiv hep th 9906064 Bibcode 1999PhRvL 83 4690R doi 10 1103 PhysRevLett 83 4690 S2CID 18530420 Seiberg Nathan Witten Edward 1999 String Theory and Noncommutative Geometry Journal of High Energy Physics 1999 9 032 arXiv hep th 9908142 Bibcode 1999JHEP 09 032S doi 10 1088 1126 6708 1999 09 032 S2CID 668885 Sen Ashoke 1993 Electric magnetic duality in string theory Nuclear Physics B 404 1 109 126 arXiv hep th 9207053 Bibcode 1993NuPhB 404 109S doi 10 1016 0550 3213 93 90475 5 S2CID 18887335 Sen Ashoke 1994a Strong weak coupling duality in four dimensional string theory International Journal of Modern Physics A 9 21 3707 3750 arXiv hep th 9402002 Bibcode 1994IJMPA 9 3707S doi 10 1142 S0217751X94001497 S2CID 16706816 Sen Ashoke 1994b Dyon monopole bound states self dual harmonic forms on the multi monopole moduli space and SL 2 Z invariance in string theory Physics Letters B 329 2 217 221 arXiv hep th 9402032 Bibcode 1994PhLB 329 217S doi 10 1016 0370 2693 94 90763 3 S2CID 17534677 Strominger Andrew 1990 Heterotic solitons Nuclear Physics B 343 1 167 184 Bibcode 1990NuPhB 343 167S doi 10 1016 0550 3213 90 90599 9 van Nieuwenhuizen Peter 1981 Supergravity Physics Reports 68 4 189 398 Bibcode 1981PhR 68 189V doi 10 1016 0370 1573 81 90157 5 Wald Robert 1984 General Relativity University of Chicago Press ISBN 978 0 226 87033 5 Witten Edward 1989 Quantum Field Theory and the Jones Polynomial Communications in Mathematical Physics 121 3 351 399 Bibcode 1989CMaPh 121 351W doi 10 1007 BF01217730 MR 0990772 S2CID 14951363 Witten Edward 1995 String theory dynamics in various dimensions Nuclear Physics B 443 1 85 126 arXiv hep th 9503124 Bibcode 1995NuPhB 443 85W doi 10 1016 0550 3213 95 00158 O S2CID 16790997 Witten Edward 2009 Geometric Langlands from six dimensions arXiv 0905 2720 hep th Witten Edward 2012 Fivebranes and knots Quantum Topology 3 1 1 137 arXiv 1101 3216 doi 10 4171 QT 26 S2CID 119248828 Woit Peter 2006 Not Even Wrong The Failure of String Theory and the Search for Unity in Physical Law Basic Books p 105 ISBN 0 465 09275 6 Yau Shing Tung Nadis Steve 2010 The Shape of Inner Space String Theory and the Geometry of the Universe s Hidden Dimensions Basic Books ISBN 978 0 465 02023 2 Zee Anthony 2010 Quantum Field Theory in a Nutshell 2nd ed Princeton University Press ISBN 978 0 691 14034 6 Zwiebach Barton 2009 A First Course in String Theory Cambridge University Press ISBN 978 0 521 88032 9 Popularization editBBC Horizon Parallel Universes 2002 feature documentary by BBC Horizon episode Parallel Universes focuses on the history and emergence of M theory and scientists involved 1 PBS org NOVA The Elegant Universe 2003 Emmy Award winning three hour miniseries by Nova with Brian Greene adapted from his The Elegant Universe book original PBS broadcast dates October 28 8 10 p m and November 4 8 9 p m 2003 See also editF theory MultiverseExternal links editSuperstringtheory com The Official String Theory Web Site created by Patricia Schwarz References on string theory and M theory for the layperson and expert Not Even Wrong Peter Woit s blog on physics in general and string theory in particular M Theory Edward Witten 1995 Witten s 1995 lecture introducing M Theory Retrieved from https en wikipedia org w index php title M theory amp oldid 1207883365, wikipedia, wiki, book, books, library,

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