Why 10 Dimensions Why 10 11 Or 26 Physical Dimensions In String

This is one of the questions discussed by Michio Kaku in his book Hyperspace. That book is an attempt to translate the mathematics of hyperspace theory into ordinary language that can be understood by a wide audience. This article is devoted to the same goal, leaving the details of the mathematics to the hyperspace theory article.

Kaku traces the number of dimensions to Srinivasa Ramanujan's modular functions, but this article will start with some fundamentals and work its way into the mathematics. The goal here is to use ordinary language when possible and be careful to clearly define jargonistic terms that come to us from the mathematics and physics of hyperspace.

2 Foundation: let's be clear what we are talking about

2.1 Spatial dimensions

2.2 String theory

String theory is a proposed physical theory. There are several versions or types of string theory. Attempts are being made to discover which version of the theory (if any) is in agreement with observations of the physical universe. All string theories include the idea of a hyperspace of more than three spatial dimensions. The "extra" spatial dimensions are theoretically "compact" or "collapsed" dimensions. This means that they are not as extended in space as the three familiar spatial dimensions. The collapsed dimensions are too small to observe directly. It is not clear how many collapsed dimensions are required for a string theory that is in best agreement with observations of the physical universe, but mathematical constraints currently favor string theories with 10, 11, or 26 dimensions.

2.3 Hyperspace

What explanatory power comes from including "extra" compact dimensions in a physical theory? Since the time of the first written speculations about the possible existence of an atomFor alternative meanings see atom (disambiguation). An atom is a microscopic structure found in all ordinary matter around us. Atoms are composed of 3 types of subatomic particles: electrons, which have a negative charge; protons, which have a positive ch, a goal of physics has been to understand the fundamental physical components of the universe. Unfortunately, many subatomic particles (each subject to some combination of the four fundamental forces) have been observed and so attention has turned to theoretical attempts to describe the diversity of subatomic particles in an elegant physical theory. Why are there so many different particles? Why do they have the physical properties that they are observed to have? Have things always been this way or have the properties of subatomic particle changed since the formation of our universe? Do they continue to change? Some theoretical physicists are exploring the idea that the diversity of subatomic particle can be accounted for in terms of symmetry breakingSpontaneous symmetry breaking in physics takes place when a system that is symmetric with respect to some Lie group goes into a vacuum state that is not symmetric. At this point the system no longer appears to behave in a symmetric manner. It is a phenome. Maybe under the high energy conditions of the early universe all particles were initially indistinguishable, a condition called supersymmetry. As the universe cooled, some spatial dimensions compacted and particles distributed themselves among the available stable energy states provided by three extended spatial dimensions and six or more compact dimensions. This line of reasoning suggests that it might be possible to explain the diversity of subatomic particles and fundamental forces in terms of a theory of how an original hyperspace "broke" into two "parts"; our extended 4 dimensional space-time and an "invisible" group of several additional compact spatial dimensions. String theory is a popular hyperspace theory in part because it easily accommodates gravity in terms of a spin=2 graviton.

2.4 Strings

Within string theory, a string is a one-dimensional object. These hypothetical one-dimensional strings are very small, on the order of the Planck length (about 1.6 × 10^-35 meters ). String theory explores the implications of strings that are either open (they have free ends) or closed (they form loops and have no free ends). Within string theory, the stable vibrational states of strings are taken to correspond to physical particles like the graviton. When a string moves through spacetime it sweeps out a 2-dimensional surface called a worldsheet. One of the features of string theory that has appeal to physicists is that when particle interactions are thought of in terms of interacting worldsheets it is possible to overcome some of the mathematical problems confronted when considering particles as points.

3 Recap before getting to the mathematics

String theory grew out of attempts to find a simple and elegant way to account for the diversity of particles and forces observed in our universe. The starting point was to assume that there might be a way to account for that diversity in terms of a single fundamental physical entity (string) that can exist in many "vibrational" states. The various allowed vibrational states of string could theoretically account for all the observed particles and forces. Unfortunately, there are many potential string theories and no simple way of finding the one that accounts for the way things are in our universe. One way to make progress is to assume that our universe arose through a process involving an initial hyperspace with supersymmetry that, upon cooling, underwent a unique process of symmetry breaking. The symmetry breaking process resulted in conventional 4 dimensional extended space-time AND some combination of additional compact dimensions. What can mathematics tell us about how many additional compact dimensions might exist?

3.1 Modular functions

Modular functions are a subclass of the more general modular forms. An example of a modular function is the Dedekind eta function, given by the infinite product

Like other modular forms, this function is defined over the domain of complex numbers z = x + iy where x and y are real and y > 0.

Remember that for complex numbers i is the square root of −1. In the function, e is Euler's number (2.71828....) and is pi (3.14159....).

3.2 What is the connection between modular functions and string theory?

Modular functions are used in the mathematical analysis of Riemann surfaces. Riemann surface theory is relevant to describing the behavior of strings as they move through space-time. When strings move they maintain a kind of symmetry called " conformal invariance"

Conformal invariance (also called " scale invariance") is related to the fact that points on the surface of a string's world sheet need not be evaluated in a particular order. As long as all points on the surface are taken into account in any consistent way, the physics should not change. Equations of how strings must behave when moving involve the Ramanujan function.

3.3 Ramanujan modular functions

1968 "Veneziano model" Euler beta function describes the strong nuclear force.

When a string moves in space-time by splitting and recombining (see worldsheet diagram at right), a large number of mathematical identities must be satisfied. These are the identities of Ramanujan's modular function.

The KSV loop diagrams of interacting strings can be described using modular functions.

The "Ramanujan function" (an elliptic modular function? satisfies the need for "conformal symmetry") has 24 "modes" that correspond to the physical vibrations if a bosonic string.

When the Ramanujan function is generalized, 24 is replaced by 8 (8 + 2 = 10) for fermion strings.

4 See also

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1 Why 10, 11, or 26 physical dimensions in string theory?