Introduction to String Theory

Table of Contents

1. Introduction
2. Motivation for String Theory
3. Particles as One-Dimensional Strings
4. Open vs Closed Strings
5. Vibrational Modes and Mass Spectrum
6. The String Action: Nambu–Goto and Polyakov
7. Quantization of the String
8. Conformal Symmetry and Worldsheet Dynamics
9. Critical Dimensions
10. Bosonic String Theory
11. Superstrings and Supersymmetry
12. Type I, Type IIA, Type IIB, Heterotic Strings
13. D-branes and Open String Endpoints
14. T-duality and Compactification
15. Extra Dimensions and Calabi–Yau Spaces
16. Anomalies and Consistency
17. String Interactions and Vertex Operators
18. Moduli Space and Vacuum Selection
19. String Coupling and Dilaton
20. String Field Theory
21. Dualities in String Theory
22. M-theory and Unification
23. Black Holes and Holography
24. String Theory and Quantum Gravity
25. Conclusion

1. Introduction

String theory is a candidate for a unified theory of all fundamental forces, including gravity. It proposes that the fundamental constituents of nature are not point-like particles but one-dimensional objects — strings — whose different vibrational modes correspond to different particles.

2. Motivation for String Theory

The main motivations include:

• Quantum gravity
• Unification of forces
• Natural inclusion of gauge theories and gravity
• Resolution of ultraviolet divergences in quantum field theory
• Rich mathematical structure with deep connections to geometry and topology

3. Particles as One-Dimensional Strings

In string theory, each fundamental particle corresponds to a specific vibrational mode of a string. The mass and spin of the particle are determined by how the string vibrates. These strings can be:

• Open strings: with two endpoints
• Closed strings: forming loops

4. Open vs Closed Strings

• Open strings can end on D-branes and give rise to gauge fields.
• Closed strings include the graviton, the quantum of gravity.

The interaction of strings is smooth and avoids the divergences found in point-particle theories.

5. Vibrational Modes and Mass Spectrum

Different vibrational patterns represent different particles. For instance:

• Lowest mode of closed strings: graviton
• Massless vector mode of open strings: photon
  Higher modes correspond to massive excitations.

6. The String Action: Nambu–Goto and Polyakov

Two formulations of the string action:

• Nambu–Goto Action:
  \[
  S = -T \int d^2 \sigma \, \sqrt{-\det h_{\alpha\beta}}
  \]
  where \( h_{\alpha\beta} = \partial_\alpha X^\mu \partial_\beta X_\mu \)
• Polyakov Action:
  \[
  S = -\frac{T}{2} \int d^2 \sigma \sqrt{-\gamma} \gamma^{\alpha\beta} \partial_\alpha X^\mu \partial_\beta X_\mu
  \]

The Polyakov action is more suitable for quantization.

7. Quantization of the String

Quantization involves promoting the coordinates \( X^\mu(\sigma, \tau) \) to operators. There are two approaches:

• Canonical quantization
• Path integral quantization

Quantization leads to discrete mass spectra and conditions like the Virasoro constraints.

8. Conformal Symmetry and Worldsheet Dynamics

The 2D worldsheet theory enjoys conformal symmetry, which allows consistent quantization. The energy-momentum tensor must vanish, leading to constraints on physical states.

9. Critical Dimensions

Quantum consistency requires spacetime to have a specific number of dimensions:

• Bosonic string theory: 26 dimensions
• Superstring theory: 10 dimensions

This arises from cancellation of conformal anomalies.

10. Bosonic String Theory

The simplest string theory:

• Includes only bosons
• Suffers from a tachyon (unstable particle)
• Lacks fermions and supersymmetry
• Important pedagogical model

11. Superstrings and Supersymmetry

Superstrings include both bosonic and fermionic degrees of freedom. Supersymmetry ensures:

• Cancellation of tachyons
• Consistency with quantum mechanics
• Natural incorporation of gravity

12. Type I, Type IIA, Type IIB, Heterotic Strings

Five consistent superstring theories:

• Type I: open and closed, unoriented, SO(32)
• Type IIA: closed, non-chiral, 10D
• Type IIB: closed, chiral, 10D
• Heterotic SO(32) and E₈×E₈

These are related by dualities.

13. D-branes and Open String Endpoints

D-branes are dynamical objects on which open strings can end. They carry charges, support gauge theories, and are crucial in string phenomenology and gauge/gravity duality.

14. T-duality and Compactification

Compactifying extra dimensions leads to dualities:

• T-duality: exchanges winding and momentum modes
• Compactification on circles or Calabi–Yau spaces allows 4D effective theories

15. Extra Dimensions and Calabi–Yau Spaces

To recover 4D physics, extra dimensions must be compactified. Calabi–Yau manifolds preserve supersymmetry and determine the properties of the low-energy theory.

16. Anomalies and Consistency

Only anomaly-free theories are consistent. The Green–Schwarz mechanism cancels anomalies in 10D superstrings, especially in Type I and heterotic strings.

17. String Interactions and Vertex Operators

Strings interact by splitting and joining. These interactions are described by vertex operators in the conformal field theory of the worldsheet.

18. Moduli Space and Vacuum Selection

String theory has many vacua characterized by moduli:

• Shape and size of extra dimensions
• Background fluxes

Understanding vacuum selection is key to connecting with real-world physics.

19. String Coupling and Dilaton

The string coupling \( g_s \) is determined by the VEV of the dilaton field \( \phi \):

\[
g_s = e^{\langle \phi \rangle}
\]

Perturbative string theory is an expansion in \( g_s \).

20. String Field Theory

An attempt to describe string theory non-perturbatively. It involves a field theory where the basic variables are entire string configurations rather than point fields.

21. Dualities in String Theory

String theories are connected via:

• T-duality: spatial compactification
• S-duality: strong-weak coupling
• U-duality: unified dualities

This suggests an underlying theory unifying all strings.

22. M-theory and Unification

M-theory is a proposed 11D theory that unifies the five 10D superstring theories. Its low-energy limit is 11D supergravity. Its full formulation is still unknown.

23. Black Holes and Holography

String theory provides microscopic models of black holes. The AdS/CFT correspondence relates string theory in AdS space to a conformal field theory on its boundary — a realization of the holographic principle.

24. String Theory and Quantum Gravity

String theory naturally incorporates quantum gravity:

• The graviton emerges from closed string states
• Ultraviolet finiteness resolves issues of perturbative gravity
• Predicts phenomena like strings, branes, extra dimensions

25. Conclusion

String theory offers a compelling and mathematically rich framework for unifying all fundamental forces, including gravity. While lacking experimental confirmation, it has yielded profound insights into quantum gravity, black holes, and dualities. Its continuing development bridges gaps between quantum field theory, geometry, and high-energy physics, and may ultimately lead to a deeper understanding of the fundamental structure of reality.