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Claimed by Choux Ruby Kim Spring 2025
'''Claimed by Choux Ruby Kim Spring 2025'''


==Introduction to String Theory==
'''Short Description of Topic:'''
String theory is a theoretical framework to address the shortcomings of Einstein's theory of general relativity and quantum physics - two primary tools for understanding modern physics. String theory is often referred to as the ''theory of everything'' - a just identification given its ability to bridge the gap between gravity and quantum physics. The theory of general relativity and quantum mechanics are the primary, established explanations for how the universe works on a macroscopic and microscopic scale, respectively. However, these two physical explanations address different ends of the spectrum of matter in terms of relativistic effects, fundamental forces, and physical properties. String theory provides explanations where modern physics fails. These fields of interest include the early universe, black holes, and atomic nuclei. To understand the purpose of the ''theory of everything,'' it is vital to have a sound understanding of general relativity's purpose and the role of relativistic quantum mechanics - that is, in terms of gravitational effects on the matter, the fundamental physics of the universe. General relativity serves an essential purpose in determining the gravitational effects on planetary-sized objects and observable particles. However, the "gap" in Einstein's theory lies within its inability to address gravity's impact on elementary particles. General relativity successfully explains macro-scaled particles, given its ability to incorporate gravitational effects in its theoretical and mathematical foundation. However, the same cannot be said for elementary particles. Accordingly, these elementary particles require relativistic quantum mechanics to explain their physical properties, assuming that gravity's effect on this scale is negligible. This is the disconnect between modern physics' primary schools of thought. As a result, the purpose of the string theory is realized in its ability to successfully incorporate gravitational effects, independent of the scale of particles. Thus, the ''theory of everything'' emerged.
: ''String theory is a framework in which the fundamental constituents of the universe are modeled as tiny one-dimensional objects called “strings.” Their different vibrational modes correspond to different particles, including the graviton. By unifying quantum mechanics and gravity, string theory aspires to be a “Theory of Everything,” albeit still awaiting direct experimental validation.''


''See reference 3.''
__TOC__


String theory is a theory that utilizes and brings together electromagnetism, the weak force, gravity, and the strong forces. These are the four fundamental forces of nature. The particles that are identified within the string theory all have a particular vibration pattern of a 1D object, a string. String theory falls under the category of quantum theory and is an example of (the quantum) theory of gravity. String theory is highly constrained due to it being confined by the parameters of 1D, that parameter being the string length. While string theory is far from being complete, efforts from modern research in string theory have to advance our current understanding of other related fields of study like black hole physics, algebraic geometry, cosmology, and condensed matter physics.
== The Main Idea ==
String theory posits that the fundamental particles of nature (electrons, quarks, photons, etc.) can be seen as different vibrational states of incredibly small ''strings.'' Rather than point-like entities, these one-dimensional strings can oscillate in many distinct ways. Each vibrational pattern gives rise to a particle with specific mass, spin, and charge. Notably, one vibrational mode matches the graviton—a spin-2 massless particle—thereby naturally including gravity in a quantum framework.<ref name=\"WikiString\">[[#References|[6]]] String theory is a theoretical framework in which the point-like particles of particle physics are replaced by one-dimensional objects called strings…</ref>


''See reference 5.''
Modern physics rests on two pillars:
* '''General Relativity''' (describing gravity at large scales)
* '''Quantum Field Theory''' (describing subatomic particles and the other forces)


===Relevant Mathematical Equations (Bekenstein-Hawking Formula)===
These two theories do not unify seamlessly in extreme regimes (e.g., near black hole singularities or the big bang). String theory seeks to reconcile them by treating gravity as an emergent phenomenon arising from string interactions, with additional spatial dimensions compactified to scales far below direct detection.<ref name=\"WikiBH\">[[#References|[8]]] Summarizes black hole entropy and Strominger–Vafa derivation…</ref>


:<math>S= \frac{c^3kA}{4\hbar G}</math>
=== A Mathematical Model ===
String theory provides several key equations and relationships:


The Bekenstein-Hawking formula for the entropy of a black hole, shown above, provides a theoretical value for the entropy of a black hole. While this equation provides an expected value that correlates to the entropy of a black hole, according to macroscopic features resulting from its microstates, the formula lacks a derivation for a black hole's entropy-based on counting microstates on a quantum scale with consideration of gravitational aspects. In 1996, Andrew Strominger and Cumrun Vafa provided a derivation for a black hole's entropy with respect to the number of microstates of a black hole and in terms of the string theory. The results obtained from these calculations provided solutions matching Berkenstein and Hawking's original formula. Thus, string theory was validated as a mode of quantum gravity.  
;1) Bekenstein–Hawking Black Hole Entropy
:<math> S_{\text{BH}} = \frac{k_B \, c^3 \, A}{4\, \hbar\, G} \, ,</math>
where:
* \(A\) is the horizon area,
* \(G\) is the gravitational constant,
* \(c\) is the speed of light,
* \(k_B\) is Boltzmann’s constant,
* \(\hbar\) is Planck’s constant.


See ''reference 1''.
This formula connects gravitational, quantum, and thermodynamic aspects of black holes. In 1996, string theorists reproduced this entropy by counting microstates of D-branes, providing a significant check on string theory’s internal consistency.<ref name=\"WikiBH\" />


===Theoretical Foundation===
;2) String Vibrational Modes (e.g., Closed String Mass Formula)
:<math> M^2 \;=\; \frac{2}{\alpha'} \bigl(N + \tilde{N} - 2\bigr)\, ,</math>
where \(N\) and \(\tilde{N}\) are the integer excitation numbers (left- and right-moving modes), and \(\alpha'\) relates to the string tension. Different integer combinations yield different particle masses, including a massless spin-2 mode identified with the graviton.<ref name=\"BrilliantMass\">[[#References|[22]]] Brilliant.org, “Mass spectrum of the closed string.”</ref>


String theory is founded on the basis that elementary particles are components of microscopically small strings - to the degree that technology is not available to visualize. A valid and common depiction of strings lined with elementary particles is a visualization of these identical particles laying on a violin string. String theory advocates propose that elementary particles are believed to be in "excited" states due to vibrations in these strings. This is significant given the bending of spacetime and the existence of black holes and wormholes - solutions to Einstein's equations that are not explained entirely by quantum physics or general relativity in their own right. On a theoretical basis, string theory provides solutions based on gravity acting on elementary particles (theories of quantum gravity), a unification of quantum mechanics, and  Einstein's theory of general relativity.  
;3) Compactification
Many consistent string theories live in 10 spacetime dimensions. To appear 4-dimensional at low energies, the extra 6 dimensions are curled up (compactified) into a tiny geometric shape (e.g., a Calabi–Yau manifold or an orbifold). A simple version is a circle \(S^1\) with radius \(R\), leading to Kaluza–Klein momentum quantization:
:<math> p_n = \frac{n \hbar}{R}\, , \quad n \in \mathbb{Z}.</math>
Such quantization means, from a 4D perspective, that there is an infinite “tower” of increasingly massive excitations, each separated by \(1/R\).<ref name=\"KKCircle\">[[#References|[14]]] Momentum quantization under periodic boundary conditions.</ref>


[[File:String Theory.jpg]]
=== A Computational Model ===
To visualize the idea of different vibrational modes on a “string,” we can implement a simplified **vibrating string** simulation in GlowScript (VPython). While not a quantum simulation, it neatly illustrates how a single fundamental system (the string) produces multiple harmonic patterns. Each mode corresponds to a distinct standing wave—an analogy for how string theory’s quantum modes yield different particles.


''See reference 2''.
You can embed or link to a Trinket-based GlowScript program. For example:
''Oscillations of the closed string.''


==History of String Theory==
<syntaxhighlight lang=\"python\">
GlowScript 3.2 VPython


The origin of string theory came from particle physics back in the 1960s. A series of experiments related to the interaction of the strong forces showed there are infinite hadrons, and their masses and spins become more prominent and higher. They are called resonance states because most of the particles are unstable particles. If an infinite number of particles engage in the interaction, the particle-particle scattering amplitude satisfies a property: duality. Gabriele Veneziano, an Italian physicist, found a simple function that helps duality. This is known as the Veneziano formula. While no experiment could fully satisfy his formula, researchers soon discovered that the formula could be naturally explained as the string and the string's scattering amplitude. So, string theory did not originate from one or a series of experiments but rather from a formula.
# A classical 1D string with fixed ends,
# demonstrating standing wave patterns.


[[File:Venezianformula.png]]
import numpy as np
''Veneziano formula''


The theory of relativity comes into play when talking about string theory. Einstein's theory of relativity can be discussed and considered as string theory's origin. The space-time view of general relativity reformed Newton's space-time view due to the limitations of Newton’s space-time view. Einstein replaced Newton's absolute time and space causality with the law of relativity.  
L = 1.0    # length of the string
Those who believe in the theory of string theory believe gravity has been quantized (successfully).  It is debated that there is no successful theory of quantum gravity, but it is still acknowledged to an extent the success of string theory.
N = 50    # number of mass points
dx = L/(N-1)
tension = 10.0
mass = 0.02
k = tension/dx
dt = 0.0005
y = [0]*(N)    # vertical displacements
v = [0]*(N)     # velocities


String theory was first proposed to describe strong forces. The quark model and quantum chromodynamics were not widely accepted as theories explaining strong forces.
# Create spheres for visualization
Based on current understanding, the meson comprises quarks and antiquarks due to strong forces. However, in string theory, it is characterized as an open string. The ends of the string correspond to quarks and antiquarks, and the string itself corresponds to the strong pulling force created between the two forces. Quantum chromodynamics is relatively prosperous due to string theory’s inability to explain many phenomena of strong forces. Due to this, string theory was abandoned by most physicists for some time.  
masses = []
for i in range(N):
    ball = sphere(pos=vector(i*dx,0,0), radius=0.01)
    masses.append(ball)


According to popular saying, the string itself has undergone two revolutions. After the first revolution, string became popular. Some string theory experts, in1985, shortly after the first revolution, believed that the ultimate theory was in sight. Some people say that this is the Theory of Everything (TOE). John Ellis, director of the European Nuclear Center's Theory Department, is a representative of this school. These people were overly optimistic at that time, or that their understanding of strings was more superficial. Schwarz and Green 1980 developed the first superstring theory model. This model dealt with open string vibrations in ten-dimensional space, which can be connected or broken.
# Pluck the string in the middle
y[int(N/2)] = 0.1
The first superstring revolution in 1984 was led by Schwarz and Green’s discovery that there is a symmetry capable of eliminating all distortion and infinity. This brought forth a new candidate for the theory of everything. He brought attention back to string theory and led physicists to pay more attention to string theory.


The second superstring revolution in 1994 brought forth many questions. There were five different versions and explanations revolving around string theory at the time.
while True:
The traditional methods scientists use could not be used to prove the authenticity of string theory. This led to the desire for new techniques and technologies. The claim that string theory is the theory of everything raises the question of why there are five different versions; they’re like plotholes. Also, suppose point particles can be regarded as string vibrations. What is the reason they cannot be caused by two-dimensional membranes, three-dimensional squares, or higher-dimensional physical vibrations? In the early 1990s, physicists started to understand the duality between versions. Edward Witten made the most notable breakthrough in 1995, where he unified the various dualities under the eleven-dimensional M theory
    rate(1000)
    # Update the vertical displacements using finite difference
    for i in range(1, N-1):
        a = k*(y[i+1]-2*y[i]+y[i-1])/mass
        v[i] += a*dt
    for i in range(N):
        y[i] += v[i]*dt
    # Enforce fixed ends
    y[0] = 0
    y[N-1] = 0
    v[0] = 0
    v[N-1] = 0


==Potential Discoveries and Applications==
    # Update visuals
    for i in range(N):
        masses[i].pos.y = y[i]
</syntaxhighlight>


When you run this code (e.g., on <nowiki>https://trinket.io/glowscript/</nowiki>), you see a discretized string. Different initial conditions (e.g., plucking at different points or shapes) can excite different standing-wave modes. Each stable pattern is analogous to how quantum strings have distinct vibrational excitations interpreted as different particles.


== Examples ==


===Wormholes===
=== Simple: Compactification to {{math|S^1}} ===
The potential usage of string theory is to provide the quantum gravitational solutions that Einstein's theory of general relativity fails to recognize at the center of black holes or wormholes. This inability is due to its lack of consideration of quantum forces alongside gravity. String theory is integral to discovering wormholes' (derived solutions to Einstein's equations) level of stability. Specifically, string theory's quantum forces and gravity enables the determination of the radiative effects and stability of this unexplained astrophysical phenomenon. In conclusion, these recently gained understandings of string theory may ultimately yield answers to questions such as...
'''Scenario:''' A 5D spacetime with coordinates \((t, x, y, z, w)\), where \(w\) is compactified into a circle of circumference \(2\pi R\).


1. Given Kerr wormholes and their potential to connect distant points in the universe, is it theoretically feasible to use these solutions to travel vast lengths through the universe?
# ''Set periodic boundary conditions:'' \(w \sim w + 2\pi R\). A free particle in the extra dimension sees quantized momentum \(p = \frac{n\hbar}{R}\).
# ''View from 4D:'' Each integer \(n\) is a mode with effective mass \(\frac{n\hbar}{Rc}\). Thus a single 5D particle becomes an infinite Kaluza–Klein tower of 4D particles.
# ''Interpretation:'' If \(R\) is extremely small, these massive modes are too heavy to observe at today’s energies, making extra dimensions effectively hidden.<ref name=\"KKCircle\" />


''See reference 2''.
=== Middling: Orbifold Compactification ({{math|S^1/{{Z}}<sub>2</sub>}}) ===
'''Scenario:''' Identify opposite points on a circle, halving it to an interval \([0, \pi R]\) with reflections at the boundaries.


[[https://sirxemic.github.io/wormhole/ Wormhole Simulation: Unknown Source]]
# ''Construction:'' Start with a circle of length \(2\pi R\). Impose {{math|w&#126;-w}}. The points \(0\) and \(\pi R\) become “fixed points” of the reflection symmetry.
# ''Field Modes:'' Even fields satisfy Neumann boundaries at the endpoints, odd fields have Dirichlet (zero at endpoints). This “projection” can remove unwanted modes.
# ''Applications in String Theory:'' Orbifolds create “branes” at fixed points and can break large gauge symmetries into smaller ones—useful for model building (reducing extra particles).


===Computational Models===
=== Difficult: Black Hole Entropy Counting ===
'''Could not find any good PHET simulations or interactive models other than the wormhole that would help achieve a better understanding on the topic.'''
'''Scenario:''' Strominger and Vafa (1996) counted microstates of certain extremal black holes (5D with D1-, D5-branes, and momentum).


[[http://aitp-conference.org/2018/slides/MD.pdf Computational Exploration of String Theory]]
# ''D-brane description at weak coupling:'' The black hole is modeled by a bound state of D1-branes and D5-branes with momentum excitations. One counts the ways to distribute momentum quanta among vibrational modes of the D-brane system.
# ''Statistical Entropy:'' The result for large charges matches <math>S = 2\pi \sqrt{N_1 N_5 N_P}</math>, exactly reproducing the Bekenstein–Hawking formula in the strong-coupling (black hole) limit.
# ''Significance:'' Demonstrates that string theory has the correct microscopic degrees of freedom to account for black hole entropy, a milestone in quantum gravity research.<ref name=\"WikiBH\" />


== Connectedness ==
String theory’s scope is broad:
* '''Cosmology and Astrophysics:''' Explains early universe (brane inflation), cosmic strings, black hole thermodynamics. 
* '''Particle Physics:''' A candidate for unifying the Standard Model forces with gravity; naturally includes supersymmetry and extra dimensions. 
* '''Mathematics and Computation:''' Calabi–Yau geometry, mirror symmetry, new insights into enumerative geometry, quantum information (holography, entanglement). 
* '''Quantum Information & Holography:''' AdS/CFT duality links spacetime geometry to quantum entanglement in strongly coupled systems. 
* '''No Immediate Industrial Application:''' Yet spin-offs include advanced mathematical tools, HPC algorithms for analyzing large dimensional “landscapes,” and cross-pollination with quantum computing.


[[File:w-003.jpg]]
== History ==
[[File:wormhole3.png]]
Below is a brief historical timeline:
[[File: strigntheory.png]]


==Examples==
;1968–1970: Dual Resonance Model
:Gabriele Veneziano’s formula fits strong-interaction scattering data. Then Nambu, Nielsen, Susskind interpret it as arising from vibrating strings.<ref name=\"TimelineEarly\">[[#References|[52]]]</ref>


'''Example One'''
;1974: Gravity in String Theory
:Schwarz, Scherk, and Yoneya identify a massless spin-2 state—interpreted as the graviton—prompting the claim that string theory can unify quantum physics and gravity.


Question:  
;1984–1985: First Superstring Revolution
Explain how the circle S^1 is equivalent to the real line R with the identification x ~ x + 2πR
:Green–Schwarz anomaly cancellation. Witten, Candelas, Horowitz, Strominger show Calabi–Yau compactifications can yield realistic 4D physics. Explosion of interest in superstrings.<ref name=\"TimelineEarly\" />


Solution:
;1995: Second Superstring Revolution
The given identification identifies 0 with 2πR. All points x between 0 and 2πR are identified with points 2πR with a magnitude larger than 2πR. The identification has made the real line periodic with period 2πR. One can think of this as identifying the interval [0,2πR) with the circumference of the circle of radius 1.
:Witten proposes all five superstring theories + 11D supergravity are unified via M-theory. D-branes (Polchinski) become central to non-perturbative dualities.
In this case, the compact space S^1 is found by taking the quotient of the non-compact space R by the discrete symmetry group Z, the group of integers. This corresponds to the fact that points shifted by integer multiples of 2πR are identified.


[[https://brilliant.org/wiki/string-theory/ ''Reference 5'']]
;1996: Black Hole Entropy
:Strominger–Vafa counting of D-brane states reproduces the Bekenstein–Hawking formula. Big success for string theory’s microstate approach to quantum gravity.


;1997–1998: AdS/CFT Correspondence (Holography)
:Maldacena’s conjecture links a 5D gravitational theory (Type IIB on AdS<sub>5</sub> × S<sub>5</sub>) to a 4D gauge theory, opening new vistas in quantum gravity, QCD, and condensed matter.


'''Example Two'''
;2000s–2020s: String Landscape & Applications
:Many possible “vacua,” possibly {{math|10<sup>500</sup>}} or more, complicating direct phenomenological predictions. Meanwhile, string insights drive progress in quantum information, black hole physics, etc.


Question:
== See also ==
Explain how the complex plane C with the identification z∼e^(2πi/3z defines an orbifold compactification.
* [[M-Theory]]
* [[Quantum_Gravity]]
* [[Extra_Dimensions]]
* [[Supergravity]]
* [[Black_Hole_Entropy]]
* [[AdS_CFT_Correspondence]]
* [[Big_Bang_Theory]] (cosmology context)
* [[Elementary_Particles_and_Particle_Physics_Theory]]
* [[Quantum_Theory]]


Solution:
== Further reading ==
The given identification identifies points in the complex plane with themselves rotated by 2π/3 and by 4π/3. The rotation of the complex plane about the origin leaves the origin fixed, so there exists an orbifold singularity at the origin. The resulting space is a cone with an opening angle 2π/3. Since the rotations of the complex plane by 2π/3 correspond to a representation of the cyclic group Zsubscript3 of order three, this space is called the C/Zsubscript3 orbifold.
* Greene, B. ''The Elegant Universe.'' (W.W. Norton, 1999). 
* Zwiebach, B. ''A First Course in String Theory.'' (Cambridge University Press, 2009). 
* Green, M.B., Schwarz, J.H., & Witten, E. ''Superstring Theory.'' Vol. 1 & 2 (Cambridge University Press, 1987). 
* Becker, K., Becker, M., & Schwarz, J. ''String Theory and M-Theory: A Modern Introduction.'' (Cambridge University Press, 2007).
* Kaku, M. ''Introduction to Superstrings and M-Theory.'' (Springer, 1999). 
* Polchinski, J. ''String Theory: Volumes 1 & 2.'' (Cambridge University Press, 1998). 
* Susskind, L. ''The Cosmic Landscape: String Theory and the Illusion of Intelligent Design.'' (Little, Brown, 2005).


[[https://brilliant.org/wiki/string-theory/ ''Reference 5'']]
== External links ==
* [https://superstringtheory.com superstringtheory.com – The Official String Theory Website] 
* [https://trinket.io/glowscript GlowScript/Trinket – Interactive VPython for classical string oscillations] 
* [https://ocw.mit.edu/courses/8-821-string-theory-fall-2008/ MIT OpenCourseWare on String Theory] 
* [https://www.youtube.com/results?search_query=maldacena+string+theory Lectures on AdS/CFT and String Theory by Juan Maldacena] 
* [https://arxiv.org/ archive] – Preprint repository with thousands of papers on string theory, cosmology, quantum gravity, etc. 
* [https://plato.stanford.edu/entries/string-theory/ Stanford Encyclopedia of Philosophy: String Theory] – Philosophical overview. 


== References ==
<references>
<ref name=\"WikiString\">Wikipedia: “String theory – Overview.” (accessed 2025).</ref>
<ref name=\"WikiBH\">Wikipedia: “String theory – Black holes and entropy.”</ref>
<ref name=\"BrilliantMass\">Brilliant.org: “String Theory – Mass spectrum.”</ref>
<ref name=\"KKCircle\">Physics StackExchange (2014): “Justification of not quantizing small extra dimensions.”</ref>
<ref name=\"TimelineEarly\">San Jose State Univ. (E. Watkins): “Timeline of the Development of String Theory.”</ref>
</references>


[[File:stringexample.png]]
[[Category:Theory]]
 
[[Category:String Theory]]
[[https://brilliant.org/wiki/string-theory/ ''Reference 5'']]
 
==Connectedness==
#How is this topic connected to something that you are interested in?
String Theory is a particularly intriguing topic due to far-reaching applications that today are widely considered science fiction. (i.e., interstellar space travel utilizing wormholes). This topic is something that not only makes you think but still has the scientific world asking questions. A general understanding of the basics yields a profound knowledge of how the physical world operates
#How is it connected to your major?
String theory falls into the category of Physics, Astrophysics, and Theoretical Physics. My major is Physics with a concentration in Astrophysics, and it mends nicely into my career path.
#Is there an interesting industrial application?
Scientists may not realize industrial applications for string theory in the near future. Still, in the long run, an understanding of string theory could have a profound, yet unforeseen, impact on the world - in a similar revolutionary and unpredicted manner as that of quantum mechanics and the development of modern communication and flow of information.
 
== Scientific Development Timeline==
'''1968-1974''': Dual resonance model
 
'''1970''': String theory is proposed to understand the quantum mechanics of oscillating strings.
 
'''1976''': Supergravity is proposed as a means of explaining the interdependence of gravity and sub-atomic particles' spectrum of excitations - an integral component in string theory.
 
'''1974-1984''': Bosonic string theory & superstring theory
 
'''1980''': Initially perceived to discredit string theory as a unification of quantum mechanics, classical physics, and particle physics, the inconsistencies of the theory were found to nullify each other when considered as special cases. This is the year that string theory becomes widely accepted as a potentially unifying explanation in the scientific community of the time.
 
'''1984-1994''': 1st superstring revolution
 
'''1991-1995''': String theory exploration, in terms of black holes, results in development towards the understanding of the different forms of string theory, in terms of their relationship.
 
'''1994-2003''': 2nd supervising revolution
 
'''1996''': String theory provides a microscopic understanding of black hole entropy and the nature of black hole quantum physics.
 
''See reference 3 & 4''.
 
''See reference 4 for in-depth explanation''.
 
== Additional Resources ==
 
===Further wiki reading===
 
[http://www.physicsbook.gatech.edu/Elementary_Particles_and_Particle_Physics_Theory Elementary Particles and Particle Physics Theory]
 
[http://www.physicsbook.gatech.edu/Quantum_Theory Quantum Theory]
 
[http://www.physicsbook.gatech.edu/Big_Bang_Theory Big Bang Theory]
 
===External links===
 
 
====Articles====
[http://mkaku.org/home/articles/blackholes-wormholes-and-the-tenth-dimension/ Wormholes and Blackholes]
 
[http://web.physics.ucsb.edu/~strings/superstrings/bholes.htm String Theory]
 
[https://doi.org/10.1016/0550-3213(88)90390-2 String theory beyond the Planck scale]
 
[https://iopscience.iop.org/article/10.1088/1126-6708/1999/09/032/pdf String theory and noncommutative geometry]
 
[https://www.damtp.cam.ac.uk/user/tong/string/string.pdf String Theory, University of Cambridge Part III Mathematical Tripos]
 
====Videos====
 
[https://youtu.be/kF4ju6j6aLE Brian Greene: Making Sense of String Theory (YouTube)]
 
[https://youtu.be/Da-2h2B4faU String Theory Explained – What is The True Nature of Reality?]
 
[https://youtu.be/n7cOlBxtKSo ScienceClic English: String Theory]
 
[https://youtu.be/0T--WC4D1C0 String Theory and the End of Space and Time with Robbert Dijkgraaf]
 
====Books====
Steven Gubser, The Little Book of String Theory
 
P. Di Francesco, P. Mathieu and D. S´en´echal, Conformal Field Theory


B. Zwiebach, A First Course in String Theory
---


M. Green, J. Schwarz and E. Witten, Superstring Theory
''Note: Any images labeled “NASA images” or “public domain” can be embedded using <code><nowiki>[[File:filename.jpg|thumb|Caption]]</nowiki></code>. Ensure licensing is clear. For your final wiki, you might upload a public domain image of a black hole or a schematic of compactification and reference them in the text.''
 
J. Polchinski, String Theory
 
==References==
 
'''Reference 1''': "SUPERSTRINGS! Black Holes&nbsp;." <i>Web.physics.ucsb.edu</i>. UCSB, n.d. Web. 03 Dec. 2015. &lt;http://web.physics.ucsb.edu/~strings/superstrings/bholes.htm&gt;.
 
'''Reference 2''': Kaku, Micho, Dr. "Blackholes, Wormholes and the Tenth Dimension." <i>Mkaku.org</i>. N.p., n.d. Web. 03 Dec. 2015. &lt;http://mkaku.org/home/articles/blackholes-wormholes-and-the-tenth-dimension/&gt;.
 
'''Reference 3''': Shwarz, Patricia, Dr. "The Official String Theory Web Site." <i>Superstringtheory.com</i>. N.p., n.d. Web. 03 Dec. 2015. &lt;http://www.superstringtheory.com/index.html&gt;.
 
'''Reference 4''': Beibei Chen 2021 IOP Conf. Ser.: Earth Environ. Sci. 658 012002 <i>https://iopscience.iop.org/article/10.1088/1755-1315/658/1/012002/pdf<i>. IOP Publishing;.
 
'''Reference 5''': Matt DeCross, Christopher Williams, Tejas Suresh, Satyabrata Dash, Eli Ross. String Theory. Brilliant. https://brilliant.org/wiki/string-theory/
 
'''Photo References''':
 
Giribet, Gaston & Celis, Emilio & Simeone, Claudio. (2019). Traversable wormholes in five-dimensional Lovelock theory. Physical Review D. 100. 10.1103/PhysRevD.100.044011.
 
Vyas, Rakshit & Joshi, Mihir. (2019). STRING THEORY: A MATHEMATICAL FRAMEWORK BEHIND COMPATIBILITY AND RECONCILEMENT BETWEEN GENERAL RELATIVITY AND QUANTUM MECHANICS. ISBN:9788192952147. 60-65.
 
American Journal of Physics 83, 486 (2015); doi: 10.1119/1.4916949
 
[[Category:Theory]]

Revision as of 18:57, 12 April 2025

Claimed by Choux Ruby Kim Spring 2025

Short Description of Topic:

String theory is a framework in which the fundamental constituents of the universe are modeled as tiny one-dimensional objects called “strings.” Their different vibrational modes correspond to different particles, including the graviton. By unifying quantum mechanics and gravity, string theory aspires to be a “Theory of Everything,” albeit still awaiting direct experimental validation.

The Main Idea

String theory posits that the fundamental particles of nature (electrons, quarks, photons, etc.) can be seen as different vibrational states of incredibly small strings. Rather than point-like entities, these one-dimensional strings can oscillate in many distinct ways. Each vibrational pattern gives rise to a particle with specific mass, spin, and charge. Notably, one vibrational mode matches the graviton—a spin-2 massless particle—thereby naturally including gravity in a quantum framework.[1]

Modern physics rests on two pillars:

  • General Relativity (describing gravity at large scales)
  • Quantum Field Theory (describing subatomic particles and the other forces)

These two theories do not unify seamlessly in extreme regimes (e.g., near black hole singularities or the big bang). String theory seeks to reconcile them by treating gravity as an emergent phenomenon arising from string interactions, with additional spatial dimensions compactified to scales far below direct detection.[2]

A Mathematical Model

String theory provides several key equations and relationships:

1) Bekenstein–Hawking Black Hole Entropy
[math]\displaystyle{ S_{\text{BH}} = \frac{k_B \, c^3 \, A}{4\, \hbar\, G} \, , }[/math]

where:

  • \(A\) is the horizon area,
  • \(G\) is the gravitational constant,
  • \(c\) is the speed of light,
  • \(k_B\) is Boltzmann’s constant,
  • \(\hbar\) is Planck’s constant.

This formula connects gravitational, quantum, and thermodynamic aspects of black holes. In 1996, string theorists reproduced this entropy by counting microstates of D-branes, providing a significant check on string theory’s internal consistency.[2]

2) String Vibrational Modes (e.g., Closed String Mass Formula)
[math]\displaystyle{ M^2 \;=\; \frac{2}{\alpha'} \bigl(N + \tilde{N} - 2\bigr)\, , }[/math]

where \(N\) and \(\tilde{N}\) are the integer excitation numbers (left- and right-moving modes), and \(\alpha'\) relates to the string tension. Different integer combinations yield different particle masses, including a massless spin-2 mode identified with the graviton.[3]

3) Compactification

Many consistent string theories live in 10 spacetime dimensions. To appear 4-dimensional at low energies, the extra 6 dimensions are curled up (compactified) into a tiny geometric shape (e.g., a Calabi–Yau manifold or an orbifold). A simple version is a circle \(S^1\) with radius \(R\), leading to Kaluza–Klein momentum quantization:

[math]\displaystyle{ p_n = \frac{n \hbar}{R}\, , \quad n \in \mathbb{Z}. }[/math]

Such quantization means, from a 4D perspective, that there is an infinite “tower” of increasingly massive excitations, each separated by \(1/R\).[4]

A Computational Model

To visualize the idea of different vibrational modes on a “string,” we can implement a simplified **vibrating string** simulation in GlowScript (VPython). While not a quantum simulation, it neatly illustrates how a single fundamental system (the string) produces multiple harmonic patterns. Each mode corresponds to a distinct standing wave—an analogy for how string theory’s quantum modes yield different particles.

You can embed or link to a Trinket-based GlowScript program. For example:

<syntaxhighlight lang=\"python\"> GlowScript 3.2 VPython

  1. A classical 1D string with fixed ends,
  2. demonstrating standing wave patterns.

import numpy as np

L = 1.0 # length of the string N = 50 # number of mass points dx = L/(N-1) tension = 10.0 mass = 0.02 k = tension/dx dt = 0.0005 y = [0]*(N) # vertical displacements v = [0]*(N) # velocities

  1. Create spheres for visualization

masses = [] for i in range(N): 

   ball = sphere(pos=vector(i*dx,0,0), radius=0.01)
   masses.append(ball)
  1. Pluck the string in the middle

y[int(N/2)] = 0.1

while True: 

   rate(1000)
   # Update the vertical displacements using finite difference
   for i in range(1, N-1):
       a = k*(y[i+1]-2*y[i]+y[i-1])/mass
       v[i] += a*dt
   for i in range(N):
       y[i] += v[i]*dt
   # Enforce fixed ends
   y[0] = 0
   y[N-1] = 0
   v[0] = 0
   v[N-1] = 0

   # Update visuals
   for i in range(N):
       masses[i].pos.y = y[i]

</syntaxhighlight>

When you run this code (e.g., on https://trinket.io/glowscript/), you see a discretized string. Different initial conditions (e.g., plucking at different points or shapes) can excite different standing-wave modes. Each stable pattern is analogous to how quantum strings have distinct vibrational excitations interpreted as different particles.

Examples

Simple: Compactification to Template loop detected: Template:Math

Scenario: A 5D spacetime with coordinates \((t, x, y, z, w)\), where \(w\) is compactified into a circle of circumference \(2\pi R\).

  1. Set periodic boundary conditions: \(w \sim w + 2\pi R\). A free particle in the extra dimension sees quantized momentum \(p = \frac{n\hbar}{R}\).
  2. View from 4D: Each integer \(n\) is a mode with effective mass \(\frac{n\hbar}{Rc}\). Thus a single 5D particle becomes an infinite Kaluza–Klein tower of 4D particles.
  3. Interpretation: If \(R\) is extremely small, these massive modes are too heavy to observe at today’s energies, making extra dimensions effectively hidden.[4]

Middling: Orbifold Compactification (Template loop detected: Template:Math)

Scenario: Identify opposite points on a circle, halving it to an interval \([0, \pi R]\) with reflections at the boundaries.

  1. Construction: Start with a circle of length \(2\pi R\). Impose Template loop detected: Template:Math. The points \(0\) and \(\pi R\) become “fixed points” of the reflection symmetry.
  2. Field Modes: Even fields satisfy Neumann boundaries at the endpoints, odd fields have Dirichlet (zero at endpoints). This “projection” can remove unwanted modes.
  3. Applications in String Theory: Orbifolds create “branes” at fixed points and can break large gauge symmetries into smaller ones—useful for model building (reducing extra particles).

Difficult: Black Hole Entropy Counting

Scenario: Strominger and Vafa (1996) counted microstates of certain extremal black holes (5D with D1-, D5-branes, and momentum).

  1. D-brane description at weak coupling: The black hole is modeled by a bound state of D1-branes and D5-branes with momentum excitations. One counts the ways to distribute momentum quanta among vibrational modes of the D-brane system.
  2. Statistical Entropy: The result for large charges matches [math]\displaystyle{ S = 2\pi \sqrt{N_1 N_5 N_P} }[/math], exactly reproducing the Bekenstein–Hawking formula in the strong-coupling (black hole) limit.
  3. Significance: Demonstrates that string theory has the correct microscopic degrees of freedom to account for black hole entropy, a milestone in quantum gravity research.[2]

Connectedness

String theory’s scope is broad:

  • Cosmology and Astrophysics: Explains early universe (brane inflation), cosmic strings, black hole thermodynamics.
  • Particle Physics: A candidate for unifying the Standard Model forces with gravity; naturally includes supersymmetry and extra dimensions.
  • Mathematics and Computation: Calabi–Yau geometry, mirror symmetry, new insights into enumerative geometry, quantum information (holography, entanglement).
  • Quantum Information & Holography: AdS/CFT duality links spacetime geometry to quantum entanglement in strongly coupled systems.
  • No Immediate Industrial Application: Yet spin-offs include advanced mathematical tools, HPC algorithms for analyzing large dimensional “landscapes,” and cross-pollination with quantum computing.

History

Below is a brief historical timeline:

1968–1970
Dual Resonance Model
Gabriele Veneziano’s formula fits strong-interaction scattering data. Then Nambu, Nielsen, Susskind interpret it as arising from vibrating strings.[5]
1974
Gravity in String Theory
Schwarz, Scherk, and Yoneya identify a massless spin-2 state—interpreted as the graviton—prompting the claim that string theory can unify quantum physics and gravity.
1984–1985
First Superstring Revolution
Green–Schwarz anomaly cancellation. Witten, Candelas, Horowitz, Strominger show Calabi–Yau compactifications can yield realistic 4D physics. Explosion of interest in superstrings.[5]
1995
Second Superstring Revolution
Witten proposes all five superstring theories + 11D supergravity are unified via M-theory. D-branes (Polchinski) become central to non-perturbative dualities.
1996
Black Hole Entropy
Strominger–Vafa counting of D-brane states reproduces the Bekenstein–Hawking formula. Big success for string theory’s microstate approach to quantum gravity.
1997–1998
AdS/CFT Correspondence (Holography)
Maldacena’s conjecture links a 5D gravitational theory (Type IIB on AdS5 × S5) to a 4D gauge theory, opening new vistas in quantum gravity, QCD, and condensed matter.
2000s–2020s
String Landscape & Applications
Many possible “vacua,” possibly Template loop detected: Template:Math or more, complicating direct phenomenological predictions. Meanwhile, string insights drive progress in quantum information, black hole physics, etc.

See also

Further reading

  • Greene, B. The Elegant Universe. (W.W. Norton, 1999).
  • Zwiebach, B. A First Course in String Theory. (Cambridge University Press, 2009).
  • Green, M.B., Schwarz, J.H., & Witten, E. Superstring Theory. Vol. 1 & 2 (Cambridge University Press, 1987).
  • Becker, K., Becker, M., & Schwarz, J. String Theory and M-Theory: A Modern Introduction. (Cambridge University Press, 2007).
  • Kaku, M. Introduction to Superstrings and M-Theory. (Springer, 1999).
  • Polchinski, J. String Theory: Volumes 1 & 2. (Cambridge University Press, 1998).
  • Susskind, L. The Cosmic Landscape: String Theory and the Illusion of Intelligent Design. (Little, Brown, 2005).

External links

References

  1. [6] String theory is a theoretical framework in which the point-like particles of particle physics are replaced by one-dimensional objects called strings… Cite error: Invalid <ref> tag; name "\"WikiString\"" defined multiple times with different content
  2. Jump up to: 2.0 2.1 2.2 [8] Summarizes black hole entropy and Strominger–Vafa derivation… Cite error: Invalid <ref> tag; name "\"WikiBH\"" defined multiple times with different content
  3. [22] Brilliant.org, “Mass spectrum of the closed string.” Cite error: Invalid <ref> tag; name "\"BrilliantMass\"" defined multiple times with different content
  4. Jump up to: 4.0 4.1 [14] Momentum quantization under periodic boundary conditions. Cite error: Invalid <ref> tag; name "\"KKCircle\"" defined multiple times with different content
  5. Jump up to: 5.0 5.1 [52] Cite error: Invalid <ref> tag; name "\"TimelineEarly\"" defined multiple times with different content

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