Applying of knot theory to string theory

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SUMMARY

The discussion centers on the application of knot theory to string theory, specifically regarding the behavior of closed strings in 4-dimensional spacetime. It establishes that knots, defined as 1-dimensional loops, cannot exist in dimensions greater than three, meaning closed strings in 4D can only form trivial knots. The conversation also explores the potential for 2D surfaces to form knots in 4D, citing the Klein bottle as an example. Additionally, it discusses the relationship between string vibrations and their representation in higher dimensions, suggesting that disturbances in strings can lead to various physical phenomena.

PREREQUISITES
  • Understanding of knot theory and its definitions
  • Familiarity with string theory concepts
  • Knowledge of topological spaces and their properties
  • Basic grasp of dimensionality in physics
NEXT STEPS
  • Research the implications of knot theory in higher-dimensional spaces
  • Explore the Klein bottle and its properties in topology
  • Investigate the relationship between string vibrations and physical phenomena
  • Study the mathematical foundations of string theory and its dimensional aspects
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Physicists, mathematicians, and students interested in theoretical physics, particularly those exploring the intersections of knot theory and string theory.

shreyakmath
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Probably a bit abstract,but I was thinking if 4D closed strings could form knots? I mean if a closed string in 4-dimensional spacetime can be considered an unknot and a knot polynomial be associated with every closed string. I also wondered that if the fundamental strings vibrate in the knotted state, their harmonics could represent something entirely different!
What are your views?
 
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shreyakmath said:
Probably a bit abstract,but I was thinking if 4D closed strings could form knots? I mean if a closed string in 4-dimensional spacetime can be considered an unknot and a knot polynomial be associated with every closed string. I also wondered that if the fundamental strings vibrate in the knotted state, their harmonics could represent something entirely different!
What are your views?

Knots are always from "materials" that have one less dimension than the space in which they are embedded. So a 4-D space would have 3-D knots. I can't say that I can picture this.
 
A knot is nothing else but the map of a closed one-dim. loop to a target space. The fact that the knot is knotted is not a property of the loop but a property of the map. It is encoded in the topological structure of the "target space minus the knot".

Now you can try to do this in N > 3 dimensions.

It turns out that there are no knots in N > 3, that means that every "knot" can be unknotted, the "target space minus the knot" is topologically identical to the "target space minus a trivial circle".
 
Strings cannot form knots in 4 dimensions. (or only trivial knots)

But this got me thinking that 2d surfaces can form "knots" in 4 dimensions. Are these, too, called knots in topology? By tom.stoer's definition for example the Klein bottle would be a knot in 4d, though not in any superior dimension.
 
Hm, knots are always defined as 1-dim loops in 3-space. But you are right, there is this analogy in higher dim. spaces
 
Last edited:
someGorilla said:
But this got me thinking that 2d surfaces can form "knots" in 4 dimensions. Are these, too, called knots in topology? By tom.stoer's definition for example the Klein bottle would be a knot in 4d, though not in any superior dimension.

tom.stoer said:
Hm, knots are always defined as 1-dim loops in 3-space. But you are right, there is this analogy in higher dim. spaces

torsten answered this in https://www.physicsforums.com/showthread.php?t=678799
 
what if the "string vibration" is actually a spin projection of a one dimensional string on a two dimensional plane. we cannot see the actual spin of the string but we can see the vibration behaviour on a plane transversal to the observer.

then how then can a closed loop can be formed in two dimensional space. visualise a telephone cord when you bend it and began twisting on the middle. notice that the two halves of the cord will twist in unison. then appying more spinning motion will result the beginning and end parts of the cord will meet; thus forming an irregular loop depending on how much spin is applied to the middle of the cord.

somehow, the telephone cord represent the actual string in space, has one dimension (length) but suspended in space in a spiral pattern. when a disturbance is acted upon the spiral string, it either contracts(gravity), elongates (light, sound, magnetism) or forms a dimensional loop (matter).

correct me if I am wrong but this only an observation.
 

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