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?
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
Knot theory is a branch of mathematics that studies the properties of mathematical knots, which are configurations of tangled, looped, or knotted strings in three-dimensional space. String theory, on the other hand, is a theoretical framework in physics that attempts to describe the fundamental nature of matter and energy in the universe. Knot theory is related to string theory in that it provides a mathematical language and tools for describing and understanding the behavior of strings in string theory.
Knot theory has several applications in string theory. One application is in understanding the topology, or the geometric properties, of string configurations. Knot theory also helps in studying the behavior of strings in non-Euclidean spaces, such as those with curved dimensions. Additionally, knot theory is used in classifying and characterizing different types of strings in string theory, such as closed strings and open strings.
Knot theory provides a powerful mathematical framework for analyzing and solving problems in string theory. By using knot theory, physicists can better understand the structure and behavior of strings in different scenarios, such as in high energy collisions or in the presence of black holes. Knot theory also helps in identifying symmetries and patterns in string theory, which can lead to new insights and predictions.
One of the main challenges in applying knot theory to string theory is the complexity of the mathematical models involved. String theory deals with high-dimensional spaces and complex geometries, making it difficult to apply knot theory techniques. Additionally, there is still a lot that is unknown about both knot theory and string theory, so there is ongoing research to better understand the connections between the two.
While the implications of string theory itself are still being explored, there are potential real-world applications of knot theory in other fields, such as biology and chemistry. For example, knot theory has been used to analyze and predict the properties of protein molecules, which have complex knot-like structures. Additionally, knot theory has been applied to the study of DNA and other biomolecules, providing insights into their behavior and properties.