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mutant knot in nLab

Contents

Context

Knot theory

knot theory

knot, link

Examples/classes:

Types

knot invariants

crossing number
bridge number
unknotting number
colorability
knot group
knot genus?
polynomial knot invariants

(observables of non-perturbative Chern-Simons theory)
Vassiliev knot invariants

(observables of pertrubative Chern-Simons theory)
Khovanov homology
Kauffman bracket?

link invariants

Related concepts:

Idea

In knot theory, the known problem of unwinding? knots gives rise to the factorization of knots generated by composing prime knots and their mutants. The computational process of computing knot invariants, namely the polynomials describing these invariants, has been postulated as a basis for “attacks” in quantum cryptography. Classes of knots called mutants would hinder these attacks and remain undetected by a quantum computer, at their present maturity. The mutants of a given knot are indistinguishable since they all have the same Jones’ type invariants. Mutants also appear in the field-theoretic framework manifest in the expectation values of Wilson loop operators.

Definition

Beginning with the tangle representation of an oriented knot KK, one can obtain a mutant K′K' by replacing one of the tangles with a rotated version of the former tangle. It is important to note that the process of mutation can be executed on various subsets of the same knot diagram containing at least one crossing?.

References

Marzuoli and Palumbo, Post Quantum Cryptography from Mutant Prime Knots, 2011, Int. J. Geom. Methods Mod. Phys. (arXiv: 1010.2055/math-ph)

Last revised on January 26, 2021 at 04:55:44. See the history of this page for a list of all contributions to it.