Namespaces
Variants
Actions

Difference between revisions of "Fox-n-colouring"

From Encyclopedia of Mathematics
Jump to: navigation, search
(Tex done)
(cf Tangle move)
Line 1: Line 1:
 
A colouring of a non-oriented link diagram (cf. also [[Knot and link diagrams]]), leading to an Abelian group invariant of links in $\mathbf{R}^3$ (cf. also [[Link|Link]]). It was introduced by R.H. Fox around 1956 to visualize dihedral representations of the knot group [[#References|[a1]]] (cf. also [[Knot and link groups]]). Using $3$-colourings is, probably, the simplest method of showing that the trefoil knot is non-trivial (see Fig.a1).
 
A colouring of a non-oriented link diagram (cf. also [[Knot and link diagrams]]), leading to an Abelian group invariant of links in $\mathbf{R}^3$ (cf. also [[Link|Link]]). It was introduced by R.H. Fox around 1956 to visualize dihedral representations of the knot group [[#References|[a1]]] (cf. also [[Knot and link groups]]). Using $3$-colourings is, probably, the simplest method of showing that the trefoil knot is non-trivial (see Fig.a1).
  
One says that a link (or tangle) diagram, $D$, is $n$-coloured if every arc is coloured by one of the numbers $0,\ldots,(n-1)$ in such a way that at each crossing the sum of the colours of the undercrossings is equal to twice the colour of the overcrossing modulo $n$. The set of $n$-colourings forms an [[Abelian group]], denoted by $\text{Col}_n(D)$. This group can be interpreted using the first homology group (modulo $n$) of the double branched cover of $S^3$ with the link as the branched point set. The group of $3$-colourings is determined by the Jones polynomial (at $t=e^{2\pi i/6}$), and the group of $5$-colourings by the [[Kauffman polynomial]] (at $a=1$, $z = 2\cos(2\pi/5)$), [[#References|[a2]]]. The $n$-moves preserve the group of $n$-colourings and $3$-moves lead to the [[Montesinos–Nakanishi conjecture]].
+
One says that a link (or tangle) diagram, $D$, is $n$-coloured if every arc is coloured by one of the numbers $0,\ldots,(n-1)$ in such a way that at each crossing the sum of the colours of the undercrossings is equal to twice the colour of the overcrossing modulo $n$. The set of $n$-colourings forms an [[Abelian group]], denoted by $\text{Col}_n(D)$. This group can be interpreted using the first homology group (modulo $n$) of the double branched cover of $S^3$ with the link as the branched point set. The group of $3$-colourings is determined by the Jones polynomial (at $t=e^{2\pi i/6}$), and the group of $5$-colourings by the [[Kauffman polynomial]] (at $a=1$, $z = 2\cos(2\pi/5)$), [[#References|[a2]]]. The $n$-moves preserve the group of $n$-colourings and $3$-moves lead to the [[Montesinos–Nakanishi conjecture]] (cf. [[Tangle move]]).
  
 
<img style="border:1px solid;" src="https://www.encyclopediaofmath.org/legacyimages/common_img/f130220a.gif" />
 
<img style="border:1px solid;" src="https://www.encyclopediaofmath.org/legacyimages/common_img/f130220a.gif" />

Revision as of 17:52, 30 December 2016

A colouring of a non-oriented link diagram (cf. also Knot and link diagrams), leading to an Abelian group invariant of links in $\mathbf{R}^3$ (cf. also Link). It was introduced by R.H. Fox around 1956 to visualize dihedral representations of the knot group [a1] (cf. also Knot and link groups). Using $3$-colourings is, probably, the simplest method of showing that the trefoil knot is non-trivial (see Fig.a1).

One says that a link (or tangle) diagram, $D$, is $n$-coloured if every arc is coloured by one of the numbers $0,\ldots,(n-1)$ in such a way that at each crossing the sum of the colours of the undercrossings is equal to twice the colour of the overcrossing modulo $n$. The set of $n$-colourings forms an Abelian group, denoted by $\text{Col}_n(D)$. This group can be interpreted using the first homology group (modulo $n$) of the double branched cover of $S^3$ with the link as the branched point set. The group of $3$-colourings is determined by the Jones polynomial (at $t=e^{2\pi i/6}$), and the group of $5$-colourings by the Kauffman polynomial (at $a=1$, $z = 2\cos(2\pi/5)$), [a2]. The $n$-moves preserve the group of $n$-colourings and $3$-moves lead to the Montesinos–Nakanishi conjecture (cf. Tangle move).

Figure: f130220a

The linear space of $p$-colourings of the boundary points of an $n$-tangle has a symplectic form (cf. also Symplectic structure), so that tangles correspond to Lagrangian subspaces (i.e. maximal totally degenerate subspaces) of the symplectic form.

The Alexander module is a generalization of the group of $n$-colourings.

References

[a1] R.H. Crowell, R.H. Fox, "An introduction to knot theory" , Ginn (1963)
[a2] J. Przytycki, "3-coloring and other elementary invariants of knots" , Knot Theory , Banach Center Publications , 42 (1998) pp. 275–295
How to Cite This Entry:
Fox-n-colouring. Encyclopedia of Mathematics. URL: http://encyclopediaofmath.org/index.php?title=Fox-n-colouring&oldid=40104
This article was adapted from an original article by Jozef Przytycki (originator), which appeared in Encyclopedia of Mathematics - ISBN 1402006098. See original article