Figure-eight knot (mathematics)

This article is about the mathematical concept. For the knot, see Figure-eight knot. For other uses, see Figure 8.

Figure-eight knot

Common name	Figure-eight knot
Arf invariant	1
Braid length	4
Braid no.	3
Bridge no.	2
Crosscap no.	2
Crossing no.	4
Genus	1
Hyperbolic volume	2.02988
Stick no.	7
Unknotting no.	1
Conway notation	[22]
A-B notation	4₁
Dowker notation	4, 6, 8, 2
Last /Next	3₁ / 5₁
Other
alternating, hyperbolic, fibered, prime, fully amphichiral, twist

Figure-eight knot of practical knot-tying, with ends joined

In knot theory, a figure-eight knot (also called Listing's knot) is the unique knot with a crossing number of four. This is the smallest possible crossing number except for the unknot and trefoil knot. The figure-eight knot is a prime knot.

Origin of name

The name is given because tying a normal figure-eight knot in a rope and then joining the ends together, in the most natural way, gives a model of the mathematical knot.

Description

A simple parametric representation of the figure-eight knot is as the set of all points (x,y,z) where

\begin{align} x & = \left(2 + \cos{(2t)} \right) \cos{(3t)} \\ y & = \left(2 + \cos{(2t)} \right) \sin{(3t)} \\ z & = \sin{(4t)} \end{align}

for t varying over the real numbers (see 2D visual realization at bottom right).

The figure-eight knot is prime, alternating, rational with an associated value of 5/2, and is achiral. The figure-eight knot is also a fibered knot. This follows from other, less simple (but very interesting) representations of the knot:

(1) It is a homogeneous^{[note 1]} closed braid (namely, the closure of the 3-string braid σ₁σ₂⁻¹σ₁σ₂⁻¹), and a theorem of John Stallings shows that any closed homogeneous braid is fibered.

(2) It is the link at (0,0,0,0) of an isolated critical point of a real-polynomial map F: R⁴→R², so (according to a theorem of John Milnor) the Milnor map of F is actually a fibration. Bernard Perron found the first such F for this knot, namely,

F(x, y, z, t)=G(x, y, z^2-t^2, 2zt),\,\!

where

\begin{align} G(x,y,z,t)=\ & (z(x^2+y^2+z^2+t^2)+x (6x^2-2y^2-2z^2-2t^2), \\ & \ t x \sqrt{2}+y (6x^2-2y^2-2z^2-2t^2)). \end{align}

Mathematical properties

Simple squared depiction of figure-eight configuration.

The figure-eight knot has played an important role historically (and continues to do so) in the theory of 3-manifolds. Sometime in the mid-to-late 1970s, William Thurston showed that the figure-eight was hyperbolic, by decomposing its complement into two ideal hyperbolic tetrahedra. (Robert Riley and Troels Jørgensen, working independently of each other, had earlier shown that the figure-eight knot was hyperbolic by other means.) This construction, new at the time, led him to many powerful results and methods. For example, he was able to show that all but ten Dehn surgeries on the figure-eight knot resulted in non-Haken, non-Seifert-fibered irreducible 3-manifolds; these were the first such examples. Many more have been discovered by generalizing Thurston's construction to other knots and links.

The figure-eight knot is also the hyperbolic knot whose complement has the smallest possible volume, 2.02988... according to the work of Chun Cao and Robert Meyerhoff. From this perspective, the figure-eight knot can be considered the simplest hyperbolic knot. The figure eight knot complement is a double-cover of the Gieseking manifold, which has the smallest volume among non-compact hyperbolic 3-manifolds.

The figure-eight knot and the (−2,3,7) pretzel knot are the only two hyperbolic knots known to have more than 6 exceptional surgeries, Dehn surgeries resulting in a non-hyperbolic 3-manifold; they have 10 and 7, respectively. A theorem of Lackenby and Meyerhoff, whose proof relies on the geometrization conjecture and computer assistance, holds that 10 is the largest possible number of exceptional surgeries of any hyperbolic knot. However, it is not currently known whether the figure-eight knot is the only one that achieves the bound of 10. A well-known conjecture is that the bound (except for the two knots mentioned) is 6.

Symmetric depiction generated by parametric equations.

Invariants

The Alexander polynomial of the figure-eight knot is

\Delta(t) = -t + 3 - t^{-1},\

the Conway polynomial is

\nabla(z) = 1-z^2,\

^[1]

and the Jones polynomial is

V(q) = q^2 - q + 1 - q^{-1} + q^{-2}.\

The symmetry between $q$ and $q^{-1}$ in the Jones polynomial reflects the fact that the figure-eight knot is achiral.

Notes

↑ A braid is called homogeneous if every generator $\sigma _{i}$ either occurs always with positive or always with negative sign.

References

↑ "4_1", The Knot Atlas.

External links

"4_1", The Knot Atlas. Accessed: 7 May 2013.
Weisstein, Eric W. "Figure Eight Knot". MathWorld.

Knot theory (knots and links)

Hyperbolic	Figure-eight (4₁) Three-twist (5₂) Stevedore (6₁) 6₂ 6₃ Endless (7₄) Carrick mat (8₁₈) Perko pair (10₁₆₁) (−2,3,7) pretzel (12n242) Whitehead (52 1) Borromean rings (63 2) L10a140

Satellite	Composite knots Granny Square Knot sum

Torus	Unknot (0₁) Trefoil (3₁) Cinquefoil (5₁) Septafoil (7₁) Unlink (02 1) Hopf (22 1) Solomon's (42 1)

Invariants	Alternating Arf invariant Bridge no. 2-bridge Brunnian Chirality Invertible Crosscap no. Crossing no. Finite type invariant Hyperbolic volume Khovanov homology Genus Knot group Link group Linking no. Polynomial Alexander Bracket HOMFLY Jones Kauffman Pretzel Prime list Stick no. Tricolorability Unknotting no. & problem

Notation & operations	Alexander–Briggs notation Conway notation Dowker notation Flype Mutation Reidemeister move Skein relation Tabulation

Other	Alexander's theorem Berge Braid theory Conway sphere Complement Double torus Fibered Knot List of knots and links Ribbon Slice Sum Tait conjectures Twist Wild Writhe

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