L6a4

Visit L6a4's page at the original Knot Atlas!

The link L6a4 is

6_{2}^{3}

in the Rolfsen table of links.

It is also known as the "Borromean Link" or the "Borromean Rings". A Brunnian link - no two loops are linked directly together, but all three rings are collectively interlinked [9].

Visit Peter Cromwell's page on the Borromean Rings.

Classic-type Borromean rings diagram with color-coded circles	Medieval-style representation of the Borromean rings, used as an emblem of Lorenzo de Medici in San Pancrazio, Florence[1]	A kolam with 3 cycles [2]	A version of the coat of arms of the Borromeo family
The Colombo Mall in Lisboa [3]	The Borromean rings as a symbol of the Christian Trinity (based on a 13th-century French manuscript)	One version of the Germanic "Valknut"	Coat of arms of Hallsberg, Sweden, with padlocks in Borromean configuration
A "Borromean" bathroom tile (the Diane de Poitiers three interlaced crescents emblem) [4]	Rectangles in three dimensions	A Borromean link at the Fields Institute [5]	Basic black-and-white depiction with minimal central overlap
3D depiction	3D depiction which purports to show simple circular toruses interlinked as Borromean rings (something which is actually geometrically impossible).	Asymmetrical depiction	Interlaced rectangles (Miguni, Fukui, Japan).
Borromean rings interlinked with cross as Christian symbol.	A practical application of the Borromean rings (Ballard Locks, Seattle)	Borromean paper clips [6]	A Borromean link by Dylan Thurston [7]
A Borromean rattle by Sassy [8]

Knot presentations

Planar diagram presentation	X₆₁₇₂ X_12,8,9,7 X_4,12,1,11 X_10,5,11,6 X₈₄₅₃ X_2,9,3,10
Gauss code	{1, -6, 5, -3}, {4, -1, 2, -5}, {6, -4, 3, -2}

Polynomial invariants

Multivariable Alexander Polynomial (in $u$ , $v$ , $w$ , ...)	${\frac {(u-1)(v-1)(w-1)}{{\sqrt {u}}{\sqrt {v}}{\sqrt {w}}}}$ (db)
Jones polynomial	$-q^{3}-q^{-3}+3q^{2}+3q^{-2}-2q-2q^{-1}+4$ (db)
Signature	0 (db)
HOMFLY-PT polynomial	$-a^{2}z^{2}-z^{2}a^{-2}+a^{2}z^{-2}+a^{-2}z^{-2}+z^{4}+2z^{2}-2z^{-2}$ (db)
Kauffman polynomial	$a^{3}z^{3}+z^{3}a^{-3}+3a^{2}z^{4}+3z^{4}a^{-2}-4a^{2}z^{2}-4z^{2}a^{-2}+a^{2}z^{-2}+a^{-2}z^{-2}+2az^{5}+2z^{5}a^{-1}-az^{3}-z^{3}a^{-1}-2az^{-1}-2a^{-1}z^{-1}+6z^{4}-8z^{2}+2z^{-2}+1$ (db)

Vassiliev invariants

V₂ and V₃:

(0, 0)

V_2,1 through V_6,9:

V_2,1

V_3,1

V_4,1

V_4,2

V_4,3

V_5,1

V_5,2

V_5,3

V_5,4

V_6,1

V_6,2

V_6,3

V_6,4

V_6,5

V_6,6

V_6,7

V_6,8

V_6,9

V_2,1 through V_6,9 were provided by Petr Dunin-Barkowski <barkovs@itep.ru>, Andrey Smirnov <asmirnov@itep.ru>, and Alexei Sleptsov <sleptsov@itep.ru> and uploaded on October 2010 by User:Drorbn. Note that they are normalized differently than V₂ and V₃.

Khovanov Homology

The coefficients of the monomials

t^{r}q^{j}

are shown, along with their alternating sums

\chi

(fixed

j

, alternation over

r

). The squares with yellow highlighting are those on the "critical diagonals", where

j-2r=s+1

or

j-2r=s-1

, where

s=

0 is the signature of L6a4. Nonzero entries off the critical diagonals (if any exist) are highlighted in red.

\		r
	\
j		\

-3

-2

-1

0

1

2

3

χ

7

1

-1

5

2

3

1

4

2

-1

2

4

2

-3

1

-5

2

-7

1

-1

Integral Khovanov Homology

(db, data source)

$\dim {\mathcal {G}}_{2r+i}\operatorname {KH} _{\mathbb {Z} }^{r}$	$i=-1$	$i=1$
$r=-3$	${\mathbb {Z} }$
$r=-2$	${\mathbb {Z} }^{2}\oplus {\mathbb {Z} }_{2}$	${\mathbb {Z} }$
$r=-1$	${\mathbb {Z} }_{2}^{2}$	${\mathbb {Z} }^{2}$
$r=0$	${\mathbb {Z} }^{4}$	${\mathbb {Z} }^{4}$
$r=1$	${\mathbb {Z} }^{2}$
$r=2$	${\mathbb {Z} }\oplus {\mathbb {Z} }_{2}^{2}$	${\mathbb {Z} }^{2}$
$r=3$	${\mathbb {Z} }_{2}$	${\mathbb {Z} }$

Computer Talk

Much of the above data can be recomputed by Mathematica using the package KnotTheory`. See A Sample KnotTheory` Session.

${\textrm {Include}}({\textrm {ColouredJonesM.mhtml}})$

In[1]:=	<< KnotTheory`
Loading KnotTheory` (version of August 17, 2005, 14:44:34)...
In[2]:=	Crossings[Link[6, Alternating, 4]]
Out[2]=	6
In[3]:=	PD[Link[6, Alternating, 4]]
Out[3]=	PD[X[6, 1, 7, 2], X[12, 8, 9, 7], X[4, 12, 1, 11], X[10, 5, 11, 6], X[8, 4, 5, 3], X[2, 9, 3, 10]]
In[4]:=	GaussCode[Link[6, Alternating, 4]]
Out[4]=	GaussCode[{1, -6, 5, -3}, {4, -1, 2, -5}, {6, -4, 3, -2}]
In[5]:=	BR[Link[6, Alternating, 4]]
Out[5]=	BR[Link[6, Alternating, 4]]
In[6]:=	alex = Alexander[Link[6, Alternating, 4]][t]
Out[6]=	ComplexInfinity
In[7]:=	Conway[Link[6, Alternating, 4]][z]
Out[7]=	ComplexInfinity
In[8]:=	Select[AllKnots[], (alex === Alexander[#][t])&]
Out[8]=	{}
In[9]:=	{KnotDet[Link[6, Alternating, 4]], KnotSignature[Link[6, Alternating, 4]]}
Out[9]=	{Infinity, 0}
In[10]:=	J=Jones[Link[6, Alternating, 4]][q]
Out[10]=	-3 3 2 2 3 4 - q + -- - - - 2 q + 3 q - q 2 q q
In[11]:=	Select[AllKnots[], (J === Jones[#][q] \|\| (J /. q-> 1/q) === Jones[#][q])&]
Out[11]=	{}
In[12]:=	A2Invariant[Link[6, Alternating, 4]][q]
Out[12]=	-10 -8 2 3 6 2 4 6 8 10 5 - q + q + -- + -- + -- + 6 q + 3 q + 2 q + q - q 6 4 2 q q q
In[13]:=	Kauffman[Link[6, Alternating, 4]][a, z]
Out[13]=	2 2 3 3 2 1 a 2 2 a 2 4 z 2 2 z z 1 + -- + ----- + -- - --- - --- - 8 z - ---- - 4 a z + -- - -- - 2 2 2 2 a z z 2 3 a z a z z a a 4 5 3 3 3 4 3 z 2 4 2 z 5 a z + a z + 6 z + ---- + 3 a z + ---- + 2 a z 2 a a
In[14]:=	{Vassiliev[2][Link[6, Alternating, 4]], Vassiliev[3][Link[6, Alternating, 4]]}
Out[14]=	{0, 0}
In[15]:=	Kh[Link[6, Alternating, 4]][q, t]
Out[15]=	4 1 2 1 2 3 2 5 2 7 3 - + 4 q + ----- + ----- + ----- + --- + 2 q t + q t + 2 q t + q t q 7 3 5 2 3 2 q t q t q t q t

L6a4

Contents

Knot presentations

Polynomial invariants

Vassiliev invariants

Khovanov Homology

Computer Talk

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