Coxeter group

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In mathematics, a Coxeter group, named after H.S.M. Coxeter, is an abstract group that admits a formal description in terms of reflections (or kaleidoscopic mirrors). Indeed, the finite Coxeter groups are precisely the finite Euclidean reflection groups; the symmetry groups of regular polyhedra are an example. However, not all Coxeter groups are finite, and not all can be described in terms of symmetries and Euclidean reflections. Coxeter groups were introduced (Coxeter 1934) as abstractions of reflection groups, and finite Coxeter groups were classified in 1935 (Coxeter 1935).

Coxeter groups find applications in many areas of mathematics. Examples of finite Coxeter groups include the symmetry groups of regular polytopes, and the Weyl groups of simple Lie algebras. Examples of infinite Coxeter groups include the triangle groups corresponding to regular tessellations of the Euclidean plane and the hyperbolic plane, and the Weyl groups of infinite-dimensional Kac–Moody algebras.

Standard references include (Humphreys 1990) and (Davis 2007).

Definition[edit]

Formally, a Coxeter group can be defined as a group with the presentation

\left\langle r_1,r_2,\ldots,r_n \mid (r_ir_j)^{m_{ij}}=1\right\rangle

where m_{ii}=1 and m_{ij}\geq 2 for i\neq j. The condition m_{i j}= \infty means no relation of the form (r_i r_j)^m should be imposed.

The pair (W,S) where W is a Coxeter group with generators S={r1,...,rn} is called Coxeter system. Note that in general S is not uniquely determined by W. For example, the Coxeter groups of type BC3 and A1xA3 are isomorphic but the Coxeter systems are not equivalent (see below for an explanation of this notation).

A number of conclusions can be drawn immediately from the above definition.

  • The relation mi i = 1 means that (riri )1 = (ri )2 = 1 for all i ; the generators are involutions.
  • If mi j = 2, then the generators ri and rj commute. This follows by observing that
xx = yy = 1,
together with
xyxy = 1
implies that
xy = x(xyxy)y = (xx)yx(yy) = yx.
Alternatively, since the generators are involutions, r_i = r_i^{-1}, so (r_ir_j)^2=r_ir_jr_ir_j=r_ir_jr_i^{-1}r_j^{-1}, and thus is equal to the commutator.
  • In order to avoid redundancy among the relations, it is necessary to assume that mi j = mj i. This follows by observing that
yy = 1,
together with
(xy)m = 1
implies that
(yx)m = (yx)myy = y(xy)my = yy = 1.
Alternatively, (xy)^k and (yx)^k are conjugate elements, as y(xy)^k y^{-1} = (yx)^k yy^{-1}=(yx)^k.

Coxeter matrix and Schläfli matrix[edit]

The Coxeter matrix is the n×n, symmetric matrix with entries mi j. Indeed, every symmetric matrix with positive integer and ∞ entries and with 1's on the diagonal such that all nondiagonal entries are greater than 1 serves to define a Coxeter group.

The Coxeter matrix can be conveniently encoded by a Coxeter diagram, as per the following rules.

  • The vertices of the graph are labelled by generator subscripts.
  • Vertices i and j are connected if and only if mi j ≥ 3.
  • An edge is labelled with the value of mi j whenever it is 4 or greater.

In particular, two generators commute if and only if they are not connected by an edge. Furthermore, if a Coxeter graph has two or more connected components, the associated group is the direct product of the groups associated to the individual components. Thus the disjoint union of Coxeter graphs yields a direct product of Coxeter groups.

The Coxeter matrix, Mi,j, is related to the Schläfli matrix, Ci,j, but the elements are modified, being proportional to the dot product of the pairwise generators: Schläfli matrix Ci,j=-2cos(π/Mi,j). The Schläfli matrix is useful because its eigenvalues determine whether the Coxeter group is of finite type (all positive), affine type (all non-negative, at least one zero), or indefinite type (otherwise). The indefinite type is sometimes further subdivided, e.g. into hyperbolic and other Coxeter groups. However, there are multiple non-equivalent definitions for hyperbolic Coxeter groups.

Examples
Coxeter group A1×A1 A2 {\tilde{I}}_1 A3 BC3 D4 {\tilde{A}}_3
Coxeter diagram CDel node.pngCDel 2.pngCDel node.png CDel node.pngCDel 3.pngCDel node.png CDel node.pngCDel infin.pngCDel node.png CDel node.pngCDel 3.pngCDel node.pngCDel 3.pngCDel node.png CDel node.pngCDel 4.pngCDel node.pngCDel 3.pngCDel node.png CDel node.pngCDel 3.pngCDel node.pngCDel split1.pngCDel nodes.png CDel node.pngCDel split1.pngCDel nodes.pngCDel split2.pngCDel node.png
Coxeter matrix \left [
\begin{smallmatrix}
 1 &  2 \\
 2 &  1  \\ 
\end{smallmatrix}\right ] \left [
\begin{smallmatrix}
 1 &  3 \\
 3 &  1  \\ 
\end{smallmatrix}\right ] \left [
\begin{smallmatrix}
 1 &  \infty \\
 \infty &  1  \\ 
\end{smallmatrix}\right ] \left [
\begin{smallmatrix}
 1 &  3 &  2 \\
 3 &  1 &  3 \\
 2 &  3 &  1 
\end{smallmatrix}\right ] \left [
\begin{smallmatrix}
 1 &  4 &  2 \\
 4 &  1 &  3 \\
 2 &  3 &  1 
\end{smallmatrix}\right ] \left [
\begin{smallmatrix}
 1 &  3 &  2 & 2 \\
 3 &  1 &  3 & 3 \\
 2 &  3 &  1 & 2\\
 2 &  3 &  2 & 1 
\end{smallmatrix}\right ] \left [
\begin{smallmatrix}
 1 &  3 &  2 & 3 \\
 3 &  1 &  3 & 2 \\
 2 &  3 &  1 & 3\\
 3 &  2 &  3 & 1 
\end{smallmatrix}\right ]
Schläfli matrix \left [
\begin{smallmatrix}
 2 &  0 \\
 0 &  2 
\end{smallmatrix}\right ] \left [
\begin{smallmatrix}
 2 &  -1 \\
 -1 &  2 
\end{smallmatrix}\right ] \left [
\begin{smallmatrix}
 2 &  -2 \\
 -2 &  2 
\end{smallmatrix}\right ] \left [
\begin{smallmatrix}
 2 &  -1 &  0 \\
 -1 &  2 &  -1 \\
 0 &  -1 &  2 
\end{smallmatrix}\right ] \left [
\begin{smallmatrix}
 2 & -\sqrt{2} &  0 \\
 -\sqrt{2} &  2 &  -1 \\
 0 &  -1 &  2 
\end{smallmatrix}\right ] \left [
\begin{smallmatrix}
 2 & -1  & 0 & 0 \\
-1 &  2 &  -1 & -1 \\
 0 & -1 &  2 & 0\\
 0 & -1 &  0 & 2 
\end{smallmatrix}\right ] \left [
\begin{smallmatrix}
 2 & -1  & 0 & -1 \\
-1 &  2 &  -1 & 0 \\
 0 & -1 &  2 & -1\\
-1 &  0 &  -1 & 2 
\end{smallmatrix}\right ]

An example[edit]

The graph in which vertices 1 through n are placed in a row with each vertex connected by an unlabelled edge to its immediate neighbors gives rise to the symmetric group Sn+1; the generators correspond to the transpositions (1 2), (2 3), ... (n n+1). Two non-consecutive transpositions always commute, while (k k+1) (k+1 k+2) gives the 3-cycle (k k+2 k+1). Of course this only shows that Sn+1 is a quotient group of the Coxeter group described by the graph, but it is not too difficult to check that equality holds.

Connection with reflection groups[edit]

For more details on this topic, see Reflection group.

Coxeter groups are deeply connected with reflection groups. Simply put, Coxeter groups are abstract groups (given via a presentation), while reflection groups are concrete groups (given as subgroups of linear groups or various generalizations). Coxeter groups grew out of the study of reflection groups — they are an abstraction: a reflection group is a subgroup of a linear group generated by reflections (which have order 2), while a Coxeter group is an abstract group generated by involutions (elements of order 2, abstracting from reflections), and whose relations have a certain form ((r_ir_j)^k, corresponding to hyperplanes meeting at an angle of \pi/k, with r_ir_j being of order k abstracting from a rotation by 2\pi/k).

The abstract group of a reflection group is a Coxeter group, while conversely a reflection group can be seen as a linear representation of a Coxeter group. For finite reflection groups, this yields an exact correspondence: every finite Coxeter group admits a faithful representation as a finite reflection group of some Euclidean space. For infinite Coxeter groups, however, a Coxeter group may not admit a representation as a reflection group.

Historically, (Coxeter 1934) proved that every reflection group is a Coxeter group (i.e., has a presentation where all relations are of the form r_i^2 or (r_ir_j)^k), and indeed this paper introduced the notion of a Coxeter group, while (Coxeter 1935) proved that every finite Coxeter group had a representation as a reflection group, and classified finite Coxeter groups.

Finite Coxeter groups[edit]

Coxeter graphs of the finite Coxeter groups.

Classification[edit]

The finite Coxeter groups were classified in (Coxeter 1935), in terms of Coxeter–Dynkin diagrams; they are all represented by reflection groups of finite-dimensional Euclidean spaces.

The finite Coxeter groups consist of three one-parameter families of increasing rank A_n, BC_n, D_n, one one-parameter family of dimension two, I_2(p), and six exceptional groups: E_6, E_7, E_8, F_4, H_3, and H_4.

Weyl groups[edit]

Main article: Weyl group

Many, but not all of these, are Weyl groups, and every Weyl group can be realized as a Coxeter group. The Weyl groups are the families A_n, BC_n, and D_n, and the exceptions E_6, E_7, E_8, F_4, and I_2(6), denoted in Weyl group notation as G_2. The non-Weyl groups are the exceptions H_3 and H_4, and the family I_2(p) except where this coincides with one of the Weyl groups (namely I_2(3) \cong A_2, I_2(4) \cong BC_2, and I_2(6) \cong G_2).

This can be proven by comparing the restrictions on (undirected) Dynkin diagrams with the restrictions on Coxeter diagrams of finite groups: formally, the Coxeter graph can be obtained from the Dynkin diagram by discarding the direction of the edges, and replacing every double edge with an edge labelled 4 and every triple edge by an edge labelled 6. Also note that every finitely generated Coxeter group is an Automatic group.[1] Dynkin diagrams have the additional restriction that the only permitted edge labels are 2, 3, 4, and 6, which yields the above. Geometrically, this corresponds to the crystallographic restriction theorem, and the fact that excluded polytopes do not fill space or tile the plane – for H_3, the dodecahedron (dually, icosahedron) does not fill space; for H_4, the 120-cell (dually, 600-cell) does not fill space; for I_2(p) a p-gon does not tile the plane except for p=3, 4, or 6 (the triangular, square, and hexagonal tilings, respectively).

Note further that the (directed) Dynkin diagrams Bn and Cn give rise to the same Weyl group (hence Coxeter group), because they differ as directed graphs, but agree as undirected graphs – direction matters for root systems but not for the Weyl group; this corresponds to the hypercube and cross-polytope being different regular polytopes but having the same symmetry group.

Properties[edit]

Some properties of the finite Coxeter groups are given in the following table:

Group
symbol
Alternate
symbol
Bracket notation Rank Order Related polytopes Coxeter-Dynkin diagram
An An [3n-1] n (n + 1)! n-simplex CDel node.pngCDel 3.pngCDel node.pngCDel 3.png..CDel 3.pngCDel node.pngCDel 3.pngCDel node.png
BCn Cn [4,3n-2] n 2n n! n-hypercube / n-cross-polytope CDel node.pngCDel 4.pngCDel node.pngCDel 3.png...CDel 3.pngCDel node.pngCDel 3.pngCDel node.png
Dn Bn [3n-3,1,1] n 2n−1 n! n-demihypercube CDel nodes.pngCDel split2.pngCDel node.pngCDel 3.png...CDel 3.pngCDel node.pngCDel 3.pngCDel node.png
E6 E6 [32,2,1] 6 72x6! = 51840 221, 122 CDel nodea.pngCDel 3a.pngCDel nodea.pngCDel 3a.pngCDel branch.pngCDel 3a.pngCDel nodea.pngCDel 3a.pngCDel nodea.png or CDel node.pngCDel 3.pngCDel node.pngCDel split1.pngCDel nodes.pngCDel 3ab.pngCDel nodes.png
E7 E7 [33,2,1] 7 72x8! = 2903040 321, 231, 132 CDel nodea.pngCDel 3a.pngCDel nodea.pngCDel 3a.pngCDel branch.pngCDel 3a.pngCDel nodea.pngCDel 3a.pngCDel nodea.pngCDel 3a.pngCDel nodea.png
E8 E8 [34,2,1] 8 192x10! = 696729600 421, 241, 142 CDel nodea.pngCDel 3a.pngCDel nodea.pngCDel 3a.pngCDel branch.pngCDel 3a.pngCDel nodea.pngCDel 3a.pngCDel nodea.pngCDel 3a.pngCDel nodea.pngCDel 3a.pngCDel nodea.png
F4 F4 [3,4,3] 4 1152 24-cell CDel node.pngCDel 3.pngCDel node.pngCDel 4.pngCDel node.pngCDel 3.pngCDel node.png
G2 - [6] 2 12 hexagon CDel node.pngCDel 6.pngCDel node.png
H2 G2 [5] 2 10 pentagon CDel node.pngCDel 5.pngCDel node.png
H3 G3 [3,5] 3 120 icosahedron / dodecahedron CDel node.pngCDel 5.pngCDel node.pngCDel 3.pngCDel node.png
H4 G4 [3,3,5] 4 14400 120-cell / 600-cell CDel node.pngCDel 5.pngCDel node.pngCDel 3.pngCDel node.pngCDel 3.pngCDel node.png
I2(p) D2p [p] 2 2p p-gon CDel node.pngCDel p.pngCDel node.png

Symmetry groups of regular polytopes[edit]

All symmetry groups of regular polytopes are finite Coxeter groups. Note that dual polytopes have the same symmetry group.

There are three series of regular polytopes in all dimensions. The symmetry group of a regular n-simplex is the symmetric group Sn+1, also known as the Coxeter group of type An. The symmetry group of the n-cube and its dual, the n-cross-polytope, is BCn, and is known as the hyperoctahedral group.

The exceptional regular polytopes in dimensions two, three, and four, correspond to other Coxeter groups. In two dimensions, the dihedral groups, which are the symmetry groups of regular polygons, form the series I2(p). In three dimensions, the symmetry group of the regular dodecahedron and its dual, the regular icosahedron, is H3, known as the full icosahedral group. In four dimensions, there are three special regular polytopes, the 24-cell, the 120-cell, and the 600-cell. The first has symmetry group F4, while the other two are dual and have symmetry group H4.

The Coxeter groups of type Dn, E6, E7, and E8 are the symmetry groups of certain semiregular polytopes.



Table of irreducible polytope families
Family
n
n-simplex n-hypercube n-orthoplex n-demicube 1k2 2k1 k21 pentagonal polytope
Group An BCn
I2(p) Dn
E6 E7 E8 F4 G2
Hn
2 2-simplex t0.svg
CDel node 1.pngCDel 3.pngCDel node.png

(Triangle)

2-cube.svg
CDel node 1.pngCDel 4.pngCDel node.png

Square

CDel node 1.pngCDel p.pngCDel node.png
p-gon
Regular polygon 6.svg
CDel node 1.pngCDel 6.pngCDel node.png
Hexagon
Regular polygon 5.svg
CDel node 1.pngCDel 5.pngCDel node.png
Pentagon
3 3-simplex t0.svg
CDel node 1.pngCDel 3.pngCDel node.pngCDel 3.pngCDel node.png
Tetrahedron
3-cube t0.svg
CDel node 1.pngCDel 4.pngCDel node.pngCDel 3.pngCDel node.png
Cube
3-cube t2.svg
CDel node 1.pngCDel 3.pngCDel node.pngCDel 4.pngCDel node.png
Octahedron
3-demicube.svg
CDel nodea 1.pngCDel 3a.pngCDel branch.png
Tetrahedron
  Dodecahedron t0 H3.png
CDel node 1.pngCDel 5.pngCDel node.pngCDel 3.pngCDel node.png
Dodecahedron
Icosahedron t0 H3.png
CDel node 1.pngCDel 3.pngCDel node.pngCDel 5.pngCDel node.png
Icosahedron
4 4-simplex t0.svg
CDel node 1.pngCDel 3.pngCDel node.pngCDel 3.pngCDel node.pngCDel 3.pngCDel node.png
5-cell
4-cube t0.svg
CDel node 1.pngCDel 4.pngCDel node.pngCDel 3.pngCDel node.pngCDel 3.pngCDel node.png

Tesseract

4-cube t3.svg
CDel node 1.pngCDel 3.pngCDel node.pngCDel 3.pngCDel node.pngCDel 4.pngCDel node.png
16-cell
4-demicube t0 D4.svg
CDel nodea 1.pngCDel 3a.pngCDel branch.pngCDel 3a.pngCDel nodea.png

Demitesseract

24-cell t0 F4.svg
CDel node 1.pngCDel 3.pngCDel node.pngCDel 4.pngCDel node.pngCDel 3.pngCDel node.png
24-cell
120-cell graph H4.svg
CDel node 1.pngCDel 5.pngCDel node.pngCDel 3.pngCDel node.pngCDel 3.pngCDel node.png
120-cell
600-cell graph H4.svg
CDel node 1.pngCDel 3.pngCDel node.pngCDel 3.pngCDel node.pngCDel 5.pngCDel node.png
600-cell
5 5-simplex t0.svg
CDel node 1.pngCDel 3.pngCDel node.pngCDel 3.pngCDel node.pngCDel 3.pngCDel node.pngCDel 3.pngCDel node.png
5-simplex
5-cube graph.svg
CDel node 1.pngCDel 4.pngCDel node.pngCDel 3.pngCDel node.pngCDel 3.pngCDel node.pngCDel 3.pngCDel node.png
5-cube
5-orthoplex.svg
CDel node 1.pngCDel 3.pngCDel node.pngCDel 3.pngCDel node.pngCDel 3.pngCDel node.pngCDel 4.pngCDel node.png
5-orthoplex
5-demicube.svg
CDel nodea 1.pngCDel 3a.pngCDel branch.pngCDel 3a.pngCDel nodea.pngCDel 3a.pngCDel nodea.png
5-demicube
   
6 6-simplex t0.svg
CDel node 1.pngCDel 3.pngCDel node.pngCDel 3.pngCDel node.pngCDel 3.pngCDel node.pngCDel 3.pngCDel node.pngCDel 3.pngCDel node.png
6-simplex
6-cube graph.svg
CDel node 1.pngCDel 4.pngCDel node.pngCDel 3.pngCDel node.pngCDel 3.pngCDel node.pngCDel 3.pngCDel node.pngCDel 3.pngCDel node.png
6-cube
6-orthoplex.svg
CDel node 1.pngCDel 3.pngCDel node.pngCDel 3.pngCDel node.pngCDel 3.pngCDel node.pngCDel 3.pngCDel node.pngCDel 4.pngCDel node.png
6-orthoplex
6-demicube.svg
CDel nodea 1.pngCDel 3a.pngCDel branch.pngCDel 3a.pngCDel nodea.pngCDel 3a.pngCDel nodea.pngCDel 3a.pngCDel nodea.png
6-demicube
Up 1 22 t0 E6.svg
CDel nodea.pngCDel 3a.pngCDel nodea.pngCDel 3a.pngCDel branch 01lr.pngCDel 3a.pngCDel nodea.pngCDel 3a.pngCDel nodea.png
122
E6 graph.svg
CDel nodea.pngCDel 3a.pngCDel nodea.pngCDel 3a.pngCDel branch.pngCDel 3a.pngCDel nodea.pngCDel 3a.pngCDel nodea 1.png
221
 
7 7-simplex t0.svg
CDel node 1.pngCDel 3.pngCDel node.pngCDel 3.pngCDel node.pngCDel 3.pngCDel node.pngCDel 3.pngCDel node.pngCDel 3.pngCDel node.pngCDel 3.pngCDel node.png
7-simplex
7-cube graph.svg
CDel node 1.pngCDel 4.pngCDel node.pngCDel 3.pngCDel node.pngCDel 3.pngCDel node.pngCDel 3.pngCDel node.pngCDel 3.pngCDel node.pngCDel 3.pngCDel node.png
7-cube
7-orthoplex.svg
CDel node 1.pngCDel 3.pngCDel node.pngCDel 3.pngCDel node.pngCDel 3.pngCDel node.pngCDel 3.pngCDel node.pngCDel 3.pngCDel node.pngCDel 4.pngCDel node.png
7-orthoplex
7-demicube.svg
CDel nodea 1.pngCDel 3a.pngCDel branch.pngCDel 3a.pngCDel nodea.pngCDel 3a.pngCDel nodea.pngCDel 3a.pngCDel nodea.pngCDel 3a.pngCDel nodea.png
7-demicube
Gosset 1 32 petrie.svg
CDel nodea.pngCDel 3a.pngCDel nodea.pngCDel 3a.pngCDel nodea.pngCDel 3a.pngCDel branch 01lr.pngCDel 3a.pngCDel nodea.pngCDel 3a.pngCDel nodea.png
132
Gosset 2 31 polytope.svg
CDel nodea.pngCDel 3a.pngCDel nodea.pngCDel 3a.pngCDel nodea.pngCDel 3a.pngCDel branch.pngCDel 3a.pngCDel nodea.pngCDel 3a.pngCDel nodea 1.png
231
E7 graph.svg
CDel nodea 1.pngCDel 3a.pngCDel nodea.pngCDel 3a.pngCDel nodea.pngCDel 3a.pngCDel branch.pngCDel 3a.pngCDel nodea.pngCDel 3a.pngCDel nodea.png
321
 
8 8-simplex t0.svg
CDel node 1.pngCDel 3.pngCDel node.pngCDel 3.pngCDel node.pngCDel 3.pngCDel node.pngCDel 3.pngCDel node.pngCDel 3.pngCDel node.pngCDel 3.pngCDel node.pngCDel 3.pngCDel node.png
8-simplex
8-cube.svg
CDel node 1.pngCDel 4.pngCDel node.pngCDel 3.pngCDel node.pngCDel 3.pngCDel node.pngCDel 3.pngCDel node.pngCDel 3.pngCDel node.pngCDel 3.pngCDel node.pngCDel 3.pngCDel node.png
8-cube
8-orthoplex.svg
CDel node 1.pngCDel 3.pngCDel node.pngCDel 3.pngCDel node.pngCDel 3.pngCDel node.pngCDel 3.pngCDel node.pngCDel 3.pngCDel node.pngCDel 3.pngCDel node.pngCDel 4.pngCDel node.png
8-orthoplex
8-demicube.svg
CDel nodea 1.pngCDel 3a.pngCDel branch.pngCDel 3a.pngCDel nodea.pngCDel 3a.pngCDel nodea.pngCDel 3a.pngCDel nodea.pngCDel 3a.pngCDel nodea.pngCDel 3a.pngCDel nodea.png
8-demicube
Gosset 1 42 polytope petrie.svg
CDel nodea.pngCDel 3a.pngCDel nodea.pngCDel 3a.pngCDel nodea.pngCDel 3a.pngCDel nodea.pngCDel 3a.pngCDel branch 01lr.pngCDel 3a.pngCDel nodea.pngCDel 3a.pngCDel nodea.png
142
2 41 polytope petrie.svg
CDel nodea.pngCDel 3a.pngCDel nodea.pngCDel 3a.pngCDel nodea.pngCDel 3a.pngCDel nodea.pngCDel 3a.pngCDel branch.pngCDel 3a.pngCDel nodea.pngCDel 3a.pngCDel nodea 1.png
241
Gosset 4 21 polytope petrie.svg
CDel nodea 1.pngCDel 3a.pngCDel nodea.pngCDel 3a.pngCDel nodea.pngCDel 3a.pngCDel nodea.pngCDel 3a.pngCDel branch.pngCDel 3a.pngCDel nodea.pngCDel 3a.pngCDel nodea.png
421
 
9 9-simplex t0.svg
CDel node 1.pngCDel 3.pngCDel node.pngCDel 3.pngCDel node.pngCDel 3.pngCDel node.pngCDel 3.pngCDel node.pngCDel 3.pngCDel node.pngCDel 3.pngCDel node.pngCDel 3.pngCDel node.pngCDel 3.pngCDel node.png
9-simplex
9-cube.svg
CDel node 1.pngCDel 4.pngCDel node.pngCDel 3.pngCDel node.pngCDel 3.pngCDel node.pngCDel 3.pngCDel node.pngCDel 3.pngCDel node.pngCDel 3.pngCDel node.pngCDel 3.pngCDel node.pngCDel 3.pngCDel node.png
9-cube
9-orthoplex.svg
CDel node 1.pngCDel 3.pngCDel node.pngCDel 3.pngCDel node.pngCDel 3.pngCDel node.pngCDel 3.pngCDel node.pngCDel 3.pngCDel node.pngCDel 3.pngCDel node.pngCDel 3.pngCDel node.pngCDel 4.pngCDel node.png
9-orthoplex
9-demicube.svg
CDel nodea 1.pngCDel 3a.pngCDel branch.pngCDel 3a.pngCDel nodea.pngCDel 3a.pngCDel nodea.pngCDel 3a.pngCDel nodea.pngCDel 3a.pngCDel nodea.pngCDel 3a.pngCDel nodea.pngCDel 3a.pngCDel nodea.png
9-demicube
 
10 10-simplex t0.svg
CDel node 1.pngCDel 3.pngCDel node.pngCDel 3.pngCDel node.pngCDel 3.pngCDel node.pngCDel 3.pngCDel node.pngCDel 3.pngCDel node.pngCDel 3.pngCDel node.pngCDel 3.pngCDel node.pngCDel 3.pngCDel node.pngCDel 3.pngCDel node.png
10-simplex
10-cube.svg
CDel node 1.pngCDel 4.pngCDel node.pngCDel 3.pngCDel node.pngCDel 3.pngCDel node.pngCDel 3.pngCDel node.pngCDel 3.pngCDel node.pngCDel 3.pngCDel node.pngCDel 3.pngCDel node.pngCDel 3.pngCDel node.pngCDel 3.pngCDel node.png
10-cube
10-orthoplex.svg
CDel node 1.pngCDel 3.pngCDel node.pngCDel 3.pngCDel node.pngCDel 3.pngCDel node.pngCDel 3.pngCDel node.pngCDel 3.pngCDel node.pngCDel 3.pngCDel node.pngCDel 3.pngCDel node.pngCDel 3.pngCDel node.pngCDel 4.pngCDel node.png
10-orthoplex
10-demicube.svg
CDel nodea 1.pngCDel 3a.pngCDel branch.pngCDel 3a.pngCDel nodea.pngCDel 3a.pngCDel nodea.pngCDel 3a.pngCDel nodea.pngCDel 3a.pngCDel nodea.pngCDel 3a.pngCDel nodea.pngCDel 3a.pngCDel nodea.pngCDel 3a.pngCDel nodea.png
10-demicube
 


Affine Coxeter groups[edit]

Coxeter diagrams for the Affine Coxeter groups

The affine Coxeter groups form a second important series of Coxeter groups. These are not finite themselves, but each contains a normal abelian subgroup such that the corresponding quotient group is finite. In each case, the quotient group is itself a Coxeter group, and the Coxeter graph is obtained from the Coxeter graph of the Coxeter group by adding another vertex and one or two additional edges. For example, for n ≥ 2, the graph consisting of n+1 vertices in a circle is obtained from An in this way, and the corresponding Coxeter group is the affine Weyl group of An. For n = 2, this can be pictured as the symmetry group of the standard tiling of the plane by equilateral triangles.

A list of the affine Coxeter groups follows:

Group
symbol
Witt
symbol
Bracket notation Related uniform tessellation(s) Coxeter-Dynkin diagram
{\tilde{A}}_n Pn+1 [3[n]] Simplectic honeycomb CDel node.pngCDel split1.pngCDel nodes.pngCDel 3ab.png...CDel 3ab.pngCDel nodes.pngCDel 3ab.pngCDel branch.png
or
CDel branch.pngCDel 3ab.pngCDel nodes.pngCDel 3ab.png...CDel 3ab.pngCDel nodes.pngCDel 3ab.pngCDel branch.png
{\tilde{B}}_n Sn+1 [4,3n-3,31,1] Demihypercubic honeycomb CDel node.pngCDel 4.pngCDel node.pngCDel 3.pngCDel node.pngCDel 3.png...CDel 3.pngCDel node.pngCDel split1.pngCDel nodes.png
{\tilde{C}}_n Rn+1 [4,3n-2,4] Hypercubic honeycomb CDel node.pngCDel 4.pngCDel node.pngCDel 3.pngCDel node.pngCDel 3.png...CDel 3.pngCDel node.pngCDel 4.pngCDel node.png
{\tilde{D}}_n Qn+1 [ 31,1,3n-4,31,1] Demihypercubic honeycomb CDel nodes.pngCDel split2.pngCDel node.pngCDel 3.pngCDel node.pngCDel 3.png...CDel 3.pngCDel node.pngCDel split1.pngCDel nodes.png
{\tilde{E}}_6 T7 [32,2,2] 222 CDel nodea.pngCDel 3a.pngCDel nodea.pngCDel 3a.pngCDel branch.pngCDel 3ab.pngCDel nodes.pngCDel 3a.pngCDel nodea.png or CDel nodes.pngCDel 3ab.pngCDel nodes.pngCDel split2.pngCDel node.pngCDel 3.pngCDel node.pngCDel 3.pngCDel node.png
{\tilde{E}}_7 T8 [33,3,1] 331, 133 CDel nodea.pngCDel 3a.pngCDel nodea.pngCDel 3a.pngCDel nodea.pngCDel 3a.pngCDel branch.pngCDel 3a.pngCDel nodea.pngCDel 3a.pngCDel nodea.pngCDel 3a.pngCDel nodea.png or CDel nodes.pngCDel 3ab.pngCDel nodes.pngCDel 3ab.pngCDel nodes.pngCDel split2.pngCDel node.pngCDel 3.pngCDel node.png
{\tilde{E}}_8 T9 [35,2,1] 521, 251, 152 CDel nodea.pngCDel 3a.pngCDel nodea.pngCDel 3a.pngCDel branch.pngCDel 3a.pngCDel nodea.pngCDel 3a.pngCDel nodea.pngCDel 3a.pngCDel nodea.pngCDel 3a.pngCDel nodea.pngCDel 3a.pngCDel nodea.png
{\tilde{F}}_4 U5 [3,4,3,3] 16-cell honeycomb
24-cell honeycomb
CDel node.pngCDel 3.pngCDel node.pngCDel 4.pngCDel node.pngCDel 3.pngCDel node.pngCDel 3.pngCDel node.png
{\tilde{G}}_2 V3 [6,3] Hexagonal tiling and
Triangular tiling
CDel node.pngCDel 6.pngCDel node.pngCDel 3.pngCDel node.png
{\tilde{I}}_1 W2 [∞] apeirogon CDel node.pngCDel infin.pngCDel node.png

The subscript is one less than the number of nodes in each case, since each of these groups was obtained by adding a node to a finite group's graph.

Hyperbolic Coxeter groups[edit]

There are infinitely many hyperbolic Coxeter groups describing reflection groups in hyperbolic space, notably including the hyperbolic triangle groups.

Partial orders[edit]

A choice of reflection generators gives rise to a length function l on a Coxeter group, namely the minimum number of uses of generators required to express a group element; this is precisely the length in the word metric in the Cayley graph. An expression for v using l(v) generators is a reduced word. For example, the permutation (13) in S3 has two reduced words, (12)(23)(12) and (23)(12)(23). The function v \to (-1)^{l(v)} defines a map G \to \{\pm 1\}, generalizing the sign map for the symmetric group.

Using reduced words one may define three partial orders on the Coxeter group, the (right) weak order, the absolute order and the Bruhat order (named for François Bruhat). An element v exceeds an element u in the Bruhat order if some (or equivalently, any) reduced word for v contains a reduced word for u as a substring, where some letters (in any position) are dropped. In the weak order, v ≥ u if some reduced word for v contains a reduced word for u as an initial segment. Indeed, the word length makes this into a graded poset. The Hasse diagrams corresponding to these orders are objects of study, and are related to the Cayley graph determined by the generators. The absolute order is defined analogously to the weak order, but with generating set/alphabet consisting of all conjugates of the Coxeter generators.

For example, the permutation (1 2 3) in S3 has only one reduced word, (12)(23), so covers (12) and (23) in the Bruhat order but only covers (12) in the weak order.

Homology[edit]

Since a Coxeter group W is generated by finitely many elements of order 2, its abelianization is an elementary abelian 2-group, i.e. it is isomorphic to the direct sum of several copies of the cyclic group Z2. This may be restated in terms of the first homology group of W.

The Schur multiplier M(W) (related to the second homology) was computed in (Ihara & Yokonuma 1965) for finite reflection groups and in (Yokonuma 1965) for affine reflection groups, with a more unified account given in (Howlett 1988). In all cases, the Schur multiplier is also an elementary abelian 2-group. For each infinite family {Wn} of finite or affine Weyl groups, the rank of M(W) stabilizes as n goes to infinity.

See also[edit]

References[edit]

  1. ^ Brink and Howlett (1993), A finiteness property and an automatic structure for Coxeter groups, Mathematische Annalen (Springer Berlin / Heidelberg), ISSN 0025-5831. 

Further reading[edit]

  • Coxeter, H.S.M. (1934), Discrete groups generated by reflections, Ann. Of Math. 35 (3): 588–621, doi:10.2307/1968753, JSTOR 1968753 
  • Coxeter, H.S.M. (1935), The complete enumeration of finite groups of the form r_i^2=(r_ir_j)^{k_{ij}}=1, J. London Math. Soc. 10: 21–25 
  • Davis, Michael W. (2007), The Geometry and Topology of Coxeter Groups, ISBN 978-0-691-13138-2 
  • Larry C Grove and Clark T. Benson, Finite Reflection Groups, Graduate texts in mathematics, vol. 99, Springer, (1985)
  • James E. Humphreys, Reflection Groups and Coxeter Groups, Cambridge studies in advanced mathematics, 29 (1990)
  • Richard Kane, Reflection Groups and Invariant Theory, CMS Books in Mathematics, Springer (2001)
  • Anders Björner and Francesco Brenti, Combinatorics of Coxeter Groups, Graduate Texts in Mathematics, vol. 231, Springer, (2005)
  • Howard Hiller, Geometry of Coxeter groups. Research Notes in Mathematics, 54. Pitman (Advanced Publishing Program), Boston, Mass.-London, 1982. iv+213 pp. ISBN 0-273-08517-4
  • Nicolas Bourbaki, Lie Groups and Lie Algebras: Chapter 4-6, Elements of Mathematics, Springer (2002). ISBN 978-3-540-42650-9
  • Howlett, Robert B. (1988), On the Schur Multipliers of Coxeter Groups, Journal of the London Mathematical Society, 2 38 (2): 263–276, doi:10.1112/jlms/s2-38.2.263 
  • Vinberg, E. B. (1984), Absence of crystallographic groups of reflections in Lobachevski spaces of large dimension, Trudy Moskov. Mat. Obshch. 47 

External links[edit]