Coxeter_diagram

Coxeter–Dynkin diagram

Pictorial representation of symmetry

In geometry, a Coxeter–Dynkin diagram (or Coxeter diagram, Coxeter graph) is a graph with numerically labeled edges (called branches) representing a Coxeter group or sometimes a uniform polytope or uniform tiling constructed from the group.

Dynkin diagrams are closely related objects, which differ from Coxeter diagrams in two respects: firstly, branches labeled "4" or greater are directed, while Coxeter diagrams are undirected; secondly, Dynkin diagrams must satisfy an additional (crystallographic) restriction, namely that the only allowed branch labels are 2, 3, 4, and 6. Dynkin diagrams correspond to and are used to classify root systems and therefore semisimple Lie algebras.^[1]

Description

A Coxeter group is a group that admits a presentation:

\langle r_{0},r_{1},\dots ,r_{n}\mid (r_{i}r_{j})^{m_{i,j}}=1\rangle

where the m_i,j are the elements of some symmetric matrix M which has 1s on its diagonal.^{[lower-alpha 1]} This matrix M, the Coxeter matrix, completely determines the Coxeter group.

Since the Coxeter matrix is symmetric, it can be viewed as the adjacency matrix of an edge-labeled graph that has vertices corresponding to the generators r_i, and edges labeled with m_i,j between the vertices corresponding to r_i and r_j. In order to simplify these diagrams, two changes can be made:

Edges that are labeled with 2 can be omitted, with the missing edges being implied to be 2s. A label 2 indicates that the corresponding two generators commute; 2 is the smallest number that can be used to label an edge.
Edges labeled 3 can be left unlabeled, with the implication that an unlabeled edge acts as a 3.

The resulting graph is a Coxeter-Dynkin diagram that describes the considered Coxeter group.

Schläfli matrix

Every Coxeter diagram has a corresponding Schläfli matrix (so named after Ludwig Schläfli), A, with matrix elements a_i,j = a_j,i = −2 cos(π/p_i,j) where p_i,j is the branch order between mirrors i and j; that is, π/p_i,j is the dihedral angle between mirrors i and j. As a matrix of cosines, A is also called a Gramian matrix. All Coxeter group Schläfli matrices are symmetric because their root vectors are normalized. A is closely related to the Cartan matrix, used in the similar but directed graph: the Dynkin diagram, in the limited cases of p = 2,3,4, and 6, which are generally not symmetric.

The determinant of the Schläfli matrix is called the Schläflian;^{[citation needed]} the Schläflian and its sign determine whether the group is finite (positive), affine (zero), or indefinite (negative).^[2] This rule is called Schläfli's Criterion.^[3]^{[failed verification]}

The eigenvalues of the Schläfli matrix determine whether a Coxeter group is of finite type (all positive), affine type (all non-negative, at least one is 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. We use the following definitions:

A Coxeter group with connected diagram is hyperbolic if it is neither of finite nor affine type, but every proper connected subdiagram is of finite or affine type.
A hyperbolic Coxeter group is compact if all its subgroups are finite (i.e. have positive determinants), and paracompact if all its subgroups are finite or affine (i.e. have nonnegative determinants).

Finite and affine groups are also called elliptical and parabolic respectively. Hyperbolic groups are also called Lannér, after F. Lannér who enumerated the compact hyperbolic groups in 1950,^[4] and Koszul (or quasi-Lannér) for the paracompact groups.

Rank 2 Coxeter groups

The type of a rank 2 Coxeter group, i.e. generated by two different mirrors, is fully determined by the determinant of the Schläfli matrix, as this determinant is simply the product of the eigenvalues: finite (positive determinant), affine (zero determinant), or hyperbolic (negative determinant) type. Coxeter uses an equivalent bracket notation which lists sequences of branch orders as a substitute for the node-branch graphic diagrams. Rational solutions [p/q], , also exist, with gcd(p,q) = 1; these define overlapping fundamental domains. For example, 3/2, 4/3, 5/2, 5/3, 5/4, and 6/5.

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Rank 2 Coxeter group diagrams
Order p	Group	Coxeter diagram		Schläfli matrix
Order p	Group	Coxeter diagram		$\left[{\begin{matrix}2&a_{12}\\a_{21}&2\end{matrix}}\right]$	Determinant $(4-a_{21}a_{12})$
Finite (Determinant > 0)
2	I₂(2) = A₁×A₁		[2]	$\left[{\begin{smallmatrix}2&0\\0&2\end{smallmatrix}}\right]$	4
3	I₂(3) = A₂		[3]	$\left[{\begin{smallmatrix}2&-1\\-1&2\end{smallmatrix}}\right]$	3
3/2			[3/2]	$\left[{\begin{smallmatrix}2&1\\1&2\end{smallmatrix}}\right]$	3
4	I₂(4) = B₂		[4]	$\left[{\begin{smallmatrix}2&-{\sqrt {2}}\\-{\sqrt {2}}&2\end{smallmatrix}}\right]$	2
4/3			[4/3]	$\left[{\begin{smallmatrix}2&{\sqrt {2}}\\{\sqrt {2}}&2\end{smallmatrix}}\right]$	2
5	I₂(5) = H₂		[5]	$\left[{\begin{smallmatrix}2&-\phi \\-\phi &2\end{smallmatrix}}\right]$	$(5-{\sqrt {5}})/2$ ≈ 1.38196601125
5/4			[5/4]	$\left[{\begin{smallmatrix}2&\phi \\\phi &2\end{smallmatrix}}\right]$	$(5-{\sqrt {5}})/2$ ≈ 1.38196601125
5/2			[5/2]	$\left[{\begin{smallmatrix}2&1-\phi \\1-\phi &2\end{smallmatrix}}\right]$	$(5+{\sqrt {5}})/2$ ≈ 3.61803398875
5/3			[5/3]	$\left[{\begin{smallmatrix}2&\phi -1\\\phi -1&2\end{smallmatrix}}\right]$	$(5+{\sqrt {5}})/2$ ≈ 3.61803398875
6	I₂(6) = G₂		[6]	$\left[{\begin{smallmatrix}2&-{\sqrt {3}}\\-{\sqrt {3}}&2\end{smallmatrix}}\right]$	1
6/5			[6/5]	$\left[{\begin{smallmatrix}2&{\sqrt {3}}\\{\sqrt {3}}&2\end{smallmatrix}}\right]$	1
8	I₂(8)		[8]	$\left[{\begin{smallmatrix}2&-{\sqrt {2+{\sqrt {2}}}}\\-{\sqrt {2+{\sqrt {2}}}}&2\end{smallmatrix}}\right]$	$2-{\sqrt {2}}$ ≈ 0.58578643763
10	I₂(10)		[10]	$\left[{\begin{smallmatrix}2&-{\sqrt {(5+{\sqrt {5}})/2}}\\-{\sqrt {(5+{\sqrt {5}})/2}}&2\end{smallmatrix}}\right]$	$(3-{\sqrt {5}})/2$ ≈ 0.38196601125
12	I₂(12)		[12]	$\left[{\begin{smallmatrix}2&-{\sqrt {2+{\sqrt {3}}}}\\-{\sqrt {2+{\sqrt {3}}}}&2\end{smallmatrix}}\right]$	$2-{\sqrt {3}}$ ≈ 0.26794919243
p	I₂(p)		[p]	$\left[{\begin{smallmatrix}2&-2\cos(\pi /p)\\-2\cos(\pi /p)&2\end{smallmatrix}}\right]$	$4\sin ^{2}(\pi /p)$
Affine (Determinant = 0)
∞	I₂(∞) = ${\tilde {I}}_{1}$ = ${\tilde {A}}_{1}$		[∞]	$\left[{\begin{smallmatrix}2&-2\\-2&2\end{smallmatrix}}\right]$	0
Hyperbolic (Determinant ≤ 0)
∞			[∞]	$\left[{\begin{smallmatrix}2&-2\\-2&2\end{smallmatrix}}\right]$	0
∞			[iπ/λ]	$\left[{\begin{smallmatrix}2&-2\cosh(2\lambda )\\-2\cosh(2\lambda )&2\end{smallmatrix}}\right]$	$-4\sinh ^{2}(2\lambda )\leq 0$

Geometric visualizations

The Coxeter–Dynkin diagram can be seen as a graphic description of the fundamental domain of mirrors. A mirror represents a hyperplane within a given dimensional spherical, Euclidean, or hyperbolic space. (In 2D spaces, a mirror is a line; in 3D, a mirror is a plane.)

These visualizations show the fundamental domains for 2D and 3D Euclidean groups, and for 2D spherical groups. For each, the Coxeter diagram can be deduced by identifying the hyperplane mirrors and labelling their connectivity, ignoring 90-degree dihedral angles (order 2; see footnote [a] below).

Coxeter groups in the Euclidean plane with equivalent diagrams. Here, domain vertices are labeled as graph branches 1, 2, etc., and are colored by their reflection order (connectivity). Reflections are labeled as graph nodes R1, R2, etc. Reflections at 90 degrees are inactive in the sense that, together, they generate no new reflections;^{[lower-alpha 2]} they are therefore not connected to each other by a branch on the diagram. Parallel mirrors are connected to each other by an ∞ labeled branch. The square of the prismatic group ${\tilde {I}}_{1}$ × ${\tilde {I}}_{1}$ is shown as a doubling of the ${\tilde {C}}_{2}$ triangle around its R2 side, but can also be created as a rectangular domain from doubling the ${\tilde {G}}_{2}$ triangle around its R2 side. The ${\tilde {A}}_{2}$ triangle is a doubling of the ${\tilde {G}}_{2}$ triangle around its R3 side. (this side disappears by doubling around itself)
Many Coxeter groups in the hyperbolic plane can be extended from the Euclidean cases as a series of hyperbolic solutions.
Coxeter groups in 3-space with diagrams. Mirrors (triangle faces) are labeled by opposite vertex: 0, ..., 3. Branches are colored by their reflection order. ${\tilde {C}}_{3}$ fills 1/48 of the cube. ${\tilde {B}}_{3}$ fills 1/24 of the cube. ${\tilde {A}}_{3}$ fills 1/12 of the cube.	Coxeter groups in the sphere with equivalent diagrams. One fundamental domain is outlined in yellow. Domain vertices (and graph branches) are colored by their reflection order.

Very-extended Coxeter diagrams

One usage includes a very-extended definition from the direct Dynkin diagram usage which considers affine groups as extended, hyperbolic groups over-extended, and a third node as very-extended simple groups. These extensions are usually marked by an exponent of 1,2, or 3 + symbols for the number of extended nodes. This extending series can be extended backwards, by sequentially removing the nodes from the same position in the graph, although the process stops after removing branching node. The E₈ extended family is the most commonly shown example extending backwards from E₃ and forwards to E₁₁.

The extending process can define a limited series of Coxeter graphs that progress from finite to affine to hyperbolic to Lorentzian. The determinant of the Cartan matrices determine where the series changes from finite (positive) to affine (zero) to hyperbolic (negative), and ending as a Lorentzian group, containing at least one hyperbolic subgroup.^[5] The noncrystallographic H_n groups forms an extended series where H₄ is extended as a compact hyperbolic and over-extended into a lorentzian group.

The determinant of the Schläfli matrix by rank are:^[6]

det(A₁ⁿ = [2ⁿ⁻¹]) = 2ⁿ (Finite for all n)
det(A_n = [3ⁿ⁻¹]) = n + 1 (finite for all n)
det(B_n = [4,3ⁿ⁻²]) = 2 (finite for all n)
det(D_n = [3^n−3,1,1]) = 4 (finite for all n)

Determinants of the Schläfli matrix in exceptional series are:

det(E_n = [3^n−3,2,1]) = 9 − n (finite for E₃ (= A₂A₁), E₄ (= A₄), E₅ (= D₅), E₆, E₇ and E₈, affine at E₉ ( ${\tilde {E}}_{8}$ ), hyperbolic at E₁₀)
det([3^n−4,3,1]) = 2(8 − n) (finite for n = 4 to 7, affine ( ${\tilde {E}}_{7}$ ), and hyperbolic at n = 8.)
det([3^n−4,2,2]) = 3(7 − n) (finite for n = 4 to 6, affine ( ${\tilde {E}}_{6}$ ), and hyperbolic at n = 7.)
det(F_n = [3,4,3ⁿ⁻³]) = 5 − n (finite for F₃ (= B₃) to F₄, affine at F₅ ( ${\tilde {F}}_{4}$ ), hyperbolic at F₆)
det(G_n = [6,3ⁿ⁻²]) = 3 − n (finite for G₂, affine at G₃ ( ${\tilde {G}}_{2}$ ), hyperbolic at G₄)

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Smaller extended series
Finite	$A_{2}$	$C_{2}$	$G_{2}$	$A_{3}$	$B_{3}$	$C_{3}$	$H_{4}$
Rank n	[3^[3],3ⁿ⁻³]	[4,4,3ⁿ⁻³]	G_n=[6,3ⁿ⁻²]	[3^[4],3ⁿ⁻⁴]	[4,3^1,n−3]	[4,3,4,3ⁿ⁻⁴]	H_n=[5,3ⁿ⁻²]
2	[3] A₂	[4] C₂	[6] G₂		[2] A₁²	[4] C₂	[5] H₂
3	[3^[3]] $A_{2}^{+}={\tilde {A}}_{2}$	[4,4] $C_{2}^{+}={\tilde {C}}_{2}$	[6,3] $G_{2}^{+}={\tilde {G}}_{2}$	[3,3]=A₃	[4,3] B₃	[4,3] C₃	[5,3] H₃
4	[3^[3],3] $A_{2}^{++}={\overline {P}}_{3}$	[4,4,3] $C_{2}^{++}={\overline {R}}_{3}$	[6,3,3] $G_{2}^{++}={\overline {V}}_{3}$	[3^[4]] $A_{3}^{+}={\tilde {A}}_{3}$	[4,3^1,1] $B_{3}^{+}={\tilde {B}}_{3}$	[4,3,4] $C_{3}^{+}={\tilde {C}}_{3}$	[5,3,3] H₄
5	[3^[3],3,3] A₂⁺⁺⁺	[4,4,3,3] C₂⁺⁺⁺	[6,3,3,3] G₂⁺⁺⁺	[3^[4],3] $A_{3}^{++}={\overline {P}}_{4}$	[4,3^2,1] $B_{3}^{++}={\overline {S}}_{4}$	[4,3,4,3] $C_{3}^{++}={\overline {R}}_{4}$	[5,3³] H₅= ${\overline {H}}_{4}$
6				[3^[4],3,3] A₃⁺⁺⁺	[4,3^3,1] B₃⁺⁺⁺	[4,3,4,3,3] C₃⁺⁺⁺	[5,3⁴] H₆
Det(M_n)	3(3−n)	2(3−n)	3−n	4(4−n)	2(4−n)

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Middle extended series
Finite	$A_{4}$	$B_{4}$	$C_{4}$	$D_{4}$	$F_{4}$	$A_{5}$	$B_{5}$	$D_{5}$
Rank n	[3^[5],3ⁿ⁻⁵]	[4,3,3^n−4,1]	[4,3,3,4,3ⁿ⁻⁵]	[3^n−4,1,1,1]	[3,4,3ⁿ⁻³]	[3^[6],3ⁿ⁻⁶]	[4,3,3,3^n−5,1]	[3^1,1,3,3^n−5,1]
3		[4,3^−1,1] B₂A₁	[4,3] B₃	[3^−1,1,1,1] A₁³	[3,4] B₃		[4,3,3] C₃
4	[3³] A₄	[4,3,3] B₄	[4,3,3] C₄	[3^0,1,1,1] D₄	[3,4,3] F₄		[4,3,3,3^−1,1] B₃A₁	[3^1,1,3,3^−1,1] A₃A₁
5	[3^[5]] $A_{4}^{+}={\tilde {A}}_{4}$	[4,3,3^1,1] $B_{4}^{+}={\tilde {B}}_{4}$	[4,3,3,4] $C_{4}^{+}={\tilde {C}}_{4}$	[3^1,1,1,1] $D_{4}^{+}={\tilde {D}}_{4}$	[3,4,3,3] $F_{4}^{+}={\tilde {F}}_{4}$	[3⁴] A₅	[4,3,3,3,3] B₅	[3^1,1,3,3] D₅
6	[3^[5],3] $A_{4}^{++}={\overline {P}}_{5}$	[4,3,3^2,1] $B_{4}^{++}={\overline {S}}_{5}$	[4,3,3,4,3] $C_{4}^{++}={\overline {R}}_{5}$	[3^2,1,1,1] $D_{4}^{++}={\overline {Q}}_{5}$	[3,4,3³] $F_{4}^{++}={\overline {U}}_{5}$	[3^[6]] $A_{5}^{+}={\tilde {A}}_{5}$	[4,3,3,3^1,1] $B_{5}^{+}={\tilde {B}}_{5}$	[3^1,1,3,3^1,1] $D_{5}^{+}={\tilde {D}}_{5}$
7	[3^[5],3,3] A₄⁺⁺⁺	[4,3,3^3,1] B₄⁺⁺⁺	[4,3,3,4,3,3] C₄⁺⁺⁺	[3^3,1,1,1] D₄⁺⁺⁺	[3,4,3⁴] F₄⁺⁺⁺	[3^[6],3] $A_{5}^{++}={\overline {P}}_{6}$	[4,3,3,3^2,1] $B_{5}^{++}={\overline {S}}_{6}$	[3^1,1,3,3^2,1] $D_{5}^{++}={\overline {Q}}_{6}$
8						[3^[6],3,3] A₅⁺⁺⁺	[4,3,3,3^3,1] B₅⁺⁺⁺	[3^1,1,3,3^3,1] D₅⁺⁺⁺
Det(M_n)	5(5−n)	2(5−n)		4(5−n)	5−n	6(6−n)	4(6−n)

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Some higher extended series
Finite	$A_{6}$	$B_{6}$	$D_{6}$	$E_{6}$	$A_{7}$	$B_{7}$	$D_{7}$	$E_{7}$	$E_{8}$
Rank n	[3^[7],3ⁿ⁻⁷]	[4,3³,3^n−6,1]	[3^1,1,3,3,3^n−6,1]	[3^n−5,2,2]	[3^[8],3ⁿ⁻⁸]	[4,3⁴,3^n−7,1]	[3^1,1,3,3,3,3^n−7,1]	[3^n−5,3,1]	E_n=[3^n−4,2,1]
3									[3^−1,2,1] E₃=A₂A₁
4				[3^−1,2,2] A₂²				[3^−1,3,1] A₃A₁	[3^0,2,1] E₄=A₄
5		[4,3,3,3,3^−1,1] B₄A₁	[3^1,1,3,3,3^−1,1] D₄A₁	[3^0,2,2] A₅				[3^0,3,1] A₅	[3^1,2,1] E₅=D₅
6	[3⁵] A₆	[4,3⁴] B₆	[3^1,1,3,3,3] D₆	[3^1,2,2] E₆		[4,3,3,3,3,3^−1,1] B₅A₁	[3^1,1,3,3,3,3^−1,1] D₅A₁	[3^1,3,1] D₆	[3^2,2,1] E₆ *
7	[3^[7]] $A_{6}^{+}={\tilde {A}}_{6}$	[4,3³,3^1,1] $B_{6}^{+}={\tilde {B}}_{6}$	[3^1,1,3,3,3^1,1] $D_{6}^{+}={\tilde {D}}_{6}$	[3^2,2,2] $E_{6}^{+}={\tilde {E}}_{6}$	[3⁶] A₇	[4,3⁵] B₇	[3^1,1,3,3,3,3^0,1] D₇	[3^2,3,1] E₇ *	[3^3,2,1] E₇ *
8	[3^[7],3] $A_{6}^{++}={\overline {P}}_{7}$	[4,3³,3^2,1] $B_{6}^{++}={\overline {S}}_{7}$	[3^1,1,3,3,3^2,1] $D_{6}^{++}={\overline {Q}}_{7}$	[3^3,2,2] $E_{6}^{++}={\overline {T}}_{7}$	[3^[8]] $A_{7}^{+}={\tilde {A}}_{7}$ *	[4,3⁴,3^1,1] $B_{7}^{+}={\tilde {B}}_{7}$ *	[3^1,1,3,3,3,3^1,1] $D_{7}^{+}={\tilde {D}}_{7}$ *	[3^3,3,1] $E_{7}^{+}={\tilde {E}}_{7}$ *	[3^4,2,1] E₈ *
9	[3^[7],3,3] A₆⁺⁺⁺	[4,3³,3^3,1] B₆⁺⁺⁺	[3^1,1,3,3,3^3,1] D₆⁺⁺⁺	[3^4,2,2] E₆⁺⁺⁺	[3^[8],3] $A_{7}^{++}={\overline {P}}_{8}$ *	[4,3⁴,3^2,1] $B_{7}^{++}={\overline {S}}_{8}$ *	[3^1,1,3,3,3,3^2,1] $D_{7}^{++}={\overline {Q}}_{8}$ *	[3^4,3,1] $E_{7}^{++}={\overline {T}}_{8}$ *	[3^5,2,1] E₉= $E_{8}^{+}={\tilde {E}}_{8}$ *
10					[3^[8],3,3] A₇⁺⁺⁺ *	[4,3⁴,3^3,1] B₇⁺⁺⁺ *	[3^1,1,3,3,3,3^3,1] D₇⁺⁺⁺ *	[3^5,3,1] E₇⁺⁺⁺ *	[3^6,2,1] E₁₀= $E_{8}^{++}={\overline {T}}_{9}$ *
11									[3^7,2,1] E₁₁=E₈⁺⁺⁺ *
Det(M_n)	7(7−n)	2(7−n)	4(7−n)	3(7−n)	8(8−n)	2(8−n)	4(8−n)	2(8−n)	9−n

Geometric folding

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Finite and affine foldings^[7]
φ_A : A_Γ → A_Γ' for finite types
Γ	Γ'	Folding description	Coxeter–Dynkin diagrams
I₂(h)	Γ(h)	Dihedral folding
B_n	A_2n	(I,s_n)
B_n	D_n+1, A_2n-1	(A₃,±ε)
F₄	E₆	(A₃,±ε)
H₄	E₈	(A₄,±ε)
H₃	D₆
H₂	A₄
G₂	A₅	(A₅,±ε)
G₂	D₄	(D₄,±ε)
φ: A_Γ⁺ → A_Γ'⁺ for affine types
${\tilde {A}}_{n-1}$	${\tilde {A}}_{kn-1}$	Locally trivial
${\tilde {B}}_{n}$	${\tilde {D}}_{2n+1}$	(I,s_n)
${\tilde {B}}_{n}$	${\tilde {D}}_{n+1}$ , ${\tilde {D}}_{2n}$	(A₃,±ε)
${\tilde {C}}_{n}$	${\tilde {B}}_{n+1}$ , ${\tilde {C}}_{2n}$	(A₃,±ε)
${\tilde {C}}_{n}$	${\tilde {C}}_{2n+1}$	(I,s_n)
${\tilde {C}}_{n}$	${\tilde {A}}_{2n+1}$	(I,s_n) & (I,s₀)
	${\tilde {A}}_{2n}$	(A₃,ε) & (I,s₀)
	${\tilde {A}}_{2n-1}$	(A₃,ε) & (A₃,ε')
${\tilde {C}}_{n}$	${\tilde {D}}_{n+2}$	(A₃,−ε) & (A₃,−ε')
${\tilde {C}}_{2}$	${\tilde {D}}_{5}$	(I,s₁)
${\tilde {F}}_{4}$	${\tilde {E}}_{6}$ , ${\tilde {E}}_{7}$	(A₃,±ε)
${\tilde {G}}_{2}$	${\tilde {D}}_{6}$ , ${\tilde {E}}_{7}$	(A₅,±ε)
	${\tilde {B}}_{3}$ , ${\tilde {F}}_{4}$	(B₃,±ε)
	${\tilde {D}}_{4}$ , ${\tilde {E}}_{6}$	(D₄,±ε)

A (simply-laced) Coxeter–Dynkin diagram (finite, affine, or hyperbolic) that has a symmetry (satisfying one condition, below) can be quotiented by the symmetry, yielding a new, generally multiply laced diagram, with the process called "folding".^[8]^[9]

For example, in D₄ folding to G₂, the edge in G₂ points from the class of the 3 outer nodes (valence 1), to the class of the central node (valence 3). And E₈ folds into 2 copies of H₄, the second copy scaled by τ.^[10]

Geometrically this corresponds to orthogonal projections of uniform polytopes and tessellations. Notably, any finite simply-laced Coxeter–Dynkin diagram can be folded to I₂(h), where h is the Coxeter number, which corresponds geometrically to a projection to the Coxeter plane.

A few hyperbolic foldings

Complex reflections

Coxeter–Dynkin diagrams have been extended to complex space, Cⁿ where nodes are unitary reflections of period greater than 2. Nodes are labeled by an index, assumed to be 2 for ordinary real reflection if suppressed. Coxeter writes the complex group, p[q]r, as diagram .^[11]

A 1-dimensional regular complex polytope in $\mathbb {C} ^{1}$ is represented as , having p vertices. Its real representation is a regular polygon, {p}. Its symmetry is _p[] or , order p. A unitary operator generator for is seen as a rotation in $\mathbb {R} ^{2}$ by 2π/p radians counter clockwise, and a edge is created by sequential applications of a single unitary reflection. A unitary reflection generator for a 1-polytope with p vertices is e^2πi/p = cos(2π/p) + i sin(2π/p). When p = 2, the generator is e^πi = –1, the same as a point reflection in the real plane.

In a higher polytope, _p{} or represents a p-edge element, with a 2-edge, {} or , representing an ordinary real edge between two vertices.

Regular complex 1-polytopes
Complex 1-polytopes, , represented in the Argand plane as regular polygons for p = 2, 3, 4, 5, and 6, with black vertices. The centroid of the p vertices is shown seen in red. The sides of the polygons represent one application of the symmetry generator, mapping each vertex to the next counterclockwise copy. These polygonal sides are not edge elements of the polytope, as a complex 1-polytope can have no edges (it often is a complex edge) and only contains vertex elements.

12 irreducible Shephard groups with their subgroup index relations.^[12] Subgroups index 2 relate by removing a real reflection: _p[2q]₂ → _p[q]_p, index 2. _p[4]_q → _p[q]_p, index q.	_p[4]₂ subgroups: p=2,3,4... _p[4]₂ → [p], index p _p[4]₂ → _p[]×_p[], index 2

A regular complex polygon in $\mathbb {C} ^{2}$ , has the form _p{q}_r or Coxeter diagram . The symmetry group of a regular complex polygon is not called a Coxeter group, but instead a Shephard group, a type of Complex reflection group. The order of _p[q]_r is $8/q\cdot (1/p+2/q+1/r-1)^{-2}$ .^[13]

The rank 2 Shephard groups are: ₂[q]₂, _p[4]₂, ₃[3]₃, ₃[6]₂, ₃[4]₃, ₄[3]₄, ₃[8]₂, ₄[6]₂, ₄[4]₃, ₃[5]₃, ₅[3]₅, ₃[10]₂, ₅[6]₂, and ₅[4]₃ or , , , , , , , , , , , , , of order 2q, 2p², 24, 48, 72, 96, 144, 192, 288, 360, 600, 1200, and 1800 respectively.

The symmetry group _p₁[q]_p₂ is represented by 2 generators R₁, R₂, where:

R₁^p₁ = R₂^p₂ = I.

If q is even, (R₂R₁)^q/2 = (R₁R₂)^q/2. If q is odd, (R₂R₁)^(q-1)/2R₂ = (R₁R₂)^(q-1)/2R₁. When q is odd, p₁=p₂.

The $\mathbb {C} ^{3}$ group or [1 1 1]^p is defined by 3 period 2 unitary reflections {R₁, R₂, R₃}:

R₁² = R₁² = R₃² = (R₁R₂)³ = (R₂R₃)³ = (R₃R₁)³ = (R₁R₂R₃R₁)^p = 1.

The period p can be seen as a double rotation in real $\mathbb {R} ^{4}$ .

A similar $\mathbb {C} ^{3}$ group or [1 1 1]^(p) is defined by 3 period 2 unitary reflections {R₁, R₂, R₃}:

R₁² = R₁² = R₃² = (R₁R₂)³ = (R₂R₃)³ = (R₃R₁)³ = (R₁R₂R₃R₂)^p = 1.

References

[1]
Hall, Brian C. (2003), Lie Groups, Lie Algebras, and Representations: An Elementary Introduction, Springer, ISBN 978-0-387-40122-5
[2]
Borovik, Alexandre; Borovik, Anna (2010). Mirrors and reflections. Springer. pp. 118–119.
[3]
Coxeter, Regular Polytopes, (3rd edition, 1973), Dover edition, ISBN 0-486-61480-8, sec. 7.7, p. 133, Schläfli's Criterion
[4]
Lannér F., On complexes with transitive groups of automorphisms, Medd. Lunds Univ. Mat. Sem. [Comm. Sem. Math. Univ. Lund], 11 (1950), 1–71
[5]
Kac-Moody Algebras in M-theory
[6]
Cartan–Gram determinants for the simple Lie groups, Wu, Alfred C. T, The American Institute of Physics, Nov 1982
[7]
John Crisp, 'Injective maps between Artin groups', in Down under group theory, Proceedings of the Special Year on Geometric Group Theory, (Australian National University, Canberra, Australia, 1996), Postscript Archived 2005-10-16 at the Wayback Machine, pp. 13-14, and googlebook, Geometric group theory down under, p. 131
[8]
Zuber, Jean-Bernard (1998). "Generalized Dynkin diagrams and root systems and their folding". Topological Field Theory: 28–30. arXiv:hep-th/9707046. Bibcode:1998tftp.conf..453Z. CiteSeerX 10.1.1.54.3122.
[9]
Dechant, Pierre-Philippe; Boehm, Celine; Twarock, Reidun (2013). "Affine extensions of non-crystallographic Coxeter groups induced by projection". Journal of Mathematical Physics. 54 (9): 093508. arXiv:1110.5228. Bibcode:2013JMP....54i3508D. doi:10.1063/1.4820441. S2CID 59469917.
[10]
The E8 Geometry from a Clifford Perspective Advances in Applied Clifford Algebras, March 2017, Volume 27, Issue 1, pp 397–421 Pierre-Philippe Dechant
[11]
Coxeter, Complex Regular Polytopes, second edition, (1991)
[12]
Coxeter, Complex Regular Polytopes, p. 177, Table III
[13]
Unitary Reflection Groups, p.87

$(R_{i}\circ R_{i})^{1}={\rm {Id}}.$
If $R\perp R',$ then $R'\circ R={\rm {sym}}_{R\cap R'}=R\circ R',$ so $R\circ R'\circ R=R\circ R\circ R'={\rm {Id}}\circ R'=R'$ and $R'\circ R\circ R'=R'\circ R'\circ R={\rm {Id}}\circ R=R.$

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[1] [1]
Hall, Brian C. (2003), Lie Groups, Lie Algebras, and Representations: An Elementary Introduction, Springer, ISBN 978-0-387-40122-5

[3] [2]
Borovik, Alexandre; Borovik, Anna (2010). Mirrors and reflections. Springer. pp. 118–119.

[4] [3]
Coxeter, Regular Polytopes, (3rd edition, 1973), Dover edition, ISBN 0-486-61480-8, sec. 7.7, p. 133, Schläfli's Criterion

[5] [4]
Lannér F., On complexes with transitive groups of automorphisms, Medd. Lunds Univ. Mat. Sem. [Comm. Sem. Math. Univ. Lund], 11 (1950), 1–71

[7] [5]
Kac-Moody Algebras in M-theory

[8] [6]
Cartan–Gram determinants for the simple Lie groups, Wu, Alfred C. T, The American Institute of Physics, Nov 1982

[9] [7]
John Crisp, 'Injective maps between Artin groups', in Down under group theory, Proceedings of the Special Year on Geometric Group Theory, (Australian National University, Canberra, Australia, 1996), Postscript Archived 2005-10-16 at the Wayback Machine, pp. 13-14, and googlebook, Geometric group theory down under, p. 131

[10] [8]
Zuber, Jean-Bernard (1998). "Generalized Dynkin diagrams and root systems and their folding". Topological Field Theory: 28–30. arXiv:hep-th/9707046. Bibcode:1998tftp.conf..453Z. CiteSeerX 10.1.1.54.3122.

[11] [9]
Dechant, Pierre-Philippe; Boehm, Celine; Twarock, Reidun (2013). "Affine extensions of non-crystallographic Coxeter groups induced by projection". Journal of Mathematical Physics. 54 (9): 093508. arXiv:1110.5228. Bibcode:2013JMP....54i3508D. doi:10.1063/1.4820441. S2CID 59469917.

[12] [10]
The E8 Geometry from a Clifford Perspective Advances in Applied Clifford Algebras, March 2017, Volume 27, Issue 1, pp 397–421 Pierre-Philippe Dechant

[13] [11]
Coxeter, Complex Regular Polytopes, second edition, (1991)

[14] [12]
Coxeter, Complex Regular Polytopes, p. 177, Table III

[15] [13]
Unitary Reflection Groups, p.87

[2] $(R_{i}\circ R_{i})^{1}={\rm {Id}}.$

[6] If $R\perp R',$ then $R'\circ R={\rm {sym}}_{R\cap R'}=R\circ R',$ so $R\circ R'\circ R=R\circ R\circ R'={\rm {Id}}\circ R'=R'$ and $R'\circ R\circ R'=R'\circ R'\circ R={\rm {Id}}\circ R=R.$

[1]

[lower-alpha 1]

[2]

[3]

[4]

[lower-alpha 2]

[5]

[6]

[7]

[8]

[9]

[10]

[11]

[12]

[13]

Uniform octahedral polyhedra
Symmetry: [4,3], (*432)							[4,3]⁺ (432)	[1⁺,4,3] = [3,3] (*332)		[3⁺,4] (3*2)
{4,3}	t{4,3}	r{4,3} r{3^1,1}	t{3,4} t{3^1,1}	{3,4} {3^1,1}	rr{4,3} s₂{3,4}	tr{4,3}	sr{4,3}	h{4,3} {3,3}	h₂{4,3} t{3,3}	s{3,4} s{3^1,1}

		=	=	=				= or	= or	=

Duals to uniform polyhedra
V4³	V3.8²	V(3.4)²	V4.6²	V3⁴	V3.4³	V4.6.8	V3⁴.4	V3³	V3.6²	V3⁵

Uniform hexagonal dihedral spherical polyhedra
Symmetry: [6,2], (*622)							[6,2]⁺, (622)	[6,2⁺], (2*3)


{6,2}	t{6,2}	r{6,2}	t{2,6}	{2,6}	rr{6,2}	tr{6,2}	sr{6,2}	s{2,6}
Duals to uniforms

V6²	V12²	V6²	V4.4.6	V2⁶	V4.4.6	V4.4.12	V3.3.3.6	V3.3.3.3

Uniform hexagonal/triangular tilings v t e
Symmetry: [6,3], (*632)							[6,3]⁺ (632)	[6,3⁺] (3*3)
{6,3}	t{6,3}	r{6,3}	t{3,6}	{3,6}	rr{6,3}	tr{6,3}	sr{6,3}	s{3,6}


6³	3.12²	(3.6)²	6.6.6	3⁶	3.4.6.4	4.6.12	3.3.3.3.6	3.3.3.3.3.3
Uniform duals

V6³	V3.12²	V(3.6)²	V6³	V3⁶	V3.4.6.4	V.4.6.12	V3⁴.6	V3⁶

Uniform heptagonal/triangular tilings v t e
Symmetry: [7,3], (*732)							[7,3]⁺, (732)


{7,3}	t{7,3}	r{7,3}	t{3,7}	{3,7}	rr{7,3}	tr{7,3}	sr{7,3}
Uniform duals


V7³	V3.14.14	V3.7.3.7	V6.6.7	V3⁷	V3.4.7.4	V4.6.14	V3.3.3.3.7

Coxeter_diagram

Coxeter–Dynkin diagram

Description

Schläfli matrix

Rank 2 Coxeter groups

Geometric visualizations

Application to uniform polytopes

Examples with polyhedra and tilings

Very-extended Coxeter diagrams

Geometric folding

Complex reflections

See also

References

Further reading

External links

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Type	Finite					Affine	Hyperbolic
Geometry					...
Coxeter diagram Bracket notation	[ ]	[2]	[3]	[4]	[p]	[∞]	[∞]	[iπ/λ]
Order	2	4	6	8	2p	∞
Mirror lines are colored to correspond to Coxeter diagram nodes. Fundamental domains are alternately colored.