McKay graph

Affine (extended) Dynkin diagrams

In mathematics, the McKay graph of a finite-dimensional representation $V$ of a finite group $G$ is a weighted quiver encoding the structure of the representation theory of $G$ . Each node represents an irreducible representation of $G$ . If $χ i, χ j$ are irreducible representations of $G$ , then there is an arrow from $χ i$ to $χ j$ if and only if $χ j$ is a constituent of the tensor product $V\otimes \chi _{i}.$ Then the weight $n ij$ of the arrow is the number of times this constituent appears in $V\otimes \chi _{i}.$ For finite subgroups $H$ of ${\text{GL}}(2,\mathbb {C} ),$ the McKay graph of $H$ is the McKay graph of the defining 2-dimensional representation of $H$ .

If $G$ has $n$ irreducible characters, then the Cartan matrix $c V$ of the representation $V$ of dimension $d$ is defined by $c_{V}=(d\delta _{ij}-n_{ij})_{ij},$ where $δ$ is the Kronecker delta. A result by Robert Steinberg states that if $g$ is a representative of a conjugacy class of $G$ , then the vectors $((\chi _{i}(g))_{i}$ are the eigenvectors of $c V$ to the eigenvalues $d-\chi _{V}(g),$ where $χ V$ is the character of the representation $V$ .^[1]

The McKay correspondence, named after John McKay, states that there is a one-to-one correspondence between the McKay graphs of the finite subgroups of ${\text{SL}}(2,\mathbb {C} )$ and the extended Dynkin diagrams, which appear in the ADE classification of the simple Lie algebras.^[2]

Definition

Let $G$ be a finite group, $V$ be a representation of $G$ and $χ$ be its character. Let $\{\chi _{1},\ldots ,\chi _{d}\}$ be the irreducible representations of $G$ . If

V\otimes \chi _{i}=\sum _{j}n_{ij}\chi _{j},

then define the McKay graph $Γ G$ of $G$ , relative to $V$ , as follows:

Each irreducible representation of $G$ corresponds to a node in $Γ G$ .
If $n ij > 0$ , there is an arrow from $χ i$ to $χ j$ of weight $n ij$ , written as $\chi _{i}\xrightarrow {n_{ij}} \chi _{j},$ or sometimes as $n ij$ unlabeled arrows.
If $n_{ij}=n_{ji},$ we denote the two opposite arrows between $χ i, χ j$ as an undirected edge of weight $n ij$ . Moreover, if $n_{ij}=1,$ we omit the weight label.

We can calculate the value of $n ij$ using inner product $\langle \cdot ,\cdot \rangle$ on characters:

n_{ij}=\langle V\otimes \chi _{i},\chi _{j}\rangle ={\frac {1}{|G|}}\sum _{g\in G}V(g)\chi _{i}(g){\overline {\chi _{j}(g)}}.

The McKay graph of a finite subgroup of ${\text{GL}}(2,\mathbb {C} )$ is defined to be the McKay graph of its canonical representation.

For finite subgroups of ${\text{SL}}(2,\mathbb {C} ),$ the canonical representation on $\mathbb {C} ^{2}$ is self-dual, so $n_{ij}=n_{ji}$ for all $i, j$ . Thus, the McKay graph of finite subgroups of ${\text{SL}}(2,\mathbb {C} )$ is undirected.

In fact, by the McKay correspondence, there is a one-to-one correspondence between the finite subgroups of ${\text{SL}}(2,\mathbb {C} )$ and the extended Coxeter-Dynkin diagrams of type A-D-E.

We define the Cartan matrix $c V$ of $V$ as follows:

c_{V}=(d\delta _{ij}-n_{ij})_{ij},

where $δ ij$ is the Kronecker delta.

Some results

If the representation $V$ is faithful, then every irreducible representation is contained in some tensor power $V^{\otimes k},$ and the McKay graph of $V$ is connected.
The McKay graph of a finite subgroup of ${\text{SL}}(2,\mathbb {C} )$ has no self-loops, that is, $n_{ii}=0$ for all $i$ .
The arrows of the McKay graph of a finite subgroup of ${\text{SL}}(2,\mathbb {C} )$ are all of weight one.

Examples

Suppose $G = A \times B$ , and there are canonical irreducible representations $c A, c B$ of $A, B$ respectively. If $χ i, i = 1, \dots, k$ , are the irreducible representations of $A$ and $ψ j, j = 1, \dots, ℓ$ , are the irreducible representations of $B$ , then

\chi _{i}\times \psi _{j}\quad 1\leq i\leq k,\,\,1\leq j\leq \ell

are the irreducible representations of

A \times B

, where

\chi _{i}\times \psi _{j}(a,b)=\chi _{i}(a)\psi _{j}(b),(a,b)\in A\times B.

In this case, we have

\langle (c_{A}\times c_{B})\otimes (\chi _{i}\times \psi _{\ell }),\chi _{n}\times \psi _{p}\rangle =\langle c_{A}\otimes \chi _{k},\chi _{n}\rangle \cdot \langle c_{B}\otimes \psi _{\ell },\psi _{p}\rangle .

Therefore, there is an arrow in the McKay graph of

G

between

\chi _{i}\times \psi _{j}

and

\chi _{k}\times \psi _{\ell }

if and only if there is an arrow in the McKay graph of

A

between

χ i, χ k

and there is an arrow in the McKay graph of

B

between

ψ j, ψ ℓ

. In this case, the weight on the arrow in the McKay graph of

G

is the product of the weights of the two corresponding arrows in the McKay graphs of

A

and

B

.

Felix Klein proved that the finite subgroups of ${\text{SL}}(2,\mathbb {C} )$ are the binary polyhedral groups; all are conjugate to subgroups of ${\text{SU}}(2,\mathbb {C} ).$ The McKay correspondence states that there is a one-to-one correspondence between the McKay graphs of these binary polyhedral groups and the extended Dynkin diagrams. For example, the binary tetrahedral group ${\overline {T}}$ is generated by the ${\text{SU}}(2,\mathbb {C} )$ matrices:

S=\left({\begin{array}{cc}i&0\\0&-i\end{array}}\right),\ \ V=\left({\begin{array}{cc}0&i\\i&0\end{array}}\right),\ \ U={\frac {1}{\sqrt {2}}}\left({\begin{array}{cc}\varepsilon &\varepsilon ^{3}\\\varepsilon &\varepsilon ^{7}\end{array}}\right),

where

ε

is a primitive eighth root of unity. In fact, we have

{\overline {T}}=\{U^{k},SU^{k},VU^{k},SVU^{k}\mid k=0,\ldots ,5\}.

The conjugacy classes of

{\overline {T}}

are:

C_{1}=\{U^{0}=I\},

C_{2}=\{U^{3}=-I\},

C_{3}=\{\pm S,\pm V,\pm SV\},

C_{4}=\{U^{2},SU^{2},VU^{2},SVU^{2}\},

C_{5}=\{-U,SU,VU,SVU\},

C_{6}=\{-U^{2},-SU^{2},-VU^{2},-SVU^{2}\},

C_{7}=\{U,-SU,-VU,-SVU\}.

The character table of

{\overline {T}}

is

Conjugacy Classes	$C_{1}$	$C_{2}$	$C_{3}$	$C_{4}$	$C_{5}$	$C_{6}$	$C_{7}$
$\chi _{1}$	$1$	$1$	$1$	$1$	$1$	$1$	$1$
$\chi _{2}$	$1$	$1$	$1$	$\omega$	$\omega ^{2}$	$\omega$	$\omega ^{2}$
$\chi _{3}$	$1$	$1$	$1$	$\omega ^{2}$	$\omega$	$\omega ^{2}$	$\omega$
$\chi _{4}$	$3$	$3$	$-1$	$0$	$0$	$0$	$0$
$c$	$2$	$-2$	$0$	$-1$	$-1$	$1$	$1$
$\chi _{5}$	$2$	$-2$	$0$	$-\omega$	$-\omega ^{2}$	$\omega$	$\omega ^{2}$
$\chi _{6}$	$2$	$-2$	$0$	$-\omega ^{2}$	$-\omega$	$\omega ^{2}$	$\omega$

Here

\omega =e^{2\pi i/3}.

The canonical representation

V

is here denoted by

c

. Using the inner product, we find that the McKay graph of

{\overline {T}}

is the extended Coxeter–Dynkin diagram of type

{\tilde {E}}_{6}.

References

^ Steinberg, Robert (1985), "Subgroups of $SU_{2}$ , Dynkin diagrams and affine Coxeter elements", Pacific Journal of Mathematics, 18: 587–598, doi:10.2140/pjm.1985.118.587
^ McKay, John (1982), "Representations and Coxeter Graphs", "The Geometric Vein", Coxeter Festschrift, Berlin: Springer-Verlag

McKay graph

Definition

Some results

Examples

See also

References

Further reading