Conjugacy class explained

In mathematics, especially group theory, two elements

and

of a group are conjugate if there is an element

in the group such that

b=gag^-1.

This is an equivalence relation whose equivalence classes are called conjugacy classes. In other words, each conjugacy class is closed under

b=gag^-1

for all elements

in the group.

Members of the same conjugacy class cannot be distinguished by using only the group structure, and therefore share many properties. The study of conjugacy classes of non-abelian groups is fundamental for the study of their structure.^[1] ^[2] For an abelian group, each conjugacy class is a set containing one element (singleton set).

Functions that are constant for members of the same conjugacy class are called class functions.

Definition

Let

be a group. Two elements

a,b\inG

are conjugate if there exists an element

g\inG

such that

gag^-1=b,

in which case

is called of

and

is called a conjugate of

\operatorname{GL}(n)

of invertible matrices, the conjugacy relation is called matrix similarity.

It can be easily shown that conjugacy is an equivalence relation and therefore partitions

into equivalence classes. (This means that every element of the group belongs to precisely one conjugacy class, and the classes

\operatorname{Cl}(a)

and

\operatorname{Cl}(b)

are equal if and only if

and

are conjugate, and disjoint otherwise.) The equivalence class that contains the element

a\inG

\operatorname(a) = \left\

and is called the conjugacy class of

The of

is the number of distinct (nonequivalent) conjugacy classes. All elements belonging to the same conjugacy class have the same order.

Conjugacy classes may be referred to by describing them, or more briefly by abbreviations such as "6A", meaning "a certain conjugacy class with elements of order 6", and "6B" would be a different conjugacy class with elements of order 6; the conjugacy class 1A is the conjugacy class of the identity which has order 1. In some cases, conjugacy classes can be described in a uniform way; for example, in the symmetric group they can be described by cycle type.

Examples

The symmetric group

S_3,

consisting of the 6 permutations of three elements, has three conjugacy classes:

No change

(abc\toabc)

. The single member has order 1.

Transposing two

(abc\toacb,abc\tobac,abc\tocba)

. The 3 members all have order 2.

A cyclic permutation of all three

(abc\tobca,abc\tocab)

. The 2 members both have order 3.

These three classes also correspond to the classification of the isometries of an equilateral triangle.

The symmetric group

S_4,

consisting of the 24 permutations of four elements, has five conjugacy classes, listed with their description, cycle type, member order, and members:

No change. Cycle type = [14]. Order = 1. Members = . The single row containing this conjugacy class is shown as a row of black circles in the adjacent table.
Interchanging two (other two remain unchanged). Cycle type = [1221]. Order = 2. Members =). The 6 rows containing this conjugacy class are highlighted in green in the adjacent table.
A cyclic permutation of three (other one remains unchanged). Cycle type = [1131]. Order = 3. Members =). The 8 rows containing this conjugacy class are shown with normal print (no boldface or color highlighting) in the adjacent table.
A cyclic permutation of all four. Cycle type = [41]. Order = 4. Members =). The 6 rows containing this conjugacy class are highlighted in orange in the adjacent table.
Interchanging two, and also the other two. Cycle type = [22]. Order = 2. Members =). The 3 rows containing this conjugacy class are shown with boldface entries in the adjacent table.

The proper rotations of the cube, which can be characterized by permutations of the body diagonals, are also described by conjugation in

S_4.

In general, the number of conjugacy classes in the symmetric group

S_n

is equal to the number of integer partitions of
n.

This is because each conjugacy class corresponds to exactly one partition of
\{1,2,\ldots,n\}

into cycles, up to permutation of the elements of
\{1,2,\ldots,n\}.

In general, the Euclidean group can be studied by conjugation of isometries in Euclidean space.

Example

Let G =

S₃

a = (2 3)

x = (1 2 3)

x^-1 = (3 2 1)

Then xax^-1

= (1 2 3) (2 3) (3 2 1) = (3 1)

= (3 1) is Conjugate of (2 3)

Properties

The identity element is always the only element in its class, that is

\operatorname{Cl}(e)=\{e\}.

is abelian then

gag^-1=a

for all

a,g\inG

, i.e.

\operatorname{Cl}(a)=\{a\}

for all

a\inG

(and the converse is also true: if all conjugacy classes are singletons then

is abelian).

If two elements

a,b\inG

belong to the same conjugacy class (that is, if they are conjugate), then they have the same order. More generally, every statement about

can be translated into a statement about

b=gag^-1,

because the map

\varphi(x)=gxg^-1

is an automorphism of

called an inner automorphism. See the next property for an example.

and

are conjugate, then so are their powers

a^k

and

b^k.

(Proof: if

a=gbg^-1

then

a^k=\left(gbg^-1\right)\left(gbg^-1\right) … \left(gbg^-1\right)=gb^kg^-1.

) Thus taking th powers gives a map on conjugacy classes, and one may consider which conjugacy classes are in its preimage. For example, in the symmetric group, the square of an element of type (3)(2) (a 3-cycle and a 2-cycle) is an element of type (3), therefore one of the power-up classes of (3) is the class (3)(2) (where

is a power-up class of

a^k

An element

a\inG

lies in the center

\operatorname{Z}(G)

if and only if its conjugacy class has only one element,

itself. More generally, if

\operatorname{C}_G(a)

denotes the of

a\inG,

i.e., the subgroup consisting of all elements

such that

ga=ag,

then the index

\left[G:\operatorname{C}_G(a)\right]

is equal to the number of elements in the conjugacy class of

(by the orbit-stabilizer theorem).

Take

\sigma\inS_n

and let

m_1,m_2,\ldots,m_s

be the distinct integers which appear as lengths of cycles in the cycle type of

\sigma

(including 1-cycles). Let

k_i

be the number of cycles of length

m_i

\sigma

for each

i=1,2,\ldots,s

(so that

	s
\sum\limits
	i=1

k_im_i=n

). Then the number of conjugates of

\sigma

is:

\frac.

Conjugacy as group action

For any two elements

g,x\inG,

let

g \cdot x := gxg^.

This defines a group action of

The orbits of this action are the conjugacy classes, and the stabilizer of a given element is the element's centralizer.^[3]

Similarly, we can define a group action of

on the set of all subsets of

by writing

g \cdot S := gSg^,

or on the set of the subgroups of

Conjugacy class equation

is a finite group, then for any group element

the elements in the conjugacy class of

are in one-to-one correspondence with cosets of the centralizer

\operatorname{C}_G(a).

This can be seen by observing that any two elements

and

belonging to the same coset (and hence,

b=cz

for some

in the centralizer

\operatorname{C}_G(a)

) give rise to the same element when conjugating

bab^ = cza(cz)^ = czaz^c^ = cazz^c^ = cac^.

That can also be seen from the orbit-stabilizer theorem, when considering the group as acting on itself through conjugation, so that orbits are conjugacy classes and stabilizer subgroups are centralizers. The converse holds as well.

Thus the number of elements in the conjugacy class of

is the index

\left[G:\operatorname{C}_G(a)\right]

of the centralizer

\operatorname{C}_G(a)

; hence the size of each conjugacy class divides the order of the group.

Furthermore, if we choose a single representative element

x_i

from every conjugacy class, we infer from the disjointness of the conjugacy classes that

|G| = \sum_i \left[G : \operatorname{C}_G(x_i)\right],

where

\operatorname{C}_G(x_i)

is the centralizer of the element

x_i.

Observing that each element of the center

\operatorname{Z}(G)

forms a conjugacy class containing just itself gives rise to the class equation:^[4]

|G| = || + \sum_i \left[G : \operatorname{C}_G(x_i)\right],

where the sum is over a representative element from each conjugacy class that is not in the center.

Knowledge of the divisors of the group order

|G|

can often be used to gain information about the order of the center or of the conjugacy classes.

Example

(that is, a group with order

p^n,

where

is a prime number and

n>0

). We are going to prove that .

Since the order of any conjugacy class of

must divide the order of

it follows that each conjugacy class

H_i

that is not in the center also has order some power of

	k_i
p

where

0<k_i<n.

But then the class equation requires that

|G| = p^n = || + \sum_i p^.

From this we see that

must divide

|{\operatorname{Z}(G)}|,

|\operatorname{Z}(G)|>1.

In particular, when

n=2,

then

is an abelian group since any non-trivial group element is of order

p^2.

If some element

is of order

p^2,

then

is isomorphic to the cyclic group of order

p^2,

hence abelian. On the other hand, if every non-trivial element in

is of order

hence by the conclusion above

|\operatorname{Z}(G)|>1,

then

|\operatorname{Z}(G)|=p>1

p^2.

We only need to consider the case when

|\operatorname{Z}(G)|=p>1,

then there is an element

which is not in the center of

Note that

\operatorname{C}_G(b)

includes

and the center which does not contain

but at least

elements. Hence the order of

\operatorname{C}_G(b)

is strictly larger than

therefore

\left|\operatorname{C}_G(b)\right|=p^2,

therefore

is an element of the center of

a contradiction. Hence

is abelian and in fact isomorphic to the direct product of two cyclic groups each of order

Conjugacy of subgroups and general subsets

S\subseteqG

(

not necessarily a subgroup), define a subset

T\subseteqG

to be conjugate to

if there exists some

g\inG

such that

T=gSg^-1.

Let

\operatorname{Cl}(S)

be the set of all subsets

T\subseteqG

such that

is conjugate to

A frequently used theorem is that, given any subset

S\subseteqG,

the index of

\operatorname{N}(S)

(the normalizer of

) in

equals the cardinality of

\operatorname{Cl}(S)

|\operatorname{Cl}(S)|=[G:N(S)].

This follows since, if

g,h\inG,

then

gSg^-1=hSh^-1

if and only if

g^-1h\in\operatorname{N}(S),

in other words, if and only if

gandh

are in the same coset of

\operatorname{N}(S).

By using

S=\{a\},

this formula generalizes the one given earlier for the number of elements in a conjugacy class.

The above is particularly useful when talking about subgroups of

The subgroups can thus be divided into conjugacy classes, with two subgroups belonging to the same class if and only if they are conjugate.Conjugate subgroups are isomorphic, but isomorphic subgroups need not be conjugate. For example, an abelian group may have two different subgroups which are isomorphic, but they are never conjugate.

Geometric interpretation

Conjugacy classes in the fundamental group of a path-connected topological space can be thought of as equivalence classes of free loops under free homotopy.

Conjugacy class and irreducible representations in finite group

In any finite group, the number of nonisomorphic irreducible representations over the complex numbers is precisely the number of conjugacy classes.

References

Book: Grillet. Pierre Antoine . Abstract algebra. 2. Graduate texts in mathematics. 242. 2007. Springer. 978-0-387-71567-4.

Notes and References

Book: Dummit. David S.. Foote. Richard M.. Abstract Algebra. John Wiley & Sons. 2004. 3rd. 0-471-43334-9.
Book: Lang, Serge. Serge Lang. Algebra. Springer. Graduate Texts in Mathematics. 2002. 0-387-95385-X.
Grillet (2007), [{{Google books|plainurl=y|id=LJtyhu8-xYwC|page=56|text=the orbits are the conjugacy classes}} p. 56]
Grillet (2007), [{{Google books|plainurl=y|id=LJtyhu8-xYwC|page=57|text=The Class Equation}} p. 57]