Theorem5.1

The symmetric group on $n$ letters, $S_n\text{,}$ is a group with $n!$ elements, where the binary operation is the composition of maps.

Proof

The identity of $S_n$ is just the identity map that sends 1 to 1, 2 to 2, $\ldots\text{,}$ $n$ to $n\text{.}$ If $f : S_n \rightarrow S_n$ is a permutation, then $f^{-1}$ exists, since $f$ is one-to-one and onto; hence, every permutation has an inverse. Composition of maps is associative, which makes the group operation associative. We leave the proof that $|S_n|= n!$ as an exercise.

Example5.2

Consider the subgroup $G$ of $S_5$ consisting of the identity permutation $\identity$ and the permutations

The following table tells us how to multiply elements in the permutation group $G\text{.}$

Remark5.3

Though it is natural to multiply elements in a group from left to right, functions are composed from right to left. Let $\sigma$ and $\tau$ be permutations on a set $X\text{.}$ To compose $\sigma$ and $\tau$ as functions, we calculate $(\sigma \circ \tau)(x) = \sigma( \tau(x))\text{.}$ That is, we do $\tau$ first, then $\sigma\text{.}$ There are several ways to approach this inconsistency. We will adopt the convention of multiplying permutations right to left. To compute $\sigma \tau\text{,}$ do $\tau$ first and then $\sigma\text{.}$ That is, by $\sigma \tau (x)$ we mean $\sigma( \tau( x))\text{.}$ (Another way of solving this problem would be to write functions on the right; that is, instead of writing $\sigma(x)\text{,}$ we could write $(x)\sigma\text{.}$ We could also multiply permutations left to right to agree with the usual way of multiplying elements in a group. Certainly all of these methods have been used.

Example5.4

Permutation multiplication is not usually commutative. Let

Then

but

Example5.5

The permutation

is a cycle of length 6, whereas

is a cycle of length 3.

Not every permutation is a cycle. Consider the permutation

This permutation actually contains a cycle of length 2 and a cycle of length 4.

Example5.6

It is very easy to compute products of cycles. Suppose that

If we think of $\sigma$ as

and $\tau$ as

then for $\sigma \tau$ remembering that we apply $\tau$ first and then $\sigma\text{,}$ it must be the case that

or $\sigma \tau = (1 3 5 6 )\text{.}$ If $\mu = (1634)\text{,}$ then $\sigma \mu = (1 6 5 2)(3 4)\text{.}$

Example5.7

The cycles $(1 3 5)$ and $(2 7 )$ are disjoint; however, the cycles $(1 3 5)$ and $(3 4 7 )$ are not. Calculating their products, we find that

The product of two cycles that are not disjoint may reduce to something less complicated; the product of disjoint cycles cannot be simplified.

Proposition5.8

Let $\sigma$ and $\tau$ be two disjoint cycles in $S_X\text{.}$ Then $\sigma \tau = \tau \sigma\text{.}$

Proof

Let $\sigma = (a_1, a_2, \ldots, a_k )$ and $\tau = (b_1, b_2, \ldots, b_l )\text{.}$ We must show that $\sigma \tau(x) = \tau \sigma(x)$ for all $x \in X\text{.}$ If $x$ is neither in $\{ a_1, a_2, \ldots, a_k \}$ nor $\{b_1, b_2, \ldots, b_l \}\text{,}$ then both $\sigma$ and $\tau$ fix $x\text{.}$ That is, $\sigma(x)=x$ and $\tau(x)=x\text{.}$ Hence,

Do not forget that we are multiplying permutations right to left, which is the opposite of the order in which we usually multiply group elements. Now suppose that $x \in \{ a_1, a_2, \ldots, a_k \}\text{.}$ Then $\sigma( a_i ) = a_{(i \bmod k) + 1}\text{;}$ that is,

However, $\tau(a_i) = a_i$ since $\sigma$ and $\tau$ are disjoint. Therefore,

Similarly, if $x \in \{b_1, b_2, \ldots, b_l \}\text{,}$ then $\sigma$ and $\tau$ also commute.

Theorem5.9

Every permutation in $S_n$ can be written as the product of disjoint cycles.

Proof

We can assume that $X = \{ 1, 2, \ldots, n \}\text{.}$ If $\sigma \in S_n$ and we define $X_1$ to be $\{ \sigma(1), \sigma^2(1), \ldots \}\text{,}$ then the set $X_1$ is finite since $X$ is finite. Now let $i$ be the first integer in $X$ that is not in $X_1$ and define $X_2$ by $\{ \sigma(i), \sigma^2(i), \ldots \}\text{.}$ Again, $X_2$ is a finite set. Continuing in this manner, we can define finite disjoint sets $X_3, X_4, \ldots\text{.}$ Since $X$ is a finite set, we are guaranteed that this process will end and there will be only a finite number of these sets, say $r\text{.}$ If $\sigma_i$ is the cycle defined by

then $\sigma = \sigma_1 \sigma_2 \cdots \sigma_r\text{.}$ Since the sets $X_1, X_2, \ldots, X_r$ are disjoint, the cycles $\sigma_1, \sigma_2, \ldots, \sigma_r$ must also be disjoint.

Example5.10

Let

Using cycle notation, we can write

Remark5.11

From this point forward we will find it convenient to use cycle notation to represent permutations. When using cycle notation, we often denote the identity permutation by $(1)\text{.}$

Proposition5.12

Any permutation of a finite set containing at least two elements can be written as the product of transpositions.

Example5.13

Consider the permutation

As we can see, there is no unique way to represent permutation as the product of transpositions. For instance, we can write the identity permutation as $(1 2 )(1 2 )\text{,}$ as $(1 3 )(2 4 )(1 3 )( 2 4 )\text{,}$ and in many other ways. However, as it turns out, no permutation can be written as the product of both an even number of transpositions and an odd number of transpositions. For instance, we could represent the permutation $(1 6)$ by

or by

but $(1 6)$ will always be the product of an odd number of transpositions.

Lemma5.14

If the identity is written as the product of $r$ transpositions,

then $r$ is an even number.

Proof

We will employ induction on $r\text{.}$ A transposition cannot be the identity; hence, $r \gt 1\text{.}$ If $r=2\text{,}$ then we are done. Suppose that $r \gt 2\text{.}$ In this case the product of the last two transpositions, $\tau_{r-1} \tau_r\text{,}$ must be one of the following cases:

where $a\text{,}$ $b\text{,}$ $c\text{,}$ and $d$ are distinct.

The first equation simply says that a transposition is its own inverse. If this case occurs, delete $\tau_{r-1} \tau_r$ from the product to obtain

By induction $r - 2$ is even; hence, $r$ must be even.

In each of the other three cases, we can replace $\tau_{r - 1} \tau_r$ with the right-hand side of the corresponding equation to obtain a new product of $r$ transpositions for the identity. In this new product the last occurrence of $a$ will be in the next-to-the-last transposition. We can continue this process with $\tau_{r - 2} \tau_{r - 1}$ to obtain either a product of $r - 2$ transpositions or a new product of $r$ transpositions where the last occurrence of $a$ is in $\tau_{r - 2}\text{.}$ If the identity is the product of $r - 2$ transpositions, then again we are done, by our induction hypothesis; otherwise, we will repeat the procedure with $\tau_{r - 3} \tau_{r - 2}\text{.}$

At some point either we will have two adjacent, identical transpositions canceling each other out or $a$ will be shuffled so that it will appear only in the first transposition. However, the latter case cannot occur, because the identity would not fix $a$ in this instance. Therefore, the identity permutation must be the product of $r-2$ transpositions and, again by our induction hypothesis, we are done.

Theorem5.15

If a permutation $\sigma$ can be expressed as the product of an even number of transpositions, then any other product of transpositions equaling $\sigma$ must also contain an even number of transpositions. Similarly, if $\sigma$ can be expressed as the product of an odd number of transpositions, then any other product of transpositions equaling $\sigma$ must also contain an odd number of transpositions.

Proof

Suppose that

where $m$ is even. We must show that $n$ is also an even number. The inverse of $\sigma$ is $\sigma_m \cdots \sigma_1\text{.}$ Since

$n$ must be even by Lemma 5.14. The proof for the case in which $\sigma$ can be expressed as an odd number of transpositions is left as an exercise.

Theorem5.16

The set $A_n$ is a subgroup of $S_n\text{.}$

Proof

Since the product of two even permutations must also be an even permutation, $A_n$ is closed. The identity is an even permutation and therefore is in $A_n\text{.}$ If $\sigma$ is an even permutation, then

where $\sigma_i$ is a transposition and $r$ is even. Since the inverse of any transposition is itself,

is also in $A_n\text{.}$

Proposition5.17

The number of even permutations in $S_n\text{,}$ $n \geq 2\text{,}$ is equal to the number of odd permutations; hence, the order of $A_n$ is $n!/2\text{.}$

Proof

Let $A_n$ be the set of even permutations in $S_n$ and $B_n$ be the set of odd permutations. If we can show that there is a bijection between these sets, they must contain the same number of elements. Fix a transposition $\sigma$ in $S_n\text{.}$ Since $n \geq 2\text{,}$ such a $\sigma$ exists. Define

by

Suppose that $\lambda_{\sigma} ( \tau ) = \lambda_{\sigma} ( \mu )\text{.}$ Then $\sigma \tau = \sigma \mu$ and so

Therefore, $\lambda_{\sigma}$ is one-to-one. We will leave the proof that $\lambda_{\sigma}$ is surjective to the reader.

Example5.18

The group $A_4$ is the subgroup of $S_4$ consisting of even permutations. There are twelve elements in $A_4\text{:}$

One of the end-of-chapter exercises will be to write down all the subgroups of $A_4\text{.}$ You will find that there is no subgroup of order 6. Does this surprise you?