Theorem15.1Cauchy

Let $G$ be a finite group and $p$ a prime such that $p$ divides the order of $G\text{.}$ Then $G$ contains a subgroup of order $p\text{.}$

Proof

We will use induction on the order of $G\text{.}$ If $|G|=p\text{,}$ then clearly $G$ itself is the required subgroup. We now assume that every group of order $k\text{,}$ where $p \leq k \lt n$ and $p$ divides $k\text{,}$ has an element of order $p\text{.}$ Assume that $|G|= n$ and $p \mid n$ and consider the class equation of $G\text{:}$

We have two cases.

Corollary15.2

Let $G$ be a finite group. Then $G$ is a $p$-group if and only if $|G| = p^n\text{.}$

Example15.3

Let us consider the group $A_5\text{.}$ We know that $|A_5| = 60 = 2^2 \cdot 3 \cdot 5\text{.}$ By Cauchy's Theorem, we are guaranteed that $A_5$ has subgroups of orders $2\text{,}$ $3$ and $5\text{.}$ The Sylow Theorems will give us even more information about the possible subgroups of $A_5\text{.}$

Theorem15.4First Sylow Theorem

Let $G$ be a finite group and $p$ a prime such that $p^r$ divides $|G|\text{.}$ Then $G$ contains a subgroup of order $p^r\text{.}$

Proof

We induct on the order of $G$ once again. If $|G| = p\text{,}$ then we are done. Now suppose that the order of $G$ is $n$ with $n \gt p$ and that the theorem is true for all groups of order less than $n\text{,}$ where $p$ divides $n\text{.}$ We shall apply the class equation once again:

First suppose that $p$ does not divide $[G:C(x_i)]$ for some $i\text{.}$ Then $p^r \mid |C(x_i)|\text{,}$ since $p^r$ divides $|G| = |C(x_i)| \cdot [G:C(x_i)]\text{.}$ Now we can apply the induction hypothesis to $C(x_i)\text{.}$

Hence, we may assume that $p$ divides $[G:C(x_i)]$ for all $i\text{.}$ Since $p$ divides $|G|\text{,}$ the class equation says that $p$ must divide $|Z(G)|\text{;}$ hence, by Cauchy's Theorem, $Z(G)$ has an element of order $p\text{,}$ say $g\text{.}$ Let $N$ be the group generated by $g\text{.}$ Clearly, $N$ is a normal subgroup of $Z(G)$ since $Z(G)$ is abelian; therefore, $N$ is normal in $G$ since every element in $Z(G)$ commutes with every element in $G\text{.}$ Now consider the factor group $G/N$ of order $|G|/p\text{.}$ By the induction hypothesis, $G/N$ contains a subgroup $H$ of order $p^{r- 1}\text{.}$ The inverse image of $H$ under the canonical homomorphism $\phi : G \rightarrow G/N$ is a subgroup of order $p^r$ in $G\text{.}$

Lemma15.5

Let $P$ be a Sylow $p$-subgroup of a finite group $G$ and let $x$ have as its order a power of $p\text{.}$ If $x^{-1} P x = P\text{,}$ then $x \in P\text{.}$

Proof

Certainly $x \in N(P)\text{,}$ and the cyclic subgroup, $\langle xP \rangle \subset N(P)/P\text{,}$ has as its order a power of $p\text{.}$ By the Correspondence Theorem there exists a subgroup $H$ of $N(P)$ containing $P$ such that $H/P = \langle xP \rangle\text{.}$ Since $|H| = |P| \cdot |\langle xP \rangle|\text{,}$ the order of $H$ must be a power of $p\text{.}$ However, $P$ is a Sylow $p$-subgroup contained in $H\text{.}$ Since the order of $P$ is the largest power of $p$ dividing $|G|\text{,}$ $H=P\text{.}$ Therefore, $H/P$ is the trivial subgroup and $xP = P\text{,}$ or $x \in P\text{.}$

Lemma15.6

Let $H$ and $K$ be subgroups of $G\text{.}$ The number of distinct $H$-conjugates of $K$ is $[H:N(K) \cap H]\text{.}$

Proof

We define a bijection between the conjugacy classes of $K$ and the right cosets of $N(K) \cap H$ by $h^{-1}Kh \mapsto (N(K) \cap H)h\text{.}$ To show that this map is a bijection, let $h_1, h_2 \in H$ and suppose that $(N(K) \cap H)h_1 = (N(K) \cap H)h_2\text{.}$ Then $h_2 h_1^{-1} \in N(K)\text{.}$ Therefore, $K = h_2 h_1^{-1} K h_1 h_2^{-1}$ or $h_1^{-1} K h_1 = h_2^{-1} K h_2\text{,}$ and the map is an injection. It is easy to see that this map is surjective; hence, we have a one-to-one and onto map between the $H$-conjugates of $K$ and the right cosets of $N(K) \cap H$ in $H\text{.}$

Theorem15.7Second Sylow Theorem

Let $G$ be a finite group and $p$ a prime dividing $|G|\text{.}$ Then all Sylow $p$-subgroups of $G$ are conjugate. That is, if $P_1$ and $P_2$ are two Sylow $p$-subgroups, there exists a $g \in G$ such that $g P_1 g^{-1} = P_2\text{.}$

Proof

Let $P$ be a Sylow $p$-subgroup of $G$ and suppose that $|G|=p^r m$ with $|P|=p^r\text{.}$ Let

consist of the distinct conjugates of $P$ in $G\text{.}$ By Lemma 15.6, $k = [G: N(P)]\text{.}$ Notice that

Since $p^r$ divides $|N(P)|\text{,}$ $p$ cannot divide $k\text{.}$

Given any other Sylow $p$-subgroup $Q\text{,}$ we must show that $Q \in {\mathcal S}\text{.}$ Consider the $Q$-conjugacy classes of each $P_i\text{.}$ Clearly, these conjugacy classes partition ${\mathcal S}\text{.}$ The size of the partition containing $P_i$ is $[Q :N(P_i) \cap Q]$ by Lemma 15.6, and Lagrange's Theorem tells us that $|Q| = [Q :N(P_i) \cap Q] |N(P_i) \cap Q|\text{.}$ Thus, $[Q :N(P_i) \cap Q]$ must be a divisor of $|Q|= p^r\text{.}$ Hence, the number of conjugates in every equivalence class of the partition is a power of $p\text{.}$ However, since $p$ does not divide $k\text{,}$ one of these equivalence classes must contain only a single Sylow $p$-subgroup, say $P_j\text{.}$ In this case, $x^{-1} P_j x = P_j$ for all $x \in Q\text{.}$ By Lemma 15.5, $P_j = Q\text{.}$

Theorem15.8Third Sylow Theorem

Let $G$ be a finite group and let $p$ be a prime dividing the order of $G\text{.}$ Then the number of Sylow $p$-subgroups is congruent to $1 \pmod{p}$ and divides $|G|\text{.}$

Proof

Let $P$ be a Sylow $p$-subgroup acting on the set of Sylow $p$-subgroups,

by conjugation. From the proof of the Second Sylow Theorem, the only $P$-conjugate of $P$ is itself and the order of the other $P$-conjugacy classes is a power of $p\text{.}$ Each $P$-conjugacy class contributes a positive power of $p$ toward $|{\mathcal S}|$ except the equivalence class $\{ P \}\text{.}$ Since $|{\mathcal S}|$ is the sum of positive powers of $p$ and 1, $|{\mathcal S}| \equiv 1 \pmod{p}\text{.}$

Now suppose that $G$ acts on ${\mathcal S}$ by conjugation. Since all Sylow $p$-subgroups are conjugate, there can be only one orbit under this action. For $P \in {\mathcal S}\text{,}$

by Lemma 15.6. But $[G : N(P)]$ is a divisor of $|G|\text{;}$ consequently, the number of Sylow $p$-subgroups of a finite group must divide the order of the group.