15.1: The Sylow Theorems

Theorem \(15.1\). Cauchy

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 \(G\text{:}\)

\[ |G| = |Z(G)| + [G: C(x_1) ] + \cdots + [ G: C(x_k)]\text{.} \nonumber \]

We have two cases.

Case 1.

Suppose the order of one of the centralizer subgroups, \(C(x_i)\text{,}\) is divisible by \(p\) for some \(i\text{,}\) \(i = 1, \ldots, k\text{.}\) In this case, by our induction hypothesis, we are done. Since \(C(x_i)\) is a proper subgroup of \(G\) and \(p\) divides \(|C(x_i)|\text{,}\) \(C(x_i)\) must contain an element of order \(p\text{.}\) Hence, \(G\) must contain an element of order \(p\text{.}\)

Case 2.

Suppose the order of no centralizer subgroup is divisible by \(p\text{.}\) Then \(p\) divides \([G:C(x_i)]\text{,}\) the order of each conjugacy class in the class equation; hence, \(p\) must divide the center of \(G\text{,}\) \(Z(G)\text{.}\) Since \(Z(G)\) is abelian, it must have a subgroup of order \(p\) by the Fundamental Theorem of Finite Abelian Groups. Therefore, the center of \(G\) contains an element of order \(p\text{.}\)

Corollary \(15.2\)

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

Theorem \(15.4\). First 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:

\[ |G| = |Z(G)| + [G: C(x_1) ] + \cdots + [ G: C(x_k)]\text{.} \nonumber \]

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 \(G\text{.}\)

Lemma \(15.5\)

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 \(x \in P\text{.}\)

Lemma \(15.6\)

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 \(H\text{.}\)

Theorem \(15.7\). Second 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

\[ {\mathcal S} = \{ P = P_1, P_2, \ldots, P_k \} \nonumber \]

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

\[ |G|= p^r m = |N(P)| \cdot [G: N(P)]= |N(P)| \cdot k\text{.} \nonumber \]

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 \(15.5\), \(P_j = Q\text{.}\)

Theorem \(15.8\)

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,

\[ {\mathcal S} = \{ P = P_1, P_2, \ldots, P_k \}\text{,} \nonumber \]

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 \(1\text{,}\) \(|{\mathcal S}| \equiv 1 \pmod{p}\text{.}\)

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 \(P \in {\mathcal S}\text{,}\)

\[ |{\mathcal S}| = |\text{orbit of }P| = [G : N(P)] \nonumber \]

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.