Sylow theorems, proof of

We let $G$ be a group of order $p^{m}k$ where $p\nmid k$ and prove Sylow’s theorems.

First, a fact which will be used several times in the proof:

Proposition 1.

If $p$ divides the size of every conjugacy class outside the center then $p$ divides the order of the center.

Proof.

This follows from the class equation:

|G|=|Z(G)|+\sum_{[a]\neq Z(G)}|[a]|

If $p$ divides the left hand side, and divides all but one entry on the right hand side, it must divide every entry on the right side of the equation, so $p|Z(G)$ . ∎

Proposition 2.

$G$ has a Sylow p-subgroup

Proof.

By induction on $|G|$ . If $|G|=1$ then there is no $p$ which divides its order, so the condition is trivial.

Suppose $|G|=p^{m}k$ , $p\nmid k$ , and the holds for all groups of smaller order. Then we can consider whether $p$ divides the order of the center, $Z(G)$ .

If it does, then by Cauchy’s theorem, there is an element $f$ of $Z(G)$ of order $p$ , and therefore a cyclic subgroup generated by $f$ , $\langle f\rangle$ , also of order $p$ . Since this is a subgroup of the center, it is normal, so $G/\langle f\rangle$ is well-defined and of order $p^{m-1}k$ . By the inductive hypothesis, this group has a subgroup $P/\langle f\rangle$ of order $p^{m-1}$ . Then there is a corresponding subgroup $P$ of $G$ which has $|P|=|P/\langle f\rangle|\cdot|\langle f\rangle|=p^{m}$ .

On the other hand, if $p\nmid|Z(G)|$ then consider the conjugacy classes not in the center. By the proposition above, since $Z(G)$ is not divisible by $p$ , at least one conjugacy class can’t be. If $a$ is a representative of this class then we have $p\nmid|[a]|=[G:C(a)]$ , and since $|C(a)|\cdot[G:C(a)]=|G|$ , $p^{m}\mid|C(a)|$ . But $C(a)\neq G$ , since $a\notin Z(G)$ , so $C(a)$ has a subgroup of order $p^{m}$ , and this is also a subgroup of $G$ . ∎

Proposition 3.

The intersection of a Sylow p-subgroup with the normalizer of a Sylow p-subgroup is the intersection of the subgroups. That is, $Q\cap N_{G}(P)=Q\cap P$ .

Proof.

If $P$ and $Q$ are Sylow p-subgroups, consider $R=Q\cap N_{G}(P)$ . Obviously $Q\cap P\subseteq R$ . In addition, since $R\subseteq N_{G}(P)$ , the second isomorphism theorem tells us that $R P$ is a group, and $|RP|=\frac{|R|\cdot|P|}{|R\cap P|}$ . $P$ is a subgroup of $R P$ , so $p^{m}\mid|RP|$ . But $R$ is a subgroup of $Q$ and $P$ is a Sylow p-subgroup, so $|R|\cdot|P|$ is a multiple of $p$ . Then it must be that $|RP|=p^{m}$ , and therefore $P=RP$ , and so $R\subseteq P$ . Obviously $R\subseteq Q$ , so $R\subseteq Q\cap P$ . ∎

The following construction will be used in the remainder of the proof:

Given any Sylow p-subgroup $P$ , consider the set of its conjugates $C$ . Then $X\in C\leftrightarrow X=xPx^{-1}=\{xpx^{-1}|\forall p\in P\}$ for some $x\in G$ . Observe that every $X\in C$ is a Sylow p-subgroup (and we will show that the converse holds as well). We let $G$ act on $C$ by conjugation:

g\cdot X=g\cdot xPx^{-1}=gxPx^{-1}g^{-1}=(gx)P(gx)^{-1}

This is clearly a group action, so we can consider the orbits of $P$ under it; this remains true if we only consider elements from some subset of $G$ . Of course, if all $G$ is used then there is only one orbit, so we restrict the action to a Sylow p-subgroup $Q$ . the orbits $O_{1},\ldots,O_{s}$ , and let $P_{1},\ldots,P_{s}$ be representatives of the corresponding orbits. By the orbit-stabilizer theorem, the size of an orbit is the index of the stabilizer, and under this action the stabilizer of any $P_{i}$ is just $N_{Q}(P_{i})=Q\cap N_{G}(P_{i})=Q\cap P$ , so $|O_{i}|=[Q:Q\cap P_{i}]$ .

There are two easy results on this construction. If $Q=P_{i}$ then $|O_{i}|=[P_{i}:P_{i}\cap P_{i}]=1$ . If $Q\neq P_{i}$ then $[Q:Q\cap P_{i}]>1$ , and since the index of any subgroup of $Q$ divides $Q$ , $p\mid|O_{i}|$ .

Proposition 4.

The number of conjugates of any Sylow p-subgroup of $G$ is congruent to $1$ modulo $p$

In the construction above, let $Q=P_{1}$ . Then $|O_{1}|=1$ and $p\mid|O_{i}|$ for $i\neq 1$ . Since the number of conjugates of $P$ is the sum of the number in each orbit, the number of conjugates is of the form $1+k_{2}p+k_{3}p+\cdots+k_{s}p$ , which is obviously congruent to $1$ modulo $p$ .

Proposition 5.

Any two Sylow p-subgroups are conjugate

Proof.

Given a Sylow p-subgroup $P$ and any other Sylow p-subgroup $Q$ , consider again the construction given above. If $Q$ is not conjugate to $P$ then $Q\neq P_{i}$ for every $i$ , and therefore $p\mid|O_{i}|$ for every orbit. But then the number of conjugates of $P$ is divisible by $p$ , contradicting the previous result. Therefore $Q$ must be conjugate to $P$ . ∎

Proposition 6.

The number of subgroups of $G$ of order $p^{m}$ is congruent to $1$ modulo $p$ and is a factor of $k$

Proof.

Since conjugates of a Sylow p-subgroup are precisely the Sylow p-subgroups, and since a Sylow p-subgroup has $1$ modulo $p$ conjugates, there are $1$ modulo $p$ Sylow p-subgroups.

Since the number of conjugates is the index of the normalizer, it must be $|G:N_{G}(P)|$ . Since $P$ is a subgroup of its normalizer, $p^{m}\mid N_{G}(P)$ , and therefore $|G:N_{G}(P)|\mid k$ . ∎

Title	Sylow theorems, proof of
Canonical name	SylowTheoremsProofOf
Date of creation	2013-03-22 12:51:02
Last modified on	2013-03-22 12:51:02
Owner	Henry (455)
Last modified by	Henry (455)
Numerical id	12
Author	Henry (455)
Entry type	Proof
Classification	msc 20D20
Related topic	SylowPSubgroup
Related topic	SylowsThirdTheorem