11-1100-Pgadey-Lect6: Difference between revisions

Theory of Transitive ${\displaystyle G}$-sets

Theorem

Every ${\displaystyle G}$-set is a disjoint union of "transitive ${\displaystyle G}$-sets"

Theorem

Theorem

If ${\displaystyle X}$ is a transitive ${\displaystyle G}$-set and ${\displaystyle x\in X}$ then ${\displaystyle X\simeq G/Stab(x)}$ where the isomorphism an isomorphism of ${\displaystyle G}$-sets.

Transitive ${\displaystyle G}$-set

A ${\displaystyle G}$-set ${\displaystyle X}$ is transitive is ${\displaystyle \forall _{x,y\in X}\exists _{g\in G}\ st.\ gx=y}$.

Stabilizer of a point

We write ${\displaystyle Stab(x)=\{g\in G:gx=x\}}$ for the stabilizer subgroup of $x$.

Proof We define an equivalence relation ${\displaystyle x\sim y\iff \exists _{g\in G}gx=y}$. This relation is reflexive since ${\displaystyle x=ex}$ and thus ${\displaystyle x\sim x}$. This relation is symmetric since ${\displaystyle y=gx}$ implies ${\displaystyle g^{-1}y=x}$. This relation is transitive, since if ${\displaystyle x=gy}$ and ${\displaystyle y=hz}$ then ${\displaystyle x=ghz}$. It follows that ${\displaystyle X=\coprod _{i\in I}Gx_{i}}$ where ${\displaystyle Gx_{i}}$ denote the orbit of a point ${\displaystyle x_{i}}$.

We then claim that ${\displaystyle Gx_{i}}$ is a transitive ${\displaystyle G}$-set. [Dror: "[This fact] is too easy."]

We show that ${\displaystyle Gx}$ is isomorphic to ${\displaystyle G/Stab(x)}$ as a ${\displaystyle G}$-set.

We produce two morphism ${\displaystyle \Psi :Gx\rightarrow G/Stab(x)}$ and ${\displaystyle \Phi :G/Stab(x)\rightarrow Gx}$.

To define ${\displaystyle \Psi }$ there is only one thing we can do. We have ${\displaystyle y\in Gx\Rightarrow y=gx}$ and then we define ${\displaystyle \Psi (y)=gStab(x)}$. We check that this map is well defined. If ${\displaystyle y=gx=g'x}$ then ${\displaystyle g^{-1}g'x=x}$ and hence ${\displaystyle g^{-1}g\in Stab(x)}$. It follows that ${\displaystyle gStab(x)=g'Stab(x)}$. Thus ${\displaystyle \Psi }$ is well defined.

To define ${\displaystyle \Phi }$ we take ${\displaystyle gStab(x)\in G/Stab(x)}$ and define ${\displaystyle \Phi (gStab(x))=gx}$. We show that this map is well defined. If ${\displaystyle gStab(x)=g'Stab(x)}$ then ${\displaystyle g^{-1}g'\in Stab(x)}$ and hence ${\displaystyle g^{-1}g'x=x}$. It follows that ${\displaystyle gx=g'x}$ and hence ${\displaystyle \Phi }$ is well defined.

We need to check that ${\displaystyle \Psi }$ and ${\displaystyle \Phi }$ are mutually inverse and ${\displaystyle G}$-set morphisms. We quickly check that ${\displaystyle \Phi }$ is a ${\displaystyle G}$-set morphism. If ${\displaystyle y=gx}$ and ${\displaystyle g_{1}\in G}$ then ${\displaystyle g_{1}\Psi (y)=g_{1}(gStab(x))=(g_{1}g)Stab(x)}$. Similarly, ${\displaystyle \Psi (g_{1}y)=g'Stab(x)=(g_{1}g)Stab(x)}$. The last inequality follows since we can take any ${\displaystyle g'}$ such that ${\displaystyle g'y=g_{1}y}$. Why not take ${\displaystyle g'=g_{1}g}$ -- since we know that works.

Theorem (Orbit-Stabilizer)

If ${\displaystyle |X|<\infty }$ and ${\displaystyle X=\coprod _{i\in I}Gx_{i}}$ then ${\displaystyle |X|=\sum _{i}{\frac {|G|}{Stab(x_{i})}}}$.

This is just a rewriting of the theorem above.

${\displaystyle p}$-Group

A ${\displaystyle p}$-group is a group ${\displaystyle G}$ with ${\displaystyle |G|=p^{k}}$ for some ${\displaystyle k}$.

${\displaystyle G=(Z/2Z)^{3},(Z/2Z)\times (Z/4Z),Z/8Z,D_{8},Q=\{\pm 1,\pm i,\pm j,\pm k:i^{2}=j^{2}=k^{2}=-1,ij=k\}}$

The last group ${\displaystyle Q}$ is the famous unit quaternions -- They need a better description here.

Theorem

Any ${\displaystyle p}$-group has a non-trivial centre.

Let ${\displaystyle G}$ act on itself by conjugation. Decompose ${\displaystyle G=\coprod Gx_{i}}$. Then, ${\displaystyle |G|=\sum _{|Gx_{i}|=1}1+\sum _{|Gx_{i}|>1}{\frac {|G|}{|Stab(x)|}}}$ Observe that ${\displaystyle |Gx_{i}||=1}$ iff ${\displaystyle x_{i}\in Z(G)}$. It follows that ${\displaystyle |G|=|Z(G)|+\sum _{|Gx_{i}|>1}{\frac {|G|}{|Stab(x)|}}}$ The formula above is called "the class formula". We have that ${\displaystyle |G|/|Stab(x)|=p^{k}}$ for some ${\displaystyle 1<k}$ since ${\displaystyle Stab(x)}$ is a subgroup. It follows that ${\displaystyle |G|\equiv 0\mod \ p}$ and ${\displaystyle \sum _{|Gx_{i}|>1}{\frac {|G|}{|Stab(x_{i})|}}\equiv 0\mod \ p}$. It follows that ${\displaystyle |Z(G)|\equiv 0\mod \ p}$. Since ${\displaystyle e\in Z(G)}$ we have ${\displaystyle 1\leq |Z(G)|}$ and thus ${\displaystyle p\leq |Z(G)|}$.

Sylow

A prove a brief technical lemma, for fun, since we could deduce it from more high powered machinery which we don't have yet.

Cauchy's Lemma

If ${\displaystyle A}$ is an abelian group and ${\displaystyle p}$ divides ${\displaystyle |A|}$, then there is an element of order ${\displaystyle p}$ in ${\displaystyle A}$.

Proof. Pick ${\displaystyle x\in A}$. If ${\displaystyle p}$ divides the order of ${\displaystyle x}$ then we have ${\displaystyle x^{np}=e}$ for some ${\displaystyle n}$. It follows that ${\displaystyle (x^{n})^{p}=e}$. We then have that the order of ${\displaystyle x^{n}}$ is ${\displaystyle p}$. If ${\displaystyle p}$ does not divide the order of ${\displaystyle p}$, then consider ${\displaystyle A/<x>}$. Since ${\displaystyle A}$ is abelian, ${\displaystyle <x>}$ is a normal subgroup. We have that ${\displaystyle p}$ divides ${\displaystyle |A/<x>|}$, and ${\displaystyle |A/<x>|<|A|}$. We then induct. Let ${\displaystyle y<x>}$ have order ${\displaystyle p}$, that is ${\displaystyle (y<x>)^{p}=<x>}$. We then have that ${\displaystyle y^{p}=x^{k}}$ for some ${\displaystyle k}$. We write ${\displaystyle |<y>|=np+r}$ where ${\displaystyle 0\leq p<r}$. We then have ${\displaystyle e=y^{|<y>|}=y^{np+r}=x^{nkp}y^{r}\Rightarrow y^{r}\in <x>}$. It follows that ${\displaystyle (y<x>)^{r}=<x>}$ contradicting the assumption that the order of ${\displaystyle y<x>}$ is ${\displaystyle p}$.

Sylow set

If ${\displaystyle |G|=p^{k}m}$ for ${\displaystyle m\not \equiv 0\mod \ p}$ then ${\displaystyle Syl_{p}(G)=\{P\leq G:|P|=p^{k}}$.

Sylow I

${\displaystyle Syl_{p}(G)\neq \emptyset }$

We proceed by induction on the oder of $p$. Assume the claim holds for all groups of order less than $|G|$. [Dror: "Stare at the class equation."] Since ${\displaystyle |G|\equiv 0\mod \ p}$ we have either:

• ${\displaystyle |G|\equiv 0\mod \ p}$ and ${\displaystyle \sum |G|/|Stab(x_{i})|\equiv 0\mod \ p}$.
• ${\displaystyle |G|\not \equiv 0\mod \ p}$ and ${\displaystyle \sum |G|/|Stab(x_{i})|\not \equiv 0\mod \ p}$.

If ${\displaystyle |Z(G)|\not \equiv 0\ \mod p}$ then there exists ${\displaystyle x_{i}}$ such that ${\displaystyle |G|/|Stab(x_{i})|\not \equiv 0\mod \ p}$. Thus ${\displaystyle p^{k}}$ divides ${\displaystyle |Stab(x_{i})|}$. We have that ${\displaystyle |Stab(x_{i})|<|G|}$ [Why happens here?] We then have that ${\displaystyle p^{k}\leq Stab(x_{i})<|G|}$ and by induction there is ${\displaystyle |P|=p^{k}}$ such that ${\displaystyle P\leq Stab(x_{i})}$. It follows ${\displaystyle P\leq Stab(x_{i})\leq G}$. We've obtained the Sylow ${\displaystyle p}$-subgroup.

WIf ${\displaystyle |Z(G)|\equiv 0\ \mod p}$ then by Cauchy's Lemma, there is ${\displaystyle x\in Z(G)}$ with ${\displaystyle |<x>|=p}$. Consider the group ${\displaystyle G/<x>}$. By the induction hypothesis there is ${\displaystyle P'\leq G/<x>}$ where ${\displaystyle |P'|=p^{k-1}}$. Then, there is the canonical projection ${\displaystyle \pi :G\rightarrow G/<x>}$. By the fourth isomorphism theory ${\displaystyle P=\pi ^{-1}(P')\leq G}$ and ${\displaystyle |\pi ^{-1}(P')|=p(p^{k-1})=p^{k}}$.

Sylow 2

Every Sylow ${\displaystyle p}$-subgroup of ${\displaystyle G>isconjugate.Moreover,every<math>p}$-subgroup is contained in a Sylow ${\displaystyle p}$-subgroup.

Sylow 3

Let ${\displaystyle n_{p}(G)=|Syl_{p}(G)|}$. We have ${\displaystyle n_{p}\equiv 0\mod \ |G|}$ and ${\displaystyle n_{p}\equiv 1\mod \ p}$.

A Nearly Tautological Lemma

If ${\displaystyle P\in Syl_{p}(G)}$ and ${\displaystyle H\leq N(P)}$ is a ${\displaystyle p}$-group, then ${\displaystyle H\leq P}$.

If ${\displaystyle x\in G}$ has ${\displaystyle |<x>|=p^{k}}$ and ${\displaystyle x\in N(P)}$ then ${\displaystyle x\in P}$.

[Dror: "This lemma is nearly tautological but it is only nearly tautological once you understand that it is nearly tautological." Parker: "A tautology?"]

We show the first statement. We have that ${\displaystyle |P/P\cap H|=p^{k}}$ since ${\displaystyle P}$ is a ${\displaystyle p}$-group. We then know that ${\displaystyle PH/H\simeq P/P\cap H}$ by the second isomorphism theorem. It foolows that ${\displaystyle |PH|=p^{k'}}$. But since ${\displaystyle P}$ is maximal, we have ${\displaystyle P=PH}$ and thus ${\displaystyle H\subseteq P}$. The first statement implies the second by taking ${\displaystyle H=<x>}$.

Groups of Order 15

If ${\displaystyle |G|=15}$ then ${\displaystyle n_{3}\equiv 0\mod \ 15}$ and ${\displaystyle n_{3}\equiv 1\mod \ 3}$. These imply ${\displaystyle n_{3}=1}$. Moreover, ${\displaystyle n_{5}\equiv 0\mod \ 15}$ and ${\displaystyle n_{5}\equiv 1\mod \ 5}$. These imply ${\displaystyle n_{5}=1}$. Thus we have ${\displaystyle P_{3}}$ a normal ${\displaystyle 3}$-subgroup. Moreover, we have ${\displaystyle P_{5}}$ a normal ${\displaystyle 5}$-subgroup. This tells us a lot about the group.