11-1100-Pgadey-Lect5: Difference between revisions

Simplicity of ${\displaystyle A_{n}}$.

Claim

${\displaystyle A_{n}}$ is simple for ${\displaystyle n\neq 4}$.

For ${\displaystyle n=1}$ we have that ${\displaystyle A_{n}=\{e\}}$ which is simple. For ${\displaystyle n=2}$ we have that ${\displaystyle S_{n}=\{(12),e\}}$, and once again ${\displaystyle A_{n}=\{e\}}$. For ${\displaystyle n=3}$ we have that ${\displaystyle A_{n}=\{e,(123),(132)\}\simeq Z/3Z}$ which is of prime order, and hence has no proper subgroups (by Lagrange). It follows that it has no normal proper subgroups.

For ${\displaystyle n=4}$ we have Dror's Favourite Homomorphism (the map ${\displaystyle S_{4}\rightarrow S_{3}}$ given by a coloured tetrahedron (link)

[This proof is not a deep conceptual proof. It is the product of a lot of playing around with cycles, and generators. This is much like a solution to the Rubik's cube, it naturally arises from a lot of playing around -- but is not conceptually deep at all.]

We proceed with some unmotivated computations: ${\displaystyle (12)(23)=(123)\quad \quad (12)(34)=(123)(234)}$ These are the main ingredients of the proof. The first equality says that a product of transpositions of non-disjoint pairs is a 3-cycle, the second equality says that the product of a pair of disjoint transpositions is a product of three cycles. Thus any product of two transpositions can be written a product of three cycles. [ The second equality is amusing with physical objects. ]

Lemma 1

${\displaystyle A_{n}}$ is generated by three cycles in ${\displaystyle S_{n}}$. That is, ${\displaystyle A_{n}=\langle \{(ijk)\in S_{n}\}\rangle }$.

We have that each element of ${\displaystyle A_{n}}$ is the product of an even number of transpositions (braid diagrams, computation with polynomials, etc). But we can replace a pair of 2-cycles with one or two 3-cycles by the computation above. It follows that any element of the alternating group can be rewritten as a product of 3-cycles.

Lemma 2

If ${\displaystyle N\triangleleft A_{n}}$ contains a 3-cycle then ${\displaystyle N=A_{n}}$.

Up to changing notation, we have that ${\displaystyle (123)\in N}$. We show that ${\displaystyle (123)^{\sigma }\in N}$ for any ${\displaystyle \sigma \in S_{n}}$. By normality, we have this for ${\displaystyle \sigma \in A_{n}}$. If ${\displaystyle \sigma \not \in A_{n}}$ we can write ${\displaystyle \sigma =(12)\sigma '}$ for ${\displaystyle \sigma \in A_{n}}$. But then ${\displaystyle (123)^{(12)}=(123)^{2}}$ and thus ${\displaystyle (123)^{\sigma }=\left((123)^{(12)}\right)^{\sigma '}\in N}$ Since all 3-cycles are conjugate to ${\displaystyle (123)}$ we have that all 3-cycles are in ${\displaystyle N}$. It follows by Lemma 1 that ${\displaystyle N=A_{n}}$.

Case I

${\displaystyle N}$ contains a cycle of length ${\displaystyle \geq 4}$.

${\displaystyle \sigma =(123456)\sigma '\in N\Rightarrow \sigma ^{-1}(123)\sigma (123)^{-1}=(136)\in N}$

The claim then follows by Lemma 2.

Case II

If ${\displaystyle N}$ contains an with two cycles of length 3.

${\displaystyle \sigma =(123)(456)\sigma '\in N\Rightarrow \sigma ^{-1}(124)\sigma (124)^{-1}=(14263)\in N}$

The claim then follows by Case I.

Case III

If ${\displaystyle N}$ contains ${\displaystyle \sigma =(123)({\textrm {aproductofdisjoint2-cycles}})}$

We have that ${\displaystyle \sigma ^{2}=(132)\in N}$. The claim then follows by Lemma 1.

Case IV

If every element of ${\displaystyle N}$ is a product of disjoint 2-cycles.

We have that ${\displaystyle \sigma =(12)(34)\sigma '\Rightarrow \sigma ^{-1}(123)\sigma (123)^{-1}=(13)(24)=\tau \in N}$ But then ${\displaystyle \tau ^{-1}(125)\tau (125)^{-1}=(13452)\in N}$. The claim then follows by Case 1.

[Note: This last case is the only place where we really use this mystical fifth element. Without it, this last step wouldn't go through.]

Throwback to ${\displaystyle S_{4}}$

Claim

${\displaystyle S_{4}}$ contains no normal ${\displaystyle H}$ such that ${\displaystyle H\simeq S_{3}}$.

${\displaystyle S_{3}}$ has an element of order three, therefore ${\displaystyle H}$ does. We then conjugate to get all the three cycles. Then ${\displaystyle H}$ is too big.

[ Suppose that ${\displaystyle (123)\in H}$, then

${\displaystyle S=\{e,(123),(132),(124),(142),(134),(143),(234),(243)\}\subset H}$

Which implies that ${\displaystyle |S_{3}|=6<9\leq |H|}$, but since ${\displaystyle H\simeq S_{3}}$ we have ${\displaystyle |H|=|S_{3}|}$, a contradiction.]

Group Actions

A group ${\displaystyle G}$ acting on a set ${\displaystyle X}$

A left (resp. right) group action of ${\displaystyle G}$ on ${\displaystyle X}$ is a binary map ${\displaystyle G\times X\rightarrow X}$ denotes by ${\displaystyle (g,x)\mapsto gx}$ satisfying:

• ${\displaystyle ex=x}$ (resp. ${\displaystyle xe=x}$)
• ${\displaystyle (g_{1}g_{2})x=g_{1}(g_{2}x)}$ (resp ${\displaystyle (xg_{1})g_{2}}$)
• [The above implies ${\displaystyle ex=x}$ and ${\displaystyle gy=x\Rightarrow g^{-1}y=x}$.]

Examples of group actions

• ${\displaystyle G}$ acting on itself by conjugation (a right action). ${\displaystyle (g,g')\mapsto g^{g'}}$
• Let ${\displaystyle S(X)}$ be the set of bijections from ${\displaystyle X}$ to ${\displaystyle X}$, with group structure given by composition. We then have an ${\displaystyle S(X)}$-action of ${\displaystyle X}$ given ${\displaystyle x\mapsto gx:X\rightarrow X\in S(X)}$

["Where does the shirt come into the business?!" Dror's remark after talking about the symmetry of a student's shirt.]

• If ${\displaystyle G=({\mathcal {G}},\cdot )}$ is a group where ${\displaystyle {\mathcal {S}}}$ is the underlying set of ${\displaystyle G}$ and ${\displaystyle \cdot }$ is the group multiplication. We have an action: ${\displaystyle (g,s)=g\cdot s}$ this gives a map ${\displaystyle G\rightarrow S({\mathcal {G}})}$.
• ${\displaystyle SO(n)}$ is the group of orientation preserving symmetries of the ${\displaystyle (n-1)}$-dimensional sphere. We have that ${\displaystyle SO(2)\leq SO(3)}$ as the subgroup of rotations that fix the north and south pole. There is a map ${\displaystyle SO(3)/SO(2)\rightarrow S^{2}}$ given by looking at the image of the north pole.
• If ${\displaystyle H\leq G}$ which may not be normal, then we have an action of ${\displaystyle G}$ on ${\displaystyle G/H}$ given by ${\displaystyle g(xH)=(gx)H}$.
• We have ${\displaystyle S_{n-1}\leq S_{n}}$ and ${\displaystyle |S_{n}/S_{n-1}|=n!/(n-1)!=n}$.

Exercise

Show that ${\displaystyle S_{n}}$ acting on ${\displaystyle \{1,2,\dots ,n\}}$ and ${\displaystyle S_{n}/S_{n-1}}$ are isomorphic ${\displaystyle S_{n}}$-sets.

[Dror violently resists rigorously defining a category. Gives a little speech about "things" and "arrows". Gives an example of taking a topological space ${\displaystyle T}$ and then looking at the space of paths with identities given by staying still, and composition of paths given by concatenation.]

Claim

Left ${\displaystyle G}$-sets form a category.

The objects of the category are actions ${\displaystyle G\times X\rightarrow X}$. The morphisms, if we have ${\displaystyle X}$ and ${\displaystyle Y}$ are ${\displaystyle G}$-sets, a morphism of ${\displaystyle G}$-sets is a function ${\displaystyle \gamma :X\rightarrow Y}$ such that ${\displaystyle \gamma (gx)=g(\gamma (x))}$.

Isomorphism of ${\displaystyle G}$-sets

An isomorphism of ${\displaystyle G}$-sets is a morphism which is bijective.

Silly fact

If ${\displaystyle X_{1}}$ and ${\displaystyle X_{2}}$ are ${\displaystyle G}$-sets then so is ${\displaystyle X_{1}\coprod X_{2}}$, the disjoint union of the two.

the next statement combines the silly observation above, with the construction of an action of ${\displaystyle G}$ on ${\displaystyle G/H}$.

Claim

Any ${\displaystyle G}$-set ${\displaystyle X}$ is a disjoint unions of the "transitive ${\displaystyle G}$-sets". And If ${\displaystyle Y}$ is a transitive ${\displaystyle G}$-set, then ${\displaystyle Y\simeq G/H}$ for some ${\displaystyle H\leq G}$.