Alternating groups are simple

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Statement

For n5, the Alternating group (?) An, i.e., the group of all even permutations on n letters, is a simple non-Abelian group.

Related facts

Facts used

  1. A5 is simple
  2. Normality satisfies transfer condition: The intersection of a normal subgroup of the whole group, with any subgroup, is normal in the subgroup.
  3. Even permutation IAPS is padding-contranormal: An is a contranormal subgroup inside An+1. More specifically, the even permutations fixing any particular letter form a contranormal subgroup of the group of all even permutations.

Proof

The proof is by induction on n.

Base case

The case n=5 is dealt with separately, by a direct argument. For full proof, refer: A5 is simple

Induction step

We prove that for n5, if An is simple, then An+1 is simple.

Given: An+1 is the group of even permutations on {1,2,3,,n+1}. N is a normal subgroup of An+1.

To prove: N=An+1 or N is trivial.

Proof: Let Hi denote the subgroup of An+1 that stabilizes the letter i. Then, each Hi consists of the even permutations on n letters (the letters excluding i) and is hence isomorphic to An. Thus, each Hi is simple.

Now, since normality satisfies transfer condition, NHi is normal in Hi for every i. By simplicity of Hi, either N contains Hi, or N intersects Hi trivially.

Suppose there exists i for which N contains Hi. Then, by fact (3) stated above, Hi is contranormal inside An+1, i.e., its normal closure is An+1. Since N is normal, this forces N=An+1, and we are done.

Otherwise, NHi is trivial for every i. Thus, no nontrivial element of N fixes any letter. Let's use this to show that N can have no nontrivial elements.

Suppose σN is nontrivial. Then, first observe that in the cycle decomposition of σ, every element must be in a cycle of the same length k (otherwise, some power of σ would fix a letter). Thus, σ has r cycles each of size k, where kr=n+1.

Now, if n5, then n+16. Choose an i and a double transposition τAn+1 such that τ fixes both i and σ(i), but such that τ does not commute with σ (this is possible because n+16). Then, σ1τστ1N is a nontrivial element of N fixing both i and σ(i), giving the required contradiction.