Commutator (group)
In a group, the commutator of two elements and , denoted or , is the element . If and commute, then . More generally, , or It then follows that We also have where denote the image of under the inner automorphism , as usual.
Relations with Commutators
Proposition 1. For all in a group, the following relations hold:
- ;
- ;
- ;
- ;
- .
Proof. For the first equation, we note that From the earlier relations, hence the relation. The second equation follows from the first by passing to inverses.
For the third equation, we define . We then note that By cyclic permutation of variables, we thus find
For the fourth equation, we have The fifth follows similarly.
Commutators and Subgroups
If and are subgroups of a group , denotes the subgroup generated by the set of commutators of the form , for and .
The group is trivial if and only if centralizes . Also, if and only if normalizes . If and are both normal (or characteristic), then so is , for if is an (inner) automorphism, then
Lemma. Let be a closed subsets of (not necessarily a subgroups); denote by the subgroup of generated by elements of the form , for , . Then .
Proof. Let be elements of and be an element of . Then
Proposition 2. Let be three subgroups of .
- The group normalizes the group .
- If the group normalizes , then the set of elements , for , , , generates the group .
Proof. For the first, we note that for any and any , by Proposition 1.
For the second, we have for any , , , , Since normalizes , the element lies in . It then follows from induction on that for all , , the element lies in the subgroup generated by elements of the form . Similarly, lies in the subgroup generated by elements of the form ; it then follows that does. Then using the observation we prove by induction on that the element lies in the subgroup generated by elements of the form . This proves the second result.