Simple non-abelian group
This page describes a group property obtained as a conjunction (AND) of two (or more) more fundamental group properties: simple group and non-Abelian group
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This article is about a standard (though not very rudimentary) definition in group theory. The article text may, however, contain more than just the basic definition
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This article is about a term related to the Classification of finite simple groups
Definition
Symbol-free definition
A group is said to be a simple non-abelian group if:
- It is simple, i.e., it has no proper nontrivial normal subgroups
- It is not abelian, i.e., it is not true that any two elements in the group commute.
Facts
Every subgroup-defining function gives trivial group or whole group
Since any subgroup-defining function (such as the center, the commutator subgroup, the Frattini subgroup, the Fitting subgroup etc.) returns a characteristic subgroup of the whole group, and since every characteristic subgroup is normal, any subgroup obtained via a subgroup-defining function must be either trivial or the whole group. This, combined with the fact that the group is non-Abelian, tells us the following:
- The center must be trivial -- in other words, the group is centerless
- The commutator subgroup must be the whole group -- in other words, the group is perfect
Relation with other properties
Stronger properties
| Property | Meaning | Proof of implication | Proof of strictness (reverse implication failure) | Intermediate notions |
|---|---|---|---|---|
| infinite simple group | infinite and a simple group | the only simple abelian groups are the groups of prime order, which are all finite. | there are finite simple non-abelian groups | |
| finite simple non-abelian group | finite, simple, and non-abelian | direct | there are infinite simple groups, which are hence non-abelian. |
Weaker properties
| Property | Meaning | Proof of implication | Proof of strictness (reverse implication failure) | Intermediate notions |
|---|---|---|---|---|
| perfect group | equals its own derived subgroup | simple and non-abelian implies perfect | SL(2,5) is an example of a perfect group that is not simple. | |FULL LIST, MORE INFO |
| centerless group | its center is a trivial group | simple and non-abelian implies centerless | symmetric group:S3 is a centerless group that is not simple. | |FULL LIST, MORE INFO |
| quasisimple group | perfect group whose inner automorphism group is simple non-abelian. | simple and non-abelian implies quasisimple | SL(2,5), and more generally, any universal central extension of a simple non-abelian group that is not Schur-trivial, gives an example. | |FULL LIST, MORE INFO |
| semisimple group | central product of quasisimple groups. | (via quasisimple) | (via quasisimple) | |FULL LIST, MORE INFO |
| almost simple group | can be embedded between a simple non-abelian group and its automorphism group | (by definition) | symmetric group:S5 is an almost simple group that is not simple. More generally, the automorphism group of any simple non-abelian group that is not complete. | |FULL LIST, MORE INFO |
| capable group | can be expressed as the inner automorphism group of some group. | (via centerless) | (via centerless) | |FULL LIST, MORE INFO |