Quasisimple group: Difference between revisions
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* <math>G</math> is [[perfect group|perfect]], that is, <math>G' = G</math> | * <math>G</math> is [[perfect group|perfect]], that is, <math>G' = G</math> | ||
* The [[inner automorphism group]] of <math>G</math> is a [[simple group]], that is, <math>G/Z(G)</math> is simple (where <math>Z(G)</math> denotes the center of <math>G</math>). | * The [[inner automorphism group]] of <math>G</math> is a [[simple group]], that is, <math>G/Z(G)</math> is simple (where <math>Z(G)</math> denotes the center of <math>G</math>). | ||
==Classification== | |||
{{further|[[Classification of finite simple groups]]}} | |||
The finite quasisimple groups can be completely classified in terms of the finite simple non-abelian groups. Specifically, for each finite simple non-abelian group <math>S</math>, consider the [[Schur multiplier]] and the corresponding [[Schur covering group]] (the unique [[universal central extension]]) <math>\hat S</math> with its map to <math>G</math>. The quasisimple groups with inner automorphism group <math>S</math> are precisey the groups <math>S</math> such that the map <math>\hat S \to S</math> can be factored in terms of a surjective map <math>\hat S \to G</math> and a surjective map <math>G \to S</math>. | |||
In particular, by the [[fourth isomorphism theorem]], these correspond precisely to the quotient groups (and hence to the subgroups, because of abelianness) of <math>\hat S/S</math>, which is the Schur multiplier of <math>S</math>. In particular, for each finite simple non-abelian groups, there are finitely many quasisimple groups associated with it. | |||
==Examples== | |||
{| class="sortable" border="1" | |||
! Finite simple non-abelian group !! Order !! Schur multiplier !! Schur covering group !! Quasisimple groups with this simple group as the inner automorphism group | |||
|- | |||
| [[alternating group:A5]] || 60 || [[cyclic group:Z2]] || [[special linear group:SL(2,5)]] || [[alternating group:A5]], [[special linear group:SL(2,5)]] | |||
|- | |||
| [[projective special linear group:PSL(3,2)]] (isomorphic to <math>PSL(2,7)</math>) || 168 || [[cyclic group:Z2]] || [[special linear group:SL(2,7)]] || [[projective special linear group:PSL(3,2)]], [[special linear group:SL(2,7)]] | |||
|- | |||
| [[alternating group:A6]] || 360 || [[cyclic group:Z6]] || [[Schur cover of alternating group:A6]] || [[alternating group:A6]], [[special linear group:SL(2,9)]], [[triple cover of alternating group:A6]], [[Schur cover of alternating group:A6]] | |||
|- | |||
| [[projective special linear group:PSL(2,8)]] || 504 || [[trivial group]] || [[projective special linear group:PSL(2,8)]] || [[projective special linear group:PSL(2,8)]] | |||
|- | |||
| [[projective special linear group:PSL(2,11)]] || 660 || [[cyclic group:Z2]] || [[special linear group:SL(2,11)]] || [[projective special linear group:PSL(2,11)]], [[special linear group:SL(2,11)]] | |||
|} | |||
==Relation with other properties== | ==Relation with other properties== | ||
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==Facts== | ==Facts== | ||
* The [[ | * The [[derived subgroup]] of an inner-simple group is quasisimple | ||
* Any normal subgroup of a quasisimple group is either the whole group, or is contained inside the [[center]] {{proofat|[[Proper and normal in quasisimple implies central]]}} | * Any normal subgroup of a quasisimple group is either the whole group, or is contained inside the [[center]] {{proofat|[[Proper and normal in quasisimple implies central]]}} | ||
Latest revision as of 02:25, 1 November 2013
This article defines a group property: a property that can be evaluated to true/false for any given group, invariant under isomorphism
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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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View a complete list of semi-basic definitions on this wiki
Definition
Symbol-free definition
A group is said to be quasisimple if it is perfect and its inner automorphism group is simple.
Definition with symbols
A group is said to be quasisimple if both the following hold:
- is perfect, that is,
- The inner automorphism group of is a simple group, that is, is simple (where denotes the center of ).
Classification
Further information: Classification of finite simple groups
The finite quasisimple groups can be completely classified in terms of the finite simple non-abelian groups. Specifically, for each finite simple non-abelian group , consider the Schur multiplier and the corresponding Schur covering group (the unique universal central extension) with its map to . The quasisimple groups with inner automorphism group are precisey the groups such that the map can be factored in terms of a surjective map and a surjective map .
In particular, by the fourth isomorphism theorem, these correspond precisely to the quotient groups (and hence to the subgroups, because of abelianness) of , which is the Schur multiplier of . In particular, for each finite simple non-abelian groups, there are finitely many quasisimple groups associated with it.
Examples
| Finite simple non-abelian group | Order | Schur multiplier | Schur covering group | Quasisimple groups with this simple group as the inner automorphism group |
|---|---|---|---|---|
| alternating group:A5 | 60 | cyclic group:Z2 | special linear group:SL(2,5) | alternating group:A5, special linear group:SL(2,5) |
| projective special linear group:PSL(3,2) (isomorphic to ) | 168 | cyclic group:Z2 | special linear group:SL(2,7) | projective special linear group:PSL(3,2), special linear group:SL(2,7) |
| alternating group:A6 | 360 | cyclic group:Z6 | Schur cover of alternating group:A6 | alternating group:A6, special linear group:SL(2,9), triple cover of alternating group:A6, Schur cover of alternating group:A6 |
| projective special linear group:PSL(2,8) | 504 | trivial group | projective special linear group:PSL(2,8) | projective special linear group:PSL(2,8) |
| projective special linear group:PSL(2,11) | 660 | cyclic group:Z2 | special linear group:SL(2,11) | projective special linear group:PSL(2,11), special linear group:SL(2,11) |
Relation with other properties
Stronger properties
Weaker properties
- Inner-simple group: A group whose inner automorphism group is simple
- Perfect group
- Group in which every proper normal subgroup is central: For full proof, refer: Proper and normal in quasisimple implies central
- Group in which every normal subgroup is a central factor
- T-group
- Directly indecomposable group
- Splitting-simple group
- Group in which every endomorphism is trivial or an automorphism is weaker than the property of being a finite quasisimple group. For full proof, refer: Finite quasisimple implies every endomorphism is trivial or an automorphism
Facts
- The derived subgroup of an inner-simple group is quasisimple
- Any normal subgroup of a quasisimple group is either the whole group, or is contained inside the center For full proof, refer: Proper and normal in quasisimple implies central
References
Textbook references
- Finite Group Theory (Cambridge Studies in Advanced Mathematics) by Michael Aschbacher, ISBN 0521786754More info, Page 156 (definition in paragraph)