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In [[group theory]], a branch of [[mathematics]], '''Frattini's argument''' is an important [[Lemma (mathematics)|lemma]] in the structure theory of [[finite group]]s. It is named after [[Giovanni Frattini]], who first used it in a paper from 1885 when defining the [[Frattini subgroup]] of a group. | |||
==Statement and proof== | |||
<blockquote>'''Frattini's Argument.''' If ''G'' is a finite group with normal subgroup ''H'', and if ''P'' is a [[Sylow p-subgroup|Sylow ''p''-subgroup]] of ''H'', then | |||
:''G'' = ''N''<sub>''G''</sub>(''P'')''H'', | |||
where ''N''<sub>''G''</sub>(''P'') denotes the [[centralizer and normalizer|normalizer]] of ''P'' in ''G''.</blockquote> | |||
'''Proof''': ''P'' is a Sylow ''p''-subgroup of ''H'', so every Sylow ''p''-subgroup of ''H'' is an ''H''-conjugate ''h''<sup>−1</sup>''Ph'' for some ''h'' ∈ ''H'' (see [[Sylow theorems]]). Let ''g'' be any element of ''G''. Since ''H'' is normal in ''G'', the subgroup ''g''<sup>−1</sup>''Pg'' is contained in ''H''. This means that ''g''<sup>−1</sup>''Pg'' is a Sylow ''p''-subgroup of ''H''. Then by the above, it must be ''H''-conjugate to ''P'': that is, for some ''h'' ∈ ''H'' | |||
:''g''<sup>−1</sup>''Pg'' = ''h''<sup>−1</sup>''Ph'', | |||
so | |||
:''hg''<sup>−1</sup>''Pgh''<sup>−1</sup> = ''P''; | |||
thus | |||
:''gh''<sup>−1</sup> ∈ ''N''<sub>''G''</sub>(''P''), | |||
and therefore ''g'' ∈ ''N''<sub>''G''</sub>(''P'')''H''. But ''g'' ∈ ''G'' was arbitrary, so ''G'' = ''HN''<sub>''G''</sub>(''P'') = ''N''<sub>''G''</sub>(''P'')''H''. <math>\square</math> | |||
==Applications== | |||
* Frattini's argument can be used as part of a proof that any finite [[nilpotent group]] is a [[direct product of groups|direct product]] of its Sylow subgroups. | |||
* By applying Frattini's argument to ''N''<sub>''G''</sub>(''N''<sub>''G''</sub>(''P'')), it can be shown that ''N''<sub>''G''</sub>(''N''<sub>''G''</sub>(''P'')) = ''N''<sub>''G''</sub>(''P'') whenever ''G'' is a finite group and ''P'' is a Sylow ''p''-subgroup of ''G''. | |||
* More generally, if a subgroup ''M'' ≤ ''G'' contains ''N''<sub>''G''</sub>(''P'') for some Sylow ''p''-subgroup ''P'' of ''G'', then ''M'' is self-normalizing, ''i.e.'' ''M'' = ''N''<sub>''G''</sub>(''M''). | |||
::Proof: ''M'' is normal in ''H'' := ''N''<sub>''G''</sub>(''M''), and ''P'' is a Sylow ''p''-subgroup of ''M'', so the Frattini argument applied to the group ''H'' with normal subgroup ''M'' and Sylow ''p''-subgroup ''P'' gives ''N''<sub>''H''</sub>(''P'')''M'' = ''H''. Since ''N''<sub>''H''</sub>(''P'') ≤ ''N''<sub>''G''</sub>(''P'') ≤ ''M'', one has the chain of inclusions ''M'' ≤ ''H'' = ''N''<sub>''H''</sub>(''P'')''M'' ≤ ''M'' ''M'' = ''M'', so ''M'' = ''H''. <math>\square</math> | |||
==References== | |||
* {{Cite book | |||
| last = Hall | |||
| first = Marshall | |||
| authorlink = | |||
| coauthors = | |||
| title = The theory of groups | |||
| publisher = Macmillan | |||
| date = 1959 | |||
| location = New York, N.Y. | |||
| pages = | |||
| url = | |||
| doi = | |||
| id = | |||
| isbn = }} (See Chapter 10, especially Section 10.4.) | |||
{{DEFAULTSORT:Frattini's Argument}} | |||
[[Category:Group theory]] | |||
[[Category:Lemmas]] | |||
[[Category:Articles containing proofs]] | |||
Latest revision as of 07:04, 19 November 2013
In group theory, a branch of mathematics, Frattini's argument is an important lemma in the structure theory of finite groups. It is named after Giovanni Frattini, who first used it in a paper from 1885 when defining the Frattini subgroup of a group.
Statement and proof
Frattini's Argument. If G is a finite group with normal subgroup H, and if P is a Sylow p-subgroup of H, then
- G = NG(P)H,
where NG(P) denotes the normalizer of P in G.
Proof: P is a Sylow p-subgroup of H, so every Sylow p-subgroup of H is an H-conjugate h−1Ph for some h ∈ H (see Sylow theorems). Let g be any element of G. Since H is normal in G, the subgroup g−1Pg is contained in H. This means that g−1Pg is a Sylow p-subgroup of H. Then by the above, it must be H-conjugate to P: that is, for some h ∈ H
- g−1Pg = h−1Ph,
so
- hg−1Pgh−1 = P;
thus
- gh−1 ∈ NG(P),
and therefore g ∈ NG(P)H. But g ∈ G was arbitrary, so G = HNG(P) = NG(P)H.
Applications
- Frattini's argument can be used as part of a proof that any finite nilpotent group is a direct product of its Sylow subgroups.
- By applying Frattini's argument to NG(NG(P)), it can be shown that NG(NG(P)) = NG(P) whenever G is a finite group and P is a Sylow p-subgroup of G.
- More generally, if a subgroup M ≤ G contains NG(P) for some Sylow p-subgroup P of G, then M is self-normalizing, i.e. M = NG(M).
- Proof: M is normal in H := NG(M), and P is a Sylow p-subgroup of M, so the Frattini argument applied to the group H with normal subgroup M and Sylow p-subgroup P gives NH(P)M = H. Since NH(P) ≤ NG(P) ≤ M, one has the chain of inclusions M ≤ H = NH(P)M ≤ M M = M, so M = H.
References
- 20 year-old Real Estate Agent Rusty from Saint-Paul, has hobbies and interests which includes monopoly, property developers in singapore and poker. Will soon undertake a contiki trip that may include going to the Lower Valley of the Omo.
My blog: http://www.primaboinca.com/view_profile.php?userid=5889534 (See Chapter 10, especially Section 10.4.)