Glauberman's replacement theorem: Difference between revisions

Revision as of 06:52, 14 August 2011

This article defines a replacement theorem
View a complete list of replacement theorems| View a complete list of failures of replacement

This article states and (possibly) proves a fact that is true for odd-order p-groups: groups of prime power order where the underlying prime is odd. The statement is false, in general, for groups whose order is a power of two.
View other such facts for p-groups|View other such facts for finite groups

Statement

Suppose $p$ is an odd prime, and $P$ is a $p$ -group. Let ${\mathcal {A}}(P)$ be the set of abelian subgroups of maximum order in $P$ and $J(P)$ be the Join of abelian subgroups of maximum order (?): the subgroup of $P$ generated by the members of ${\mathcal {A}}(P)$ .

Suppose $B$ is a Class two normal subgroup (?) of $P$ such that its Derived subgroup (?) is contained in the center of $J(P)$ ; in symbols:

$[B,B]\leq Z(J(P))$ .

If $A\in {\mathcal {A}}(P)$ is such that $B$ does not normalize $A$ , there exists $A^{*}\in {\mathcal {A}}(P)$ such that:

$A\cap B$ is a proper subgroup of $A^{*}\cap B$ .
$A^{*}$ normalizes $A$ .

Related facts

Breakdown at the prime two

Other replacement theorems

For a complete list of replacement theorems, refer:

Category:Replacement theorems

Applications

References

Textbook references

Finite Groups by Daniel Gorenstein, ISBN 0821843427, Page 274, Theorem 2.7, Section 8.2 (Glauberman's theorem), ^{More info}

Journal references

A characteristic subgroup of a p-stable group by George Isaac Glauberman, , Volume 20, Page 1101 - 1135(Year 1968): ^{More info}

@@ Line 6: / Line 6: @@
 Suppose <math>p</math> is an odd prime, and <math>P</math> is a <math>p</math>-group. Let <math>\mathcal{A}(P)</math> be the set of [[fact about::abelian subgroup of maximum order|abelian subgroups of maximum order]] in <math>P</math> and <math>J(P)</math> be the [[fact about::join of abelian subgroups of maximum order]]: the subgroup of <math>P</math> generated by the members of <math>\mathcal{A}(P)</math>.
-Suppose <math>B</math> is a [[fact about::class two normal subgroup]] of <math>P</math> such that its [[commutator subgroup]] is contained in the [[center]] of <math>J(P)</math>; in symbols:
+Suppose <math>B</math> is a [[fact about::class two normal subgroup]] of <math>P</math> such that its [[fact about::derived subgroup]] is contained in the [[center]] of <math>J(P)</math>; in symbols:
 <math>[B,B] \le Z(J(P))</math>.