Grün's first theorem on the focal subgroup

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Statement

Suppose G is a finite group and P is a p-Sylow subgroup of G. Let P0 be the focal subgroup of P in G. Then:

P0=PNG(P),PQQSylp(G).

In other words, P0 is generated by the intersection between P and the commutator subgroup of its normalizer, along with the intersection between P and the commutator subgroups of all p-Sylow subgroups.

Facts used

  1. Focal subgroup theorem
  2. Alperin's fusion theorem in terms of tame intersections

Proof

Given: A finite group G with p-Sylow subgroup P having focal subgroup P0.

To prove: P0=P1 where:

P1=PNG(P),PQQSylp(G).

Proof:

Proof that P1P0

  1. P1P: This is clear, since all the subgroups used to generate P1 are contained in P.
  2. P1[G,G]: All the subgroups used to generate P1 are contained in the commutator subgroup of some subgroup, which in turn is contained in [G,G]. Thus, P1[G,G].
  3. P1P0: By the previous two steps, P1P[G,G]. By the focal subgroup theorem (fact (1)), P0=P[G,G], so P1P0.

Proof that P0P1

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References

Textbook references

  • Finite Groups by Daniel Gorenstein, ISBN 0821843427, Page 252, Theorem 4.2, Chapter 7 (Fusion, transfer and p-factor groups), Section 7.4 (Theorems of Burnside, Frobenius and Grün, More info