The Schur-Zassenhaus Theorem #
In this file we prove the Schur-Zassenhaus theorem.
Main results #
exists_right_complement'_of_coprime
: The Schur-Zassenhaus theorem: IfH : Subgroup G
is normal and has order coprime to its index, then there exists a subgroupK
which is a (right) complement ofH
.exists_left_complement'_of_coprime
: The Schur-Zassenhaus theorem: IfH : Subgroup G
is normal and has order coprime to its index, then there exists a subgroupK
which is a (left) complement ofH
.
The quotient of the transversals of an abelian normal N
by the diff
relation.
Equations
- One or more equations did not get rendered due to their size.
Instances For
Equations
- Subgroup.instInhabitedQuotientDiff H = id inferInstance
Equations
- One or more equations did not get rendered due to their size.
Proof of the Schur-Zassenhaus theorem #
In this section, we prove the Schur-Zassenhaus theorem.
The proof is by contradiction. We assume that G
is a minimal counterexample to the theorem.
We will arrive at a contradiction via the following steps:
- step 0:
N
(the normal Hall subgroup) is nontrivial. - step 1: If
K
is a subgroup ofG
withK ⊔ N = ⊤
, thenK = ⊤
. - step 2:
N
is a minimal normal subgroup, phrased in terms of subgroups ofG
. - step 3:
N
is a minimal normal subgroup, phrased in terms of subgroups ofN
. - step 4:
p
(min_fact (Fintype.card N)
) is prime (follows from step0). - step 5:
P
(a Sylowp
-subgroup ofN
) is nontrivial. - step 6:
N
is ap
-group (applies step 1 to the normalizer ofP
inG
). - step 7:
N
is abelian (applies step 3 to the center ofN
).
Do not use this lemma: It is made obsolete by exists_right_complement'_of_coprime
Schur-Zassenhaus for normal subgroups:
If H : Subgroup G
is normal, and has order coprime to its index, then there exists a
subgroup K
which is a (right) complement of H
.
Schur-Zassenhaus for normal subgroups:
If H : Subgroup G
is normal, and has order coprime to its index, then there exists a
subgroup K
which is a (right) complement of H
.
Schur-Zassenhaus for normal subgroups:
If H : Subgroup G
is normal, and has order coprime to its index, then there exists a
subgroup K
which is a (left) complement of H
.
Schur-Zassenhaus for normal subgroups:
If H : Subgroup G
is normal, and has order coprime to its index, then there exists a
subgroup K
which is a (left) complement of H
.