Orbit coherence in permutation groups

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Orbit coherence in permutation groups John R. Britnell Department of Mathematics Imperial College London j.britnell@imperial.ac.uk Groups St Andrews 2013 Joint work with Mark Wildon (RHUL)

Orbit partitions Let G be a group of permutations of a set Ω. Definitions For g G, write π(g) for the partition of Ω given by the orbits of g. Write π(g) = {π(g) g G}.

Orbit partitions Let G be a group of permutations of a set Ω. Definitions For g G, write π(g) for the partition of Ω given by the orbits of g. Write π(g) = {π(g) g G}. Example π(s 3 ) = { {{1}, {2}, {3} }, { { 1, 2}, {3} }, { {1, 3}, {2} }, { {1}, {2, 3} }, { {1, 2, 3} } }.

The partition lattice Let ρ and σ be partitions of Ω. Say ρ is a refinement of σ if every part of σ is a union of parts of ρ. We also say σ is a coarsening of ρ, and write ρ σ.

The partition lattice Let ρ and σ be partitions of Ω. Say ρ is a refinement of σ if every part of σ is a union of parts of ρ. We also say σ is a coarsening of ρ, and write ρ σ. Refinement is a partial order on the set P(Ω) of partitions of Ω.

The partition lattice Let ρ and σ be partitions of Ω. Say ρ is a refinement of σ if every part of σ is a union of parts of ρ. We also say σ is a coarsening of ρ, and write ρ σ. Refinement is a partial order on the set P(Ω) of partitions of Ω. The set P(Ω) is a lattice under the refinement order.

The partition lattice Let ρ and σ be partitions of Ω. Say ρ is a refinement of σ if every part of σ is a union of parts of ρ. We also say σ is a coarsening of ρ, and write ρ σ. Refinement is a partial order on the set P(Ω) of partitions of Ω. The set P(Ω) is a lattice under the refinement order. Any two partitions ρ and σ have a greatest common refinement ρ σ (their meet). a least common coarsening ρ σ (their join).

Coherence properties The set π(g) is a subset of P(Ω), and inherits the refinement order.

Coherence properties The set π(g) is a subset of P(Ω), and inherits the refinement order. The phrase orbit coherence refers generically to any interesting order-theoretic properties that π(g) may possess.

Coherence properties The set π(g) is a subset of P(Ω), and inherits the refinement order. The phrase orbit coherence refers generically to any interesting order-theoretic properties that π(g) may possess. For instance, π(g) may be a chain;

Coherence properties The set π(g) is a subset of P(Ω), and inherits the refinement order. The phrase orbit coherence refers generically to any interesting order-theoretic properties that π(g) may possess. For instance, π(g) may be a chain; a sublattice of P(Ω);

Coherence properties The set π(g) is a subset of P(Ω), and inherits the refinement order. The phrase orbit coherence refers generically to any interesting order-theoretic properties that π(g) may possess. For instance, π(g) may be a chain; a sublattice of P(Ω); a lower subsemilattice (meet-coherence); an upper subsemilattice (join-coherence).

Chains

Chains Theorem If π(g) is a chain, then there is a prime p such that every cycle of every element of G is of p-power length;

Chains Theorem If π(g) is a chain, then there is a prime p such that every cycle of every element of G is of p-power length; for each orbit O of G, the permutation group on O induced by the action of G is regular;

Chains Theorem If π(g) is a chain, then there is a prime p such that every cycle of every element of G is of p-power length; for each orbit O of G, the permutation group on O induced by the action of G is regular; if G acts transitively, then it is a subgroup of the Prüfer p-group.

Chains Theorem If π(g) is a chain, then there is a prime p such that every cycle of every element of G is of p-power length; for each orbit O of G, the permutation group on O induced by the action of G is regular; if G acts transitively, then it is a subgroup of the Prüfer p-group. An ingredient in the proof of the last part is that a group acting regularly is join-coherent if and only if it is locally cyclic.

Sublattices

Sublattices Examples Full symmetric groups; Bounded support groups, e.g. FS(Ω); Point-stabilizer, set-stabilizers, etc. in Sym(Ω).

Sublattices Examples Full symmetric groups; Bounded support groups, e.g. FS(Ω); Point-stabilizer, set-stabilizers, etc. in Sym(Ω). Theorem Let g Sym(Ω) and let G = Cent Sym(Ω) (g). Then π(g) is a sublattice if and only if g has only finitely many cycles of length k for all k > 1, and only finitely many infinite cycles.

Sublattices Examples Full symmetric groups; Bounded support groups, e.g. FS(Ω); Point-stabilizer, set-stabilizers, etc. in Sym(Ω). Theorem Let g Sym(Ω) and let G = Cent Sym(Ω) (g). Then π(g) is a sublattice if and only if g has only finitely many cycles of length k for all k > 1, and only finitely many infinite cycles. In particular, centralizers in S n always give sublattices.

Join-coherence structure theorems

Join-coherence structure theorems Theorem Let G 1 and G 2 be finite join-coherent permutation groups on Ω 1 and Ω 2 respectively. Then G 1 G 2 is join-coherent in its action on Ω 1 Ω 2 if and only if G 1 and G 2 have coprime orders.

Join-coherence structure theorems Theorem Let G 1 and G 2 be finite join-coherent permutation groups on Ω 1 and Ω 2 respectively. Then G 1 G 2 is join-coherent in its action on Ω 1 Ω 2 if and only if G 1 and G 2 have coprime orders. Theorem Let G 1 and G 2 be join-coherent permutation groups on Ω 1 and Ω 2, where Ω 2 is finite. Then the wreath product G 1 G 2 is join-coherent in its action on Ω 1 Ω 2.

Join-coherence structure theorems Theorem Let G 1 and G 2 be finite join-coherent permutation groups on Ω 1 and Ω 2 respectively. Then G 1 G 2 is join-coherent in its action on Ω 1 Ω 2 if and only if G 1 and G 2 have coprime orders. Theorem Let G 1 and G 2 be join-coherent permutation groups on Ω 1 and Ω 2, where Ω 2 is finite. Then the wreath product G 1 G 2 is join-coherent in its action on Ω 1 Ω 2. Corollary For i N let G i be a join-coherent permutation group on the finite set Ω i. Then the profinite wreath product G 2 G 1 is join-coherent on i N Ω i.

Primitive join-coherent groups Let G be a finitely generated transitive permutation group on Ω. If G is join-coherent, then it contains a full cycle.

Primitive join-coherent groups Let G be a finitely generated transitive permutation group on Ω. If G is join-coherent, then it contains a full cycle. Theorem The finite primitive join-coherent groups are S n in its natural action; transitive subgroups of AGL 1 (p).

Groups normalizing a full cycle

Groups normalizing a full cycle Theorem Let G be a permutation group on n points which normalizes an n-cycle. Let n have prime factorization i pa i i. Then G is join-coherent if and only if it is isomorphic to i G i, where G i is a transitive permutation group on p a i i points, the orders of the groups G i are mutually coprime, and one of the following holds for each i:

Groups normalizing a full cycle Theorem Let G be a permutation group on n points which normalizes an n-cycle. Let n have prime factorization i pa i i. Then G is join-coherent if and only if it is isomorphic to i G i, where G i is a transitive permutation group on p a i i points, the orders of the groups G i are mutually coprime, and one of the following holds for each i: G i is cyclic of order p a i i,

Groups normalizing a full cycle Theorem Let G be a permutation group on n points which normalizes an n-cycle. Let n have prime factorization i pa i i. Then G is join-coherent if and only if it is isomorphic to i G i, where G i is a transitive permutation group on p a i i points, the orders of the groups G i are mutually coprime, and one of the following holds for each i: G i is cyclic of order p a i i, a i = 1 and G i is a transitive subgroup of AGL 1 (p i ),

Groups normalizing a full cycle Theorem Let G be a permutation group on n points which normalizes an n-cycle. Let n have prime factorization i pa i i. Then G is join-coherent if and only if it is isomorphic to i G i, where G i is a transitive permutation group on p a i i points, the orders of the groups G i are mutually coprime, and one of the following holds for each i: G i is cyclic of order p a i i, a i = 1 and G i is a transitive subgroup of AGL 1 (p i ), a i > 1 and G i is the extension of a cyclic group of order p a i i the automorphism x x r, where r = p a i 1 i + 1. by

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