Infinitely generated pseudocompact modules for finite groups and Weiss' Theorem

MacQuarrie, John; Symonds, Peter; Zalesskiĭ, Pavel

doi:10.1016/j.aim.2019.106925

Cited by 8 publications

(10 citation statements)

References 35 publications

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“…Let M be an .OGb/ e -module representing an element of Pic.OGb/. By Weiss' criterion (see [21], and [14] for a version allowing O as a coefficient ring) our M has trivial source if and only if the lattice of P -fixed points taken on the left To finish, let us briefly mention the following nice consequence of Theorems A and B, even though it is implied by [20,Theorem (38.6)], a theorem due to Puig. To state it, we need the notion of a splendid Morita equivalence.…”

Section: Proofs Of the Main Theorems And Applicationsmentioning

confidence: 99%

On the geometry of lattices and finiteness of Picard groups

Eisele

2021

Journal Für Die Reine Und Angewandte Mathematik (Crelles Journal)

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Let ( K , 𝒪 , k ) {(K,\mathcal{O},k)} be a p-modular system with k algebraically closed and 𝒪 {\mathcal{O}} unramified, and let Λ be an 𝒪 {\mathcal{O}} -order in a separable K-algebra. We call a Λ-lattice L rigid if Ext Λ 1 ⁡ ( L , L ) = 0 {{\operatorname{Ext}}^{1}_{\Lambda}(L,L)=0} , in analogy with the definition of rigid modules over a finite-dimensional algebra. By partitioning the Λ-lattices of a given dimension into “varieties of lattices”, we show that there are only finitely many rigid Λ-lattices L of any given dimension. As a consequence we show that if the first Hochschild cohomology of Λ vanishes, then the Picard group and the outer automorphism group of Λ are finite. In particular, the Picard groups of blocks of finite groups defined over 𝒪 {\mathcal{O}} are always finite.

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Section: Proofs Of the Main Theorems And Applicationsmentioning

confidence: 99%

On the geometry of lattices and finiteness of Picard groups

Eisele

2021

Journal Für Die Reine Und Angewandte Mathematik (Crelles Journal)

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“…Let

H

be a finite

p

‐group and

M

be a permutation pro‐

p

R [H]

‐module. (i)[, Corollary 2.3]:

0true M = ⨁_{K ⩽ H} \prod_{I_{K}} R [H / K]

, where

I_{K}

is some set of indices. (ii)[, Proposition 3.4]: Every direct summand

A

M

is a permutation module. Furthermore, there exists a subset

J_{K} \subseteq I_{K}

for each

K

such that

0true \prod_{K ⩽ H} \prod_{J_{K}} R [H / K]

complements

A

M

. (iii)[, Corollary 6.8]: If

U

is also permutation

{double-struckZ}_{p} false[H false]

‐module, then an extension of

M

U

splits and so is a permutation

{double-struckZ}_{p} false[H false]

‐module. …”

Section: Preliminariesmentioning

confidence: 99%

“…Hence

{\overset{M}{true}}^{N} = {\overset{M}{true}}_{1} \oplus {\overset{M}{true}}_{p}^{N}

is an

{double-struckF}_{p} false[G false]

‐decomposition and so by Proposition (ii)

{\bar{M}}_{1}

and

{\bar{M}}_{p}^{N}

are

{double-struckF}_{p} false[G false]

‐permutation, since

{\bar{M}}^{N}

is. By [, Theorem 8.6]

M_{1}

and

M_{p}^{N} ≅ M^{N} / M_{1}

are

{double-struckZ}_{p} false[G false]

‐monomial lattices, (that is, a direct product of lattices induced from a rank 1 lattices). Monomial

{double-struckZ}_{p} false[G false]

‐lattices are permutation

{double-struckZ}_{p} false[G false]

‐lattices for

p > 2

.…”

Section: Preliminariesmentioning

confidence: 99%

“…Monomial

{double-struckZ}_{p} false[G false]

‐lattices are permutation

{double-struckZ}_{p} false[G false]

‐lattices for

p > 2

. For

p = 2

we need to apply [, Lemma 8.4] to deduce that the

{double-struckZ}_{p} false[G false]

‐module

M^{N}

decomposes as

M^{N} ≅ M_{1} \oplus M_{p}^{N}

and hence by Proposition (ii)

M_{1}

and

M_{p}^{N} ≅ M^{N} / M_{1}

are

{double-struckZ}_{p} false[G false]

‐permutation. Applying Theorem we deduce that

M_{p}

is a

{double-struckZ}_{p} false[G false]

‐permutation module.…”

Section: Preliminariesmentioning

confidence: 99%

“…Namely, we prove that the abelianization

{\tilde{F}}^{a b}

is a permutation

{double-struckZ}_{p} false[H false]

‐module. Then we use the results of on infinitely generated

p

‐adic permutation modules and especially infinitely generated pro‐

p

version of the celebrated theorem of Weiss to prove the following theorem of independent interest. Theorem Let

G = F ⋊ H

be a semidirect product of a finite

p

‐group and a free pro‐

p

group

F

.…”

Section: Introductionmentioning

confidence: 99%

See 2 more Smart Citations

Infinitely generated virtually free pro‐p groups and p‐adic representations

Zalesskiĭ

2018

Journal of Topology

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We prove the pro‐p version of the Karras, Pietrowski, Solitar, Cohen and Scott result stating that a virtually free group acts on a tree with finite vertex stabilizers. If a virtually free pro‐p group G has finite centralizers of all non‐trivial torsion elements, a stronger statement is proved: G embeds into a free pro‐p product of a free pro‐p group and a finite p‐group. Integral p‐adic representation theory is used in the proof; it replaces the Stallings theory of ends in the pro‐p case.

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Block theory and Brauer's first main theorem for profinite groups

Flores

MacQuarrie

2022

Advances in Mathematics

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Infinitely generated pseudocompact modules for finite groups and Weiss' Theorem

Cited by 8 publications

References 35 publications

On the geometry of lattices and finiteness of Picard groups

On the geometry of lattices and finiteness of Picard groups

Infinitely generated virtually free pro‐p groups and p‐adic representations

Block theory and Brauer's first main theorem for profinite groups

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