On groups whose subgroups are closed in the profinite topology

AbstractWe show that the wreath product of a finitely generated abelian group with a polycyclic group is a LERF group. This theorem yields as a corollary that finitely generated free metabelian groups are LERF, a result due to Coulbois. We also show that a free solvable group of class 3 and rank at least 2 does not contain a strictly ascending HNN-extension of a finitely generated group. Since such groups are known not to be LERF, this settles, in the negative, a question of J. O. Button.

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On the Profinite Topology on Negatively Curved Groups

Journal of Algebra ◽

10.1006/jabr.1998.7847 ◽

1999 ◽

Vol 219 (1) ◽

pp. 80-86 ◽

Cited By ~ 4

Author(s):

Rita Gitik

Keyword(s):

Negatively Curved ◽

Profinite Topology

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Finitely approximate groups and actions Part I: The Ribes–Zalesskiĭ property

Journal of Symbolic Logic ◽

10.2178/jsl/1318338850 ◽

2011 ◽

Vol 76 (4) ◽

pp. 1297-1306 ◽

Cited By ~ 5

Author(s):

Christian Rosendal

Keyword(s):

Metric Space ◽

Discrete Group ◽

Metric Spaces ◽

Finitely Generated ◽

Partial Isometries ◽

Profinite Topology

AbstractWe investigate extensions of S. Solecki's theorem on closing off finite partial isometries of metric spaces [11] and obtain the following exact equivalence: any action of a discrete group Γ by isometries of a metric space is finitely approximable if and only if any product of finitely generated subgroups of Γ is closed in the profinite topology on Γ.

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Factoriality and the Pin-Reutenauer procedure

Discrete Mathematics & Theoretical Computer Science ◽

10.46298/dmtcs.650 ◽

2016 ◽

Vol Vol. 18 no. 3 (Automata, Logic and Semantics) ◽

Author(s):

J. Almeida ◽

J. C. Costa ◽

M. Zeitoun

Keyword(s):

Free Group ◽

Free Algebra ◽

Natural Analogue ◽

Finitely Generated ◽

Finite Semigroups ◽

Rational Language ◽

Profinite Topology

We consider implicit signatures over finite semigroups determined by sets of pseudonatural numbers. We prove that, under relatively simple hypotheses on a pseudovariety V of semigroups, the finitely generated free algebra for the largest such signature is closed under taking factors within the free pro-V semigroup on the same set of generators. Furthermore, we show that the natural analogue of the Pin-Reutenauer descriptive procedure for the closure of a rational language in the free group with respect to the profinite topology holds for the pseudovariety of all finite semigroups. As an application, we establish that a pseudovariety enjoys this property if and only if it is full.

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ASH'S TYPE II THEOREM, PROFINITE TOPOLOGY AND MALCEV PRODUCTS: PART I

International Journal of Algebra and Computation ◽

10.1142/s0218196791000298 ◽

1991 ◽

Vol 01 (04) ◽

pp. 411-436 ◽

Cited By ~ 67

Author(s):

KARSTEN HENCKELL ◽

STUART W. MARGOLIS ◽

JEAN-ERIC PIN ◽

JOHN RHODES

Keyword(s):

Free Group ◽

Semigroup Theory ◽

Direct Proof ◽

Type Ii ◽

Finitely Generated ◽

Free Monoids ◽

Finite Monoids ◽

Rational Subset ◽

Block Groups ◽

Profinite Topology

This paper is concerned with the many deep and far reaching consequences of Ash's positive solution of the type II conjecture for finite monoids. After reviewing the statement and history of the problem, we show how it can be used to decide if a finite monoid is in the variety generated by the Malcev product of a given variety and the variety of groups. Many interesting varieties of finite monoids have such a description including the variety generated by inverse monoids, orthodox monoids and solid monoids. A fascinating case is that of block groups. A block group is a monoid such that every element has at most one semigroup inverse. As a consequence of the cover conjecture — also verified by Ash — it follows that block groups are precisely the divisors of power monoids of finite groups. The proof of this last fact uses earlier results of the authors and the deepest tools and results from global semigroup theory. We next give connections with the profinite group topologies on finitely generated free monoids and free groups. In particular, we show that the type II conjecture is equivalent with two other conjectures on the structure of closed sets (one conjecture for the free monoid and another one for the free group). Now Ash's theorem implies that the two topological conjectures are true and independently, a direct proof of the topological conjecture for the free group has been recently obtained by Ribes and Zalesskii. An important consequence is that a rational subset of a finitely generated free group G is closed in the profinite topology if and only if it is a finite union of sets of the form gH1H2…Hn, where g ∈ G and each Hi is a finitely generated subgroup of G. This significantly extends classical results of M. Hall. Finally, we return to the roots of this problem and give connections with the complexity theory of finite semigroups. We show that the largest local complexity function in the sense of Rhodes and Tilson is computable.

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On the profinite topology of right-angled Artin groups

Journal of Algebra ◽

10.1016/j.jalgebra.2008.03.031 ◽

2008 ◽

Vol 320 (3) ◽

pp. 1174-1181 ◽

Cited By ~ 4

Author(s):

V. Metaftsis ◽

E. Raptis

Keyword(s):

Artin Groups ◽

Right Angled Artin Groups ◽

Profinite Topology

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On The Profinite Topology on a Free Group

Bulletin of the London Mathematical Society ◽

10.1112/blms/25.1.37 ◽

1993 ◽

Vol 25 (1) ◽

pp. 37-43 ◽

Cited By ~ 65

Author(s):

Luis Ribes ◽

Pavel A. Zalesskii

Keyword(s):

Free Group ◽

Profinite Topology

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The Bass-Milnor-Serre theorem for nonstandard models in Peano arithmetic

Journal of Symbolic Logic ◽

10.2307/2275153 ◽

1993 ◽

Vol 58 (4) ◽

pp. 1451-1458

Author(s):

Anatole Khelif

Keyword(s):

Exact Sequence ◽

Finite Index ◽

Fundamental System ◽

Algebraic Number Field ◽

Peano Arithmetic ◽

Congruence Subgroups ◽

Open Set ◽

Nonstandard Models ◽

Image Position ◽

Profinite Topology

The aim of this paper is to extend the Bass-Milnor-Serre theorem to the nonstandard rings associated with nonstandard models of Peano arithmetic, in brief to Peano rings.First, we recall the classical setting. Let k be an algebraïc number field, and let θ be its ring of integers. Let n be an integer ≥ 3, and let G be the group Sln(θ) of (n, n) matrices of determinant 1 with coefficients in θ.The profinite topology in G is the topology having as fundamental system of open subgroups the subgroups of finite index.Congruence subgroups of finite index of G are the kernels of the maps Sln(θ) → Sln(θ/I) for which all ideals I of θ are of finite index. By taking these subgroups as a fundamental system of open subgroups, one obtains the congruence topology on G. Every open set for this topology is open in the profinite topology.We denote by Ḡ (resp., Ĝ) the completion of G for the congruence (resp., profinite) topology.The Bass-Milnor-Serre theorem [1] consists of the two following statements:(A) If k admits a real embedding, then we have an exact sequenceThat is, Ĝ and Ḡ are isomorphic.(B) If k is totally imaginary, then one has an exact sequencewhere μ(k)is the group of the roots of unity of k.

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