Inertial endomorphisms of an abelian group

Abstract: We describe inertial endomorphisms of an abelian group A, that is endomorphisms\ud ϕ with the property |(ϕ(X) + X)/X| < ∞ for each X ≤ A. They form a ring\ud I E(A) containing the ideal F(A) formed by the so-called finitary endomorphisms, the ring\ud of power endomorphisms and also other non-trivial instances.We show that the quotient ring\ud I E(A)/F(A) is commutative. Moreover, inertial invertible endomorphisms form a group,\ud provided A has finite torsion-free rank. In any case, the group I Aut(A) they gen… Show more

“…We recall that in [4], we called multiplications of an abelian group A either the actions on A of a subring of Q or, when A is periodic, the above action of J . Multiplications form a ring M (A).…”

“…The rank of F coincides with the torsion-free rank r 0 (A), that is the rank of the torsion free group A/T , where T = T (A) denotes the torsion subgroup of A, as usual. In Proposition 1 of [4] we noticed that when A is not periodic multiplications which are not by an integer are inertial iff the underlying abelian group A has finite torsion-free rank. For abelian groups with infinite torsion-free rank, case (a) in Characterization Theorem below.…”

“…In [4] we have proved the following Fact (and given a fruithful description of inertial endomorphisms as reported in the Characterization Theorem below).…”

“…We use an argument similar to one we used in the proof of Proposition 5 of [4]. Fix ϕ and suppose that either for each H ≤ A the group H + ϕ(H)/H is finite or for each H ≤ A the group H/H ∩ ϕ(H) is finite.…”

“…On the other side, we call inertial an endomorphism with respect to which each subgroup is inert. This property has been studied in [3] and [4] in connection with the study of inert subgroups of groups (see [1], [10], [14]). Recall that in non-abelian group context, a subgroup is said to be inert if it is commensurable with its conjugates (that is w.r.t.…”

On the ring of inertial endomorphisms of an abelian group

“…We recall that in [4], we called multiplications of an abelian group A either the actions on A of a subring of Q or, when A is periodic, the above action of J . Multiplications form a ring M (A).…”

“…The rank of F coincides with the torsion-free rank r 0 (A), that is the rank of the torsion free group A/T , where T = T (A) denotes the torsion subgroup of A, as usual. In Proposition 1 of [4] we noticed that when A is not periodic multiplications which are not by an integer are inertial iff the underlying abelian group A has finite torsion-free rank. For abelian groups with infinite torsion-free rank, case (a) in Characterization Theorem below.…”

“…In [4] we have proved the following Fact (and given a fruithful description of inertial endomorphisms as reported in the Characterization Theorem below).…”

“…We use an argument similar to one we used in the proof of Proposition 5 of [4]. Fix ϕ and suppose that either for each H ≤ A the group H + ϕ(H)/H is finite or for each H ≤ A the group H/H ∩ ϕ(H) is finite.…”

“…On the other side, we call inertial an endomorphism with respect to which each subgroup is inert. This property has been studied in [3] and [4] in connection with the study of inert subgroups of groups (see [1], [10], [14]). Recall that in non-abelian group context, a subgroup is said to be inert if it is commensurable with its conjugates (that is w.r.t.…”

On the ring of inertial endomorphisms of an abelian group

Groups in which each subgroup is commensurable with a normal subgroup

Topological entropy for locally linearly compact vector spaces