Cyclic module

Last updated October 17, 2022

In mathematics, more specifically in ring theory, a cyclic module or monogenous module^[1] is a module over a ring that is generated by one element. The concept is a generalization of the notion of a cyclic group, that is, an Abelian group (i.e. Z-module) that is generated by one element.

Definition

A left R-module M is called cyclic if M can be generated by a single element i.e. M = (x) = Rx = {rx | r ∈ R} for some x in M. Similarly, a right R-module N is cyclic if N = yR for some y ∈ N.

Examples

2Z as a Z-module is a cyclic module.
In fact, every cyclic group is a cyclic Z-module.
Every simple R-module M is a cyclic module since the submodule generated by any non-zero element x of M is necessarily the whole module M. In general, a module is simple if and only if it is nonzero and is generated by each of its nonzero elements.^[2]
If the ring R is considered as a left module over itself, then its cyclic submodules are exactly its left principal ideals as a ring. The same holds for R as a right R-module, mutatis mutandis.
If R is F[x], the ring of polynomials over a field F, and V is an R-module which is also a finite-dimensional vector space over F, then the Jordan blocks of x acting on V are cyclic submodules. (The Jordan blocks are all isomorphic to F[x] / (x − λ)ⁿ; there may also be other cyclic submodules with different annihilators; see below.)

Properties

Given a cyclic R-module M that is generated by x, there exists a canonical isomorphism between M and R / Ann_Rx, where Ann_Rx denotes the annihilator of x in R.

Every module is a sum of cyclic submodules.^[3]

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References

↑ Bourbaki, Algebra I: Chapters 1–3, p. 220
↑ Anderson & Fuller 1992 , Just after Proposition 2.7.
↑ Anderson & Fuller 1992 , Proposition 2.7.

Anderson, Frank W.; Fuller, Kent R. (1992), Rings and categories of modules, Graduate Texts in Mathematics, vol. 13 (2 ed.), New York: Springer-Verlag, pp. x+376, doi:10.1007/978-1-4612-4418-9, ISBN 0-387-97845-3, MR 1245487
B. Hartley; T.O. Hawkes (1970). Rings, modules and linear algebra . Chapman and Hall. pp. 77, 152. ISBN 0-412-09810-5.
Lang, Serge (1993), Algebra (Third ed.), Reading, Mass.: Addison-Wesley, pp. 147–149, ISBN 978-0-201-55540-0, Zbl 0848.13001

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[1] Bourbaki, Algebra I: Chapters 1–3, p. 220

[2] Anderson & Fuller 1992 , Just after Proposition 2.7.

[3] Anderson & Fuller 1992 , Proposition 2.7.

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