Dense submodule

In abstract algebra, specifically in module theory, a dense submodule of a module is a refinement of the notion of an essential submodule. If N is a dense submodule of M, it may also be said it may alternatively be said that "N ⊆ M is a rational extension". Dense submodules are connected with rings of quotients in noncommutative ring theory. Most of the results appearing here were first established in (Johnson 1951), (Utumi 1956) and (Findlay & Lambek 1958).

It should be noticed that this terminology is different from the notion of a dense subset in general topology. No topology is needed to define a dense submodule, and a dense submodule may or may not be topologically dense in a module with topology.

Contents

Definition

This article modifies exposition appearing in (Storrer 1972) and (Lam 1999, p. 272). Let R be a ring, and M be a right R module with submodule N. For an element y of M, define

y^{-1}N=\{r\in R \mid yr\in N \} \,

Note that the expression y−1 is only formal and that y is not necessarily invertible, but it helps to suggest that y⋅(y−1N) ⊆ N. The set y −1N is always a right ideal of R.

A submodule N of M is said to be a dense submodule if for all x and y in M with x ≠ 0, there exists an r in R such that xr ≠ {0} and yr is in N. In other words, using the introduced notation, the set

x(y^{-1}N)\neq\{0\} \,

In this case, the relationship is denoted by

N\subseteq_d M\,

Another equivalent definition is homological in nature: N is dense in M if and only if

\mathrm{Hom}_R (M/N,E(M))=\{0\}\,

where E(M) is the injective hull of M.

Properties

Examples

Applications

Rational hull of a module

Every right R module M has a maximal essential extension E(M) which is its injective hull. The analogous construction using a maximal dense extension results in the rational hull (M) which is a submodule of E(M). When a module has no proper rational extension, so that (M) = M, the module is said to be rationally complete. If R is right nonsingular, then of course (M) = E(M).

The rational hull is readily identified within the injective hull. Let S=EndR(E(M)) be the endomorphism ring of the injective hull. Then an element x of the injective hull is in the rational hull if and only if x is sent to zero by all maps in S which are zero on M. In symbols,

\tilde{E}(M)=\{x\in E(M) \mid \forall f\in S, f(M)=0 \implies f(x)=0\}\,

In general, there may be maps in S which are zero on M and yet are nonzero for some x not in M, and such an x would not be in the rational hull.

Maximal right ring of quotients

The maximal right ring of quotients can be described in two ways in connection with dense right ideals of R.

References