abstract algebra In mathematics, more specifically algebra, abstract algebra or modern algebra is the study of algebraic structures. Algebraic structures include group (mathematics), groups, ring (mathematics), rings, field (mathematics), fields, module (mathe ...

, specifically in

module theory In mathematics, a module is a generalization of the notion of vector space in which the field of scalars is replaced by a ring. The concept of ''module'' generalizes also the notion of abelian group, since the abelian groups are exactly the mo ...

, a dense submodule of a module is a refinement of the notion of an

essential submodule In mathematics, specifically module theory, given a ring ''R'' and an ''R''-module ''M'' with a submodule ''N'', the module ''M'' is said to be an essential extension of ''N'' (or ''N'' is said to be an essential submodule or large submodule of ''M ...

. If ''N'' is a dense submodule of ''M'', 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 , and . It should be noticed that this terminology is different from the notion of a

dense subset In topology and related areas of mathematics, a subset ''A'' of a topological space ''X'' is said to be dense in ''X'' if every point of ''X'' either belongs to ''A'' or else is arbitrarily "close" to a member of ''A'' — for instance, the ra ...

general topology In mathematics, general topology is the branch of topology that deals with the basic set-theoretic definitions and constructions used in topology. It is the foundation of most other branches of topology, including differential topology, geometri ...

. 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.

Definition

This article modifies

exposition Exposition (also the French for exhibition) may refer to: *Universal exposition or World's Fair * Expository writing ** Exposition (narrative) * Exposition (music) *Trade fair A trade fair, also known as trade show, trade exhibition, or trade e ...

appearing in and . Let ''R'' be a ring, and ''M'' be a right ''R'' module with submodule ''N''. For an element ''y'' of ''M'', define :

y^N=\ \,

Note that the expression ''y''⁻¹ is only formal since it is not meaningful to speak of the module-element ''y'' being

invertible In mathematics, the concept of an inverse element generalises the concepts of opposite () and reciprocal () of numbers. Given an operation denoted here , and an identity element denoted , if , one says that is a left inverse of , and that is ...

, but the notation helps to suggest that ''y''⋅(''y''⁻¹''N'') ⊆ ''N''. The set ''y'' ⁻¹''N'' is always a right

ideal Ideal may refer to: Philosophy * Ideal (ethics), values that one actively pursues as goals * Platonic ideal, a philosophical idea of trueness of form, associated with Plato Mathematics * Ideal (ring theory), special subsets of a ring considere ...

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'' ≠ and ''yr'' is in ''N''. In other words, using the introduced notation, the set :

x(y^N)\neq\ \,

In this case, the relationship is denoted by :

N\subseteq_d M\,

Another equivalent definition is

homological Homology may refer to: Sciences Biology *Homology (biology), any characteristic of biological organisms that is derived from a common ancestor * Sequence homology, biological homology between DNA, RNA, or protein sequences *Homologous chrom ...

in nature: ''N'' is dense in ''M'' if and only if :

\mathrm_R (M/N,E(M))=\\,

where ''E''(''M'') is the

injective hull In mathematics, particularly in algebra, the injective hull (or injective envelope) of a module is both the smallest injective module containing it and the largest essential extension of it. Injective hulls were first described in . Definition ...

of ''M''.

Properties

* It can be shown that ''N'' is an essential submodule of ''M'' if and only if for all ''y'' ≠ 0 in ''M'', the set ''y''⋅(''y'' ⁻¹''N'') ≠ . Clearly then, every dense submodule is an essential submodule. * If ''M'' is a

nonsingular module In the branches of abstract algebra known as ring theory and module theory, each right (resp. left) ''R''-module ''M'' has a singular submodule consisting of elements whose annihilators are essential right (resp. left) ideals in ''R''. In set not ...

, then ''N'' is dense in ''M'' if and only if it is essential in ''M''. * A ring is a right

nonsingular ring In the branches of abstract algebra known as ring theory and module theory, each right (resp. left) ''R''-module ''M'' has a singular submodule consisting of elements whose annihilators are essential right (resp. left) ideals in ''R''. In set no ...

if and only if its essential right ideals are all dense right ideals. * If ''N'' and ''N' '' are dense submodules of ''M'', then so is ''N'' ∩ ''N' ''. * If ''N'' is dense and ''N'' ⊆ ''K'' ⊆ ''M'', then ''K'' is also dense. * If ''B'' is a dense right ideal in ''R'', then so is ''y''⁻¹''B'' for any ''y'' in ''R''.

Examples

* If ''x'' is a non-zerodivisor in the

center Center or centre may refer to: Mathematics *Center (geometry), the middle of an object * Center (algebra), used in various contexts ** Center (group theory) ** Center (ring theory) * Graph center, the set of all vertices of minimum eccentrici ...

of ''R'', then ''xR'' is a dense right ideal of ''R''. * If ''I'' is a two-sided ideal of ''R'', ''I'' is dense as a right ideal if and only if the ''left'' annihilator of ''I'' is zero, that is,

\ell\cdot \mathrm(I)=\\,

. In particular in commutative rings, the dense ideals are precisely the ideals which are

faithful module In mathematics, the annihilator of a subset of a module over a ring is the ideal formed by the elements of the ring that give always zero when multiplied by an element of . Over an integral domain, a module that has a nonzero annihilator is a ...

Applications

Rational hull of a module

Every right ''R'' module ''M'' has a maximal essential extension ''E''(''M'') which is its

. The analogous construction using a maximal dense extension results in the rational hull ''Ẽ''(''M'') which is a submodule of ''E''(''M''). When a module has no proper rational extension, so that ''Ẽ''(''M'') = ''M'', the module is said to be rationally complete. If ''R'' is right nonsingular, then of course ''Ẽ''(''M'') = ''E''(''M''). The rational hull is readily identified within the injective hull. Let ''S''=End_''R''(''E''(''M'')) be the

endomorphism ring In mathematics, the endomorphisms of an abelian group ''X'' form a ring. This ring is called the endomorphism ring of ''X'', denoted by End(''X''); the set of all homomorphisms of ''X'' into itself. Addition of endomorphisms arises naturally in a ...

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(M)=\\,

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''. * In one method, ''Ẽ''(''R'') is shown to be module isomorphic to a certain endomorphism ring, and the ring structure is taken across this isomorphism to imbue ''Ẽ''(''R'') with a ring structure, that of the maximal right ring of quotients. * In a second method, the maximal right ring of quotients is identified with a set of equivalence classes of homomorphisms from dense right ideals of ''R'' into ''R''. The equivalence relation says that two functions are equivalent if they agree on a dense right ideal of ''R''.

References

* * * * *{{citation , last=Utumi , first=Yuzo , title=On quotient rings , journal=Osaka Mathematical Journal , volume=8 , year=1956 , pages=1–18 , mr=0078966 , doi=10.18910/8001 , doi-access=free Module theory Ring theory