Endomorphism ring

Description

Let (A, +) be an abelian group and we consider the group homomorphisms from A into A. Then addition of two such homomorphisms may be defined pointwise to produce another group homomorphism. Explicitly, given two such homomorphisms f and g, the sum of f and g is the homomorphism (f + g)(x) := f(x) + g(x). Under this operation End(A) is an abelian group. With the additional operation of composition of homomorphisms, End(A) is a ring with multiplicative identity. This composition is explicitly (fg)(x) := f(g(x)). The multiplicative identity is the identity homomorphism on A.

If the set A does not form an abelian group, then the above construction is not necessarily additive, as then the sum of two homomorphisms need not be a homomorphism. This set of endomorphisms is a canonical example of a near-ring which is not a ring.

Properties

Endomorphism rings always have additive and multiplicative identities, respectively the zero map and identity map.

Endomorphism rings are associative, but typically non-commutative.

If a module is simple, then its endomorphism ring is a division ring (this is sometimes called Schur's lemma).

A module is indecomposable if and only if its endomorphism ring does not contain any non-trivial idempotent elements. If the module is an injective module, then indecomposability is equivalent to the endomorphism ring being a local ring.

For a semisimple module, the endomorphism ring is a von Neumann regular ring.

The endomorphism ring of a nonzero right uniserial module has either one or two maximal right ideals. If the module is Artinian, Noetherian, projective or injective, then the endomorphism ring has a unique maximal ideal, so that it is a local ring.

The endomorphism ring of an Artinian uniform module is a local ring.

The endomorphism ring of a module with finite composition length is a semiprimary ring.

The endomorphism ring of a continuous module or discrete module is a clean ring.

If an R module is finitely generated and projective (that is, a progenerator), then the endomorphism ring of the module and R share all Morita invariant properties. A fundamental result of Morita theory is that all rings equivalent to R arise as endomorphism rings of progenerators.

Examples

In the category of R modules the endomorphism ring of an R-module M will only use the R module homomorphisms, which are typically a proper subset of the abelian group homomorphisms. When M is a finitely generated projective module, the endomorphism ring is central to Morita equivalence of module categories.

For any abelian group A , M n ( E n d ( A ) ) ≅ E n d ( A n ) , since any matrix in M n ( E n d ( A ) ) carries a natural homomorphism structure of A n as follows:

( ϕ 11 ⋯ ϕ 1 n ⋮ ⋮ ϕ n 1 ⋯ ϕ n n ) ( a 1 ⋮ a n ) = ( ∑ i = 1 n ϕ 1 i ( a i ) ⋮ ∑ i = 1 n ϕ n i ( a i ) ) . One can use this isomorphism to construct a lot of non-commutative endomorphism rings. For example: E n d ( Z × Z ) ≅ M 2 ( Z ) , since E n d ( Z ) ≅ Z . Also, when R = K is a field, there is a canonical isomorphism E n d ( K ) ≅ K , so E n d ( K n ) ≅ M n ( K ) , that is, the endomorphism ring of a K -vector space is identified with the ring of n-by-n matrices with entries in K . More generally, the endomorphism algebra of the free module M = R n is naturally n -by- n matrices with entries in the ring R .

As a particular example of the last point, for any ring R with unity, End(R_R) = R, where the elements of R act on R by left multiplication.

In general, endomorphism rings can be defined for the objects of any preadditive category.