In mathematics, especially in the field of category theory, the concept of injective object is a generalization of the concept of injective module. This concept is important in cohomology, in homotopy theory and in the theory of model categories. The dual notion is that of a projective object.

Definition

An object Q in a category \mathbf{C} is said to be injective if for every monomorphism f: X \to Y and every morphism g: X \to Q there exists a morphism h: Y \to Q extending g to Y, i.e. such that. That is, every morphism X \to Q factors through every monomorphism. The morphism h in the above definition is not required to be uniquely determined by f and g. In a locally small category, it is equivalent to require that the hom functor carries monomorphisms in \mathbf{C} to surjective set maps.

In Abelian categories

The notion of injectivity was first formulated for abelian categories, and this is still one of its primary areas of application. When \mathbf{C} is an abelian category, an object Q of \mathbf{C} is injective if and only if its hom functor HomC(–,Q) is exact. If is an exact sequence in \mathbf{C} such that Q is injective, then the sequence splits.

Enough injectives and injective hulls

The category \mathbf{C} is said to have enough injectives if for every object X of \mathbf{C}, there exists a monomorphism from X to an injective object. A monomorphism g in \mathbf{C} is called an essential monomorphism if for any morphism f, the composite fg is a monomorphism only if f is a monomorphism. If g is an essential monomorphism with domain X and an injective codomain G, then G is called an injective hull of X. The injective hull is then uniquely determined by X up to a non-canonical isomorphism.

Examples

Uses

If an abelian category has enough injectives, we can form injective resolutions, i.e. for a given object X we can form a long exact sequence and one can then define the derived functors of a given functor F by applying F to this sequence and computing the homology of the resulting (not necessarily exact) sequence. This approach is used to define Ext, and Tor functors and also the various cohomology theories in group theory, algebraic topology and algebraic geometry. The categories being used are typically functor categories or categories of sheaves of OX modules over some ringed space (X, OX) or, more generally, any Grothendieck category.

Generalization

Let \mathbf{C} be a category and let \mathcal{H} be a class of morphisms of \mathbf{C}. An object Q of \mathbf{C} is said to be \mathcal{H}-injective if for every morphism f: A \to Q and every morphism h: A \to B in \mathcal{H} there exists a morphism g: B \to Q with. If \mathcal{H} is the class of monomorphisms, we are back to the injective objects that were treated above. The category \mathbf{C} is said to have enough \mathcal{H}-injectives if for every object X of \mathbf{C}, there exists an \mathcal{H}-morphism from X to an \mathcal{H}-injective object. A \mathcal{H}-morphism g in \mathbf{C} is called \mathcal{H}-essential if for any morphism f, the composite fg is in \mathcal{H} only if f is in \mathcal{H}. If g is a \mathcal{H}-essential morphism with domain X and an \mathcal{H}-injective codomain G, then G is called an \mathcal{H}-injective hull of X.

Examples of

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-injective objects