Snake lemmaThe snake lemma is a tool used in mathematics, particularly homological algebra, to construct long exact sequences. The snake lemma is valid in every and is a crucial tool in homological algebra and its applications, for instance in algebraic topology. Homomorphisms constructed with its help are generally called connecting homomorphisms. In an (such as the category of abelian groups or the category of vector spaces over a given field), consider a commutative diagram: where the rows are exact sequences and 0 is the zero object.
Image (category theory)In , a branch of mathematics, the image of a morphism is a generalization of the of a function. Given a and a morphism in , the image of is a monomorphism satisfying the following universal property: There exists a morphism such that . For any object with a morphism and a monomorphism such that , there exists a unique morphism such that . Remarks: such a factorization does not necessarily exist. is unique by definition of monic. therefore by monic. is monic. already implies that is unique.
Five lemmaIn mathematics, especially homological algebra and other applications of theory, the five lemma is an important and widely used lemma about commutative diagrams. The five lemma is not only valid for abelian categories but also works in the , for example. The five lemma can be thought of as a combination of two other theorems, the four lemmas, which are to each other. Consider the following commutative diagram in any (such as the category of abelian groups or the category of vector spaces over a given field) or in the category of groups.
Noetherian schemeIn algebraic geometry, a noetherian scheme is a scheme that admits a finite covering by open affine subsets , noetherian rings. More generally, a scheme is locally noetherian if it is covered by spectra of noetherian rings. Thus, a scheme is noetherian if and only if it is locally noetherian and quasi-compact. As with noetherian rings, the concept is named after Emmy Noether. It can be shown that, in a locally noetherian scheme, if is an open affine subset, then A is a noetherian ring.
Maschke's theoremIn mathematics, Maschke's theorem, named after Heinrich Maschke, is a theorem in group representation theory that concerns the decomposition of representations of a finite group into irreducible pieces. Maschke's theorem allows one to make general conclusions about representations of a finite group G without actually computing them. It reduces the task of classifying all representations to a more manageable task of classifying irreducible representations, since when the theorem applies, any representation is a direct sum of irreducible pieces (constituents).
Mitchell's embedding theoremMitchell's embedding theorem, also known as the Freyd–Mitchell theorem or the full embedding theorem, is a result about ; it essentially states that these categories, while rather abstractly defined, are in fact of modules. This allows one to use element-wise diagram chasing proofs in these categories. The theorem is named after Barry Mitchell and Peter Freyd. The precise statement is as follows: if A is a small abelian category, then there exists a ring R (with 1, not necessarily commutative) and a full, faithful and exact functor F: A → R-Mod (where the latter denotes the category of all left R-modules).
Pre-abelian categoryIn mathematics, specifically in , a pre-abelian category is an that has all and . Spelled out in more detail, this means that a category C is pre-abelian if: C is , that is over the of abelian groups (equivalently, all hom-sets in C are abelian groups and composition of morphisms is bilinear); C has all finite (equivalently, all finite coproducts); note that because C is also preadditive, finite products are the same as finite coproducts, making them biproducts; given any morphism f: A → B in C, the equaliser of f and the zero morphism from A to B exists (this is by definition the kernel of f), as does the coequaliser (this is by definition the cokernel of f).
CoimageIn algebra, the coimage of a homomorphism is the quotient of the domain by the kernel. The coimage is canonically isomorphic to the by the first isomorphism theorem, when that theorem applies. More generally, in , the coimage of a morphism is the dual notion of the .
Regular categoryIn , a regular category is a category with and coequalizers of a pair of morphisms called kernel pairs, satisfying certain exactness conditions. In that way, regular categories recapture many properties of abelian categories, like the existence of images, without requiring additivity. At the same time, regular categories provide a foundation for the study of a fragment of first-order logic, known as regular logic. A category C is called regular if it satisfies the following three properties: C is .
Weil cohomology theoryIn algebraic geometry, a Weil cohomology or Weil cohomology theory is a cohomology satisfying certain axioms concerning the interplay of algebraic cycles and cohomology groups. The name is in honor of André Weil. Any Weil cohomology theory factors uniquely through the of Chow motives, but the category of Chow motives itself is not a Weil cohomology theory, since it is not an . Fix a base field k of arbitrary characteristic and a "coefficient field" K of characteristic zero.
