Quotient of an abelian category

In mathematics, the quotient (also called Serre quotient or Gabriel quotient) of an abelian category ${\mathcal {A}}$ by a Serre subcategory ${\mathcal {B}}$ is the abelian category ${\mathcal {A}}/{\mathcal {B}}$ which, intuitively, is obtained from ${\mathcal {A}}$ by ignoring (i.e. treating as zero) all objects from ${\mathcal {B}}$ . There is a canonical exact functor $Q\colon {\mathcal {A}}\to {\mathcal {A}}/{\mathcal {B}}$ whose kernel is ${\mathcal {B}}$ .

Definition[]

Formally, ${\mathcal {A}}/{\mathcal {B}}$ is the category whose objects are those of ${\mathcal {A}}$ and whose morphisms from X to Y are given by the direct limit (of abelian groups) $\varinjlim \mathrm {Hom} _{\mathcal {A}}(X',Y/Y')$ over subobjects $X'\subseteq X$ and $Y'\subseteq Y$ such that $X/X'\in {\cal {B}}$ and $Y'\in {\cal {B}}$ . (Here, $X/X'$ and $Y/Y'$ denote quotient objects computed in ${\mathcal {A}}$ .) Composition of morphisms in ${\mathcal {A}}/{\mathcal {B}}$ is induced by the universal property of the direct limit.

The canonical functor $Q\colon {\mathcal {A}}\to {\mathcal {A}}/{\mathcal {B}}$ sends an object X to itself and a morphism $f\colon X\to Y$ to the corresponding element of the direct limit with X′ = X and Y′ = 0.

Examples[]

Let $k$ be a field and consider the abelian category ${\rm {Mod}}(k)$ of all vector spaces over $k$ . Then the full subcategory ${\rm {mod}}(k)$ of finite-dimensional vector spaces is a Serre-subcategory of ${\rm {Mod}}(k)$ . The quotient ${\cal {{C}={\rm {Mod}}(k)/{\rm {mod}}(k)}}$ has as objects the $k$ -vector spaces, and the set of morphisms from $X$ to $Y$ in ${\cal {C}}$ is

\{k{\text{-linear maps from }}X{\text{ to }}Y\}/\{k{\text{-linear maps from }}X{\text{ to }}Y{\text{ with finite-dimensional image}}\}

(which is a quotient of vector spaces). This has the effect of identifying all finite-dimensional vector spaces with 0, and of identifying two linear maps whenever their difference has finite-dimensional image.

Properties[]

The quotient ${\mathcal {A}}/{\mathcal {B}}$ is an abelian category, and the canonical functor $Q\colon {\mathcal {A}}\to {\mathcal {A}}/{\mathcal {B}}$ is exact. The kernel of $Q$ is ${\mathcal {B}}$ , i.e., $Q(X)$ is a zero object of ${\mathcal {A}}/{\mathcal {B}}$ if and only if $X$ belongs to ${\mathcal {B}}$ .

The quotient and canonical functor are characterized by the following universal property: if ${\mathcal {C}}$ is any abelian category and $F\colon {\mathcal {A}}\to {\mathcal {C}}$ is an exact functor such that $F(X)$ is a zero object of ${\mathcal {C}}$ for each object $X\in {\mathcal {B}}$ , then there is a unique exact functor ${\overline {F}}\colon {\mathcal {A}}/{\mathcal {B}}\to {\mathcal {C}}$ such that $F={\overline {F}}\circ Q$ .^[1]

Gabriel–Popescu[]

The Gabriel–Popescu theorem states that any Grothendieck category ${\mathcal {A}}$ is equivalent to a quotient category $\operatorname {Mod} (R)/{\cal {B}}$ , where $\operatorname {Mod} (R)$ denotes the abelian category of right modules over some unital ring $R$ , and ${\cal {B}}$ is some localizing subcategory of $\operatorname {Mod} (R)$ .^[2]

References[]

^ Gabriel, Pierre, Des categories abeliennes, Bull. Soc. Math. France 90 (1962), 323-448.
^ N. Popesco, P. Gabriel (1964). "Caractérisation des catégories abéliennes avec générateurs et limites inductives exactes". Comptes Rendus de l'Académie des Sciences. 258: 4188–4190.CS1 maint: uses authors parameter (link)

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[1] Gabriel, Pierre, Des categories abeliennes, Bull. Soc. Math. France 90 (1962), 323-448.

[2] N. Popesco, P. Gabriel (1964). "Caractérisation des catégories abéliennes avec générateurs et limites inductives exactes". Comptes Rendus de l'Académie des Sciences. 258: 4188–4190.CS1 maint: uses authors parameter (link)

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