Grothendieck topology: Difference between revisions

The notion of a Grothendieck topology or site captures the essential properties necessary for constructing a robust theory of cohomology of sheaves. The theory of Grothendieck topologies was developed by Alexander Grothendieck and Michael Artin.

Definition

A Grothendieck topology ${\displaystyle T}$ consists of

1. A category, denoted ${\displaystyle cat(T)}$
2. A set of coverings ${\displaystyle \{U_{i}\to U\}}$, denoted ${\displaystyle cov(T)}$, such that
   1. ${\displaystyle \{id:U\mapsto U\}\in cov(T)}$ for each object ${\displaystyle U}$ of ${\displaystyle cat(T)}$
   2. If ${\displaystyle \{U_{i}\to U\}\in cov(T)}$, and ${\displaystyle V\to U}$ is any morphism in ${\displaystyle cat(T)}$, then the canonical morphisms of the fiber products determine a covering ${\displaystyle \{U_{i}\times _{U}V\to V\}\in cov(T)}$
   3. If ${\displaystyle \{U_{i}\to U\}\in cov(T)}$ and ${\displaystyle \{V_{i,j}\to U_{i}\}\in cov(T)}$, then ${\displaystyle \{V_{i,j}\to U_{i}\to U\}\in cov(T)}$

Examples

1. A standard topological space ${\displaystyle X}$ becomes a category ${\displaystyle op(X)}$ when you regard the open subsets of ${\displaystyle X}$ as objects, and morphisms are inclusions. An open covering of open subsets ${\displaystyle U}$ clearly verify the axioms above for coverings in a site. Notice that a presheaf of rings is just a contravariant functor from the category ${\displaystyle op(X)}$ into the category of rings.
2. The Small Étale Site Let ${\displaystyle S}$ be a scheme. Then the category of étale schemes over ${\displaystyle S}$ (i.e., ${\displaystyle S}$-schemes ${\displaystyle X}$ over ${\displaystyle S}$ whose structural morphisms are étale)

Sheaves on Sites

In analogy with the situation for topological spaces, a presheaf may be defined as a contravariant functor such that for all coverings ${\displaystyle \{U_{i}\to U\}\in cov(T)}$, the diagram Failed to parse (unknown function "\Prod"): {\displaystyle 0\to F(U)\to \Prod F(U_i)\to \Prod F(U_i\times_U U_j)} is exact.