The small affine Zariski site #
X.AffineZariskiSite is the small affine Zariski site of X, whose elements are affine open
sets of X, and whose arrows are basic open sets D(f) ⟶ U for any f : Γ(X, U).
Every presieve on U is then given by a Set Γ(X, U) (presieveOfSections_surjective), and
we endow X.AffineZariskiSite with grothendieckTopology X, such that s : Set Γ(X, U) is
a cover if and only if Ideal.span s = ⊤ (generate_presieveOfSections_mem_grothendieckTopology).
This is a dense subsite of X.Opens (with respect to Opens.grothendieckTopology X) via the
inclusion functor toOpensFunctor X,
which gives an equivalence of categories of sheaves (sheafEquiv).
Note that this differs from the definition on stacks project where the arrows in the small affine Zariski site are arbitrary inclusions.
X.AffineZariskiSite is the small affine Zariski site of X, whose elements are affine open
sets of X, and whose arrows are basic open sets D(f) ⟶ U for any f : Γ(X, U).
Note that this differs from the definition on stacks project where the arrows in the small affine Zariski site are arbitrary inclusions.
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- X.AffineZariskiSite = { U : X.Opens // AlgebraicGeometry.IsAffineOpen U }
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The inclusion from X.AffineZariskiSite to X.Opens.
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- One or more equations did not get rendered due to their size.
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- AlgebraicGeometry.Scheme.AffineZariskiSite.instPartialOrder = { toPreorder := AlgebraicGeometry.Scheme.AffineZariskiSite.instPreorder, le_antisymm := ⋯ }
The basic open set of a section, as an element of AffineZariskiSite.
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The inclusion functor from X.AffineZariskiSite to X.Opens.
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The forgetful functor from X.AffineZariskiSite to Scheme is isomorphic to Spec Γ(X, -).
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The Grothendieck topology on X.AffineZariskiSite induced from the topology on X.Opens.
Also see mem_grothendieckTopology_iff_sectionsOfPresieve.
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The presieve associated to a set of sections.
This is a surjection, see presieveOfSections_surjective.
Equations
- U.presieveOfSections s x✝ = ∃ f ∈ s, X.basicOpen f = V.toOpens
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The set of sections associated to a presieve.
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The category of sheaves on X.AffineZariskiSite is equivalent to the categories of sheaves
over X.
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The directed cover of a scheme indexed by X.AffineZariskiSite.
Note the related Scheme.directedAffineCover, which has the same (defeq) cover but a different
category instance on the indices.
Equations
- AlgebraicGeometry.Scheme.AffineZariskiSite.directedCover X = { I₀ := X.AffineZariskiSite, X := fun (U : X.AffineZariskiSite) => ↑↑U, f := fun (U : X.AffineZariskiSite) => (↑U).ι, mem₀ := ⋯ }
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- One or more equations did not get rendered due to their size.
"Quasi-coherent 𝒪ₓ-algebras" #
A presheaf F of rings on X.AffineZariskiSite with a structural morphism α : 𝒪ₓ ⟶ F
is said to be Coequifibered if F(D(f)) = F(U)[1/f]
for every open U and any section f : Γ(X, U).
(See coequifibered_iff_forall_isLocalizationAway)
Under this condition we can construct a family of gluing data (See relativeGluingData) and glue
F into a scheme over X via (relativeGluingData _).glued,
Also see the relative gluing API in Mathlib/AlgebraicGeometry/RelativeGluing.lean.
This is closely related to the notion of quasi-coherent 𝒪ₓ-algebras, and we shall link them
together once the theory of quasi-coherent 𝒪ₓ-algebras are developed.
X is the colimit of its affine opens. See isColimit_cocone below.
Equations
- AlgebraicGeometry.Scheme.AffineZariskiSite.cocone X = { pt := X, ι := { app := fun (U : X.AffineZariskiSite) => ⋯.fromSpec, naturality := ⋯ } }
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Alias of CategoryTheory.NatTrans.Coequifibered.
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The relative gluing data associated to a quasi-coherent 𝒪ₓ algebra.
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- One or more equations did not get rendered due to their size.
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Alias of AlgebraicGeometry.Scheme.AffineZariskiSite.opensRange_relativeGluingData_map.
X is the colimit of its affine opens.