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Let be a space (an object of a category of spaces), let be the category of sheaves on the frame of opens on , let denote the wide subcategory of with only étale morphisms. Then there is an adjoint equivalence
where
sends an étale morphism to the sheaf of local sections of .
sends a sheaf on to its espace étale.
We wish to clarify in which sense also the - topos can be regarded as an -sheaftopos on . One formulation of this is to show that is a locally representable structured -topos - and that the representation is exhibited by formally étale morphisms.
We assume that is the admissible class defined by an infinitesimal modality on .
(1) A -structure on an -topos is called universal if for every -topos composition with induces an equivalence of -categories if
where denotes the geometric morphisms with inverse image .
(2) In this case we say exhibits as classifying -topos for -structures on .
, , and are -structured -toposes.
The classifying topos for -structures is and the -toposes in question are linked with by geometric morphisms. We obtain the required structures as the image of
respectively for and in place of “H/X”.
Let be an -category. We have . A pro object in in is a formal limit of a cofiltered diagram in . A cofiltered diagram is defined to be a finite diagram having a cone (i.e. a family of natural transformation for all , where denotes the constant functor having value ). So we have
and the hom sets are
We have (more or less) synonyms:
pro object, cofiltered, having a cone
ind object, filtered, having a cocone
(1) A morphisms is called étale if (1a) the underlying geometric morphism of -toposes is étale and (1b) the induced map is an equivalence in
(2) Condition (1b) is equivalent to the requirement that is -cocartesian for the projection.
(3) Being an étale geometric morphism of structured -toposes is a local property:
If there is an effective epimorphism to the terminal object of , and in a morphism such that
is étale, then is étale.
Let be a structured -topos, let be an object.
(1) The restriction of to is defined to be the slice .
(2) The restriction of to is defined to be composite
where is base change along .
Let be a morphism of geometries. Let the restriction functor.
(1) Then there is an adjunction
where the left adjoint is called a relative spectrum functor.
(2) Let now be the discrete geometry underlying . Then
is called absolute spectrum functor; here denotes the inclusion of the ind objects of .
A -structured (∞,1)-topos is called locally representable (aka a -scheme) if
such that
the cover in that the canonical morphism (with the terminal object of ) is an effective epimorphism;
for every there exists an equivalence
of structured -toposes for some (in the (∞,1)-category of pro-objects in ). In other words is assumed to be locally equivalent to an absolute spectrum (aka affine scheme) of a pro object in .
If is a structured topos and is an restriction thereof, then is an étale morphism of structured toposes.
There exists a -structure on such that is a locally representable -structured -topos.
has to satisfy
is left exact
satisfies codescent: For every collection of admissible (i.e. formally étale) morphisms in which generate a covering sieve on , the induced map is an effective epimorphism in .
The terminal object in is the identity on . The collection of all formally étale effective epimorphisms (in ) with codomain covers . By HTT Remark 6.2.3.6. they cover in the slice. This follows from
Now we choose to be the composit of base change (this functor is exact) along (this functor is exact) followed by the coreflector (that we have a coreflector is shown (reference)) (this functor is right adjoint and hence left exact). In total is left exact and since our cover consists only of formally étale morphisms and hence preserve the cover.
Now we describe the restriction of to an element of the cover:
Let be an element of the cover; i.e. a formally étale effective epimorphism .
The restriction of to is given by:
Objects of are cocones where is formally étale. Morphisms are pyramids with four faces and tip .
The restriction of the -structure is given as follows:
where is base change along .
Now we show that is locally equivalent to an absolute spectrum:
Let denote the discrete geometry (admissible morphisms are precisely all equivalences) with underlying category . Let be a morphism of geometries (i.e. preserves finite limits, maps admissible morphism to such, the image of an admissible cover is an admissible cover). Then there is an adjunction preserves finite limits, maps admissible morphism to such, the image of an admissible cover is an admissible cover). Then there is an adjunction
and the absolute spectrum is defined to be the composit
Ind(H^{op})\simeq Pro(H)^{op}\simeq Lex(H, \infty Grpd)\hookrightarrow LTop(H_0)\stackrel{Spec_{H_0,H}{\to}LTop(H)
(Pro objects in are cofiltered diagrams in or -equivalently - filtered diagrams in)