Presheaf with transfers

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In algebraic geometry, a presheaf with transfers is, roughly, a presheaf that, like cohomology theory, comes with pushforwards, “transfer” maps. Precisely, it is, by definition, a contravariant additive functor from the category of finite correspondences (defined below) to the category of abelian groups (in category theory, “presheaf” is another term for a contravariant functor).

When a presheaf F with transfers is restricted to the subcategory of smooth separated schemes, it can be viewed as a presheaf on the category with extra maps , not coming from morphisms of schemes but also from finite correspondences from X to Y

A presheaf F with transfers is said to be -homotopy invariant if for every X.

For example, Chow groups as well as motivic cohomology groups form presheaves with transfers.

Finite correspondence

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Let   be algebraic schemes (i.e., separated and of finite type over a field) and suppose   is smooth. Then an elementary correspondence is an irreducible closed subscheme  ,   some connected component of X, such that the projection   is finite and surjective.[1] Let   be the free abelian group generated by elementary correspondences from X to Y; elements of   are then called finite correspondences.

The category of finite correspondences, denoted by  , is the category where the objects are smooth algebraic schemes over a field; where a Hom set is given as:   and where the composition is defined as in intersection theory: given elementary correspondences   from   to   and   from   to  , their composition is:

 

where   denotes the intersection product and  , etc. Note that the category   is an additive category since each Hom set   is an abelian group.

This category contains the category   of smooth algebraic schemes as a subcategory in the following sense: there is a faithful functor   that sends an object to itself and a morphism   to the graph of  .

With the product of schemes taken as the monoid operation, the category   is a symmetric monoidal category.

Sheaves with transfers

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The basic notion underlying all of the different theories are presheaves with transfers. These are contravariant additive functors

 

and their associated category is typically denoted  , or just   if the underlying field is understood. Each of the categories in this section are abelian categories, hence they are suitable for doing homological algebra.

Etale sheaves with transfers

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These are defined as presheaves with transfers such that the restriction to any scheme   is an etale sheaf. That is, if   is an etale cover, and   is a presheaf with transfers, it is an Etale sheaf with transfers if the sequence

 

is exact and there is an isomorphism

 

for any fixed smooth schemes  .

Nisnevich sheaves with transfers

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There is a similar definition for Nisnevich sheaf with transfers, where the Etale topology is switched with the Nisnevich topology.

Examples

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Units

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The sheaf of units   is a presheaf with transfers. Any correspondence   induces a finite map of degree   over  , hence there is the induced morphism

 [2]

showing it is a presheaf with transfers.

Representable functors

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One of the basic examples of presheaves with transfers are given by representable functors. Given a smooth scheme   there is a presheaf with transfers   sending  .[2]

Representable functor associated to a point

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The associated presheaf with transfers of   is denoted  .

Pointed schemes

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Another class of elementary examples comes from pointed schemes   with  . This morphism induces a morphism   whose cokernel is denoted  . There is a splitting coming from the structure morphism  , so there is an induced map  , hence  .

Representable functor associated to A1-0

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There is a representable functor associated to the pointed scheme   denoted  .

Smash product of pointed schemes

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Given a finite family of pointed schemes   there is an associated presheaf with transfers  , also denoted  [2] from their Smash product. This is defined as the cokernel of

 

For example, given two pointed schemes  , there is the associated presheaf with transfers   equal to the cokernel of

 [3]

This is analogous to the smash product in topology since   where the equivalence relation mods out  .

Wedge of single space

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A finite wedge of a pointed space   is denoted  . One example of this construction is  , which is used in the definition of the motivic complexes   used in Motivic cohomology.

Homotopy invariant sheaves

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A presheaf with transfers   is homotopy invariant if the projection morphism   induces an isomorphism   for every smooth scheme  . There is a construction associating a homotopy invariant sheaf[2] for every presheaf with transfers   using an analogue of simplicial homology.

Simplicial homology

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There is a scheme

 

giving a cosimplicial scheme  , where the morphisms   are given by  . That is,

 

gives the induced morphism  . Then, to a presheaf with transfers  , there is an associated complex of presheaves with transfers   sending

 

and has the induced chain morphisms

 

giving a complex of presheaves with transfers. The homology invariant presheaves with transfers   are homotopy invariant. In particular,   is the universal homotopy invariant presheaf with transfers associated to  .

Relation with Chow group of zero cycles

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Denote  . There is an induced surjection   which is an isomorphism for   projective.

Zeroth homology of Ztr(X)

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The zeroth homology of   is   where homotopy equivalence is given as follows. Two finite correspondences   are  -homotopy equivalent if there is a morphism   such that   and  .

Motivic complexes

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For Voevodsky's category of mixed motives, the motive   associated to  , is the class of   in  . One of the elementary motivic complexes are   for  , defined by the class of

 [2]

For an abelian group  , such as  , there is a motivic complex  . These give the motivic cohomology groups defined by

 

since the motivic complexes   restrict to a complex of Zariksi sheaves of  .[2] These are called the  -th motivic cohomology groups of weight  . They can also be extended to any abelian group  ,

 

giving motivic cohomology with coefficients in   of weight  .

Special cases

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There are a few special cases which can be analyzed explicitly. Namely, when  . These results can be found in the fourth lecture of the Clay Math book.

Z(0)

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In this case,   which is quasi-isomorphic to   (top of page 17),[2] hence the weight   cohomology groups are isomorphic to

 

where  . Since an open cover

Z(1)

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This case requires more work, but the end result is a quasi-isomorphism between   and  . This gives the two motivic cohomology groups

 

where the middle cohomology groups are Zariski cohomology.

General case: Z(n)

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In general, over a perfect field  , there is a nice description of   in terms of presheaves with transfer  . There is a quasi-ismorphism

 

hence

 

which is found using splitting techniques along with a series of quasi-isomorphisms. The details are in lecture 15 of the Clay Math book.

See also

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References

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  1. ^ Mazza, Voevodsky & Weibel 2006, Definition 1.1.
  2. ^ a b c d e f g Lecture Notes on Motivic Cohomology (PDF). Clay Math. pp. 13, 15–16, 17, 21, 22.
  3. ^ Note   giving  
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