More generally, pairs of adjoint functors between the categories of sheaves appear in various other setups apart from geometric morphisms of topoi, for instance on abelian categories of quasicoherent sheaves, bounded derived categories of coherent sheaves and the term direct image is used for the right adjoint part of these, too.

Specifically for Grothendieck toposes: a morphism of sites f:X→Yf : X \to Y induces a geometric morphism of Grothendieck toposes

(p *⊣p *):Sh(X)←p *→p *Sh(Y) (p^* \dashv p_*) \;\;\; : \;\;\; Sh(X) \stackrel{}{\stackrel{\overset{p_*}{\to}}{\overset{p^*}{\leftarrow}}} Sh(Y)

between the categories of sheaves on the sites, with

p *p_* the direct image
and p *p^* its left adjoint: the inverse image.

Definition

Given a morphism of sites f:X→Yf : X \to Y coming from a functor f t:S Y→S Xf^t : S_Y \to S_X, the direct image operation on presheaves is the functor

f *:PSh(X)→PSh(Y) f_* : PSh(X) \to PSh(Y)

f *F:S Y op→f tS X op→FSet. f_* F : S_Y^{op} \stackrel{f^t}{\to} S_X^{op} \stackrel{F}{\to} Set \,.

The restriction of this operation to sheaves, which respects sheaves, is the direct image of sheaves

f *:Sh(X)→Sh(Y). f_* : Sh(X) \to Sh(Y) \,.

Examples

Global sections

For XX a site with a terminal object, let the morphism of sites be the canonical morphism p:X→*p : X \to {*}.

The direct image p *p_* is the global sections functor;
the inverse image p *p^* is the constant sheaf functor;
the left adjoint to p *p^* is Π 0\Pi_0, the functor of geometric connected components (see homotopy group of an ∞-stack).

Restriction and extension of sheaves

See

restriction and extension of sheaves

for the moment.

Direct image with compact supports

Let f:X→Yf:X\to Y be a morphism of locally compact topological spaces. Then there exist a unique subfunctor f !:Sh(X)→Sh(Y)f_!: Sh(X)\to Sh(Y) of the direct image functor f *f_* such that for any abelian sheaf FF over XX the sections of f !(F)f_!(F) over U open⊂XU^{open}\subset X are those sections s∈f *(U)=Γ(f −1(U),F)s\in f_*(U)= \Gamma(f^{-1}(U),F) for which the restriction supp(s)|f:supp(s)↪Usupp(s)|f : supp(s)\hookrightarrow U is a proper map.

This is called the direct image with compact support.

It follows that f !f_! is left exact.

Let p:X→*p:X\to {*} be the map into the one point space. Then for any F∈Sh(X)F\in Sh(X) the abelian sheaf p !Fp_!F is the abelian group consisting of sections s∈Γ(X,F)s\in \Gamma(X,F) such that supp(s)supp(s) is compact. One writes Γ c(X,F)≔p !F\Gamma_c(X,F) \coloneqq p_! F and calls this group a group of sections of FF with compact support. If y∈Yy\in Y, then the fiber (f !F) y(f_! F)_y is isomorphic to Γ c(f −1y,F| f −1(y))\Gamma_c(f^{-1}y,F|_{f^{-1}(y)}).

Derived direct image

(e.g. Tamme, I (3.7.1), II (1.3.4), Milne, 12.1).

Proof

We have a commuting diagram

Ab(PSh(X)) ⟶(−)∘f −1 Ab(PSh(Y)) ↑ inc ↓ L Ab(Sh(X)) ⟶f * Ab(Sh(Y)), \array{ Ab(PSh(X)) &\stackrel{(-)\circ f^{-1}}{\longrightarrow}& Ab(PSh(Y)) \\ \uparrow^{\mathrlap{inc}} && \downarrow^{L} \\ Ab(Sh(X)) &\stackrel{f_\ast}{\longrightarrow}& Ab(Sh(Y)) } \,,

where the right vertical morphism is sheafification. Because (−)∘f −1(-) \circ f^{-1} and LL are both exact functors it follows that for I •→ℱI^\bullet \to \mathcal{F} an injective resolution that

R pf *(ℱ) :≃H p(f *I) =H p(LI •(f −1(−))) =L(H p(I •)(f −1(−))) \begin{aligned} R^p f_\ast(\mathcal{F}) & :\simeq H^p( f_\ast I) \\ & = H^p(L I^\bullet(f^{-1}(-))) \\ & = L (H^p(I^\bullet)(f^{-1}(-))) \end{aligned}

derived direct image

References

e.g.

Günter Tamme, section II 1 of Introduction to Étale Cohomology

James Milne, section 7 of Lectures on Étale Cohomology

Last revised on December 24, 2020 at 02:24:35. See the history of this page for a list of all contributions to it.