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For any category C and topological space X we have the notion of a C-valued presheaf on X.

What assumptions must be made about C in order that we have the notion of such a presheaf being a 'sheaf'? I understand the definition of the sheaf properties using an equalizer diagram which assumes C has products and a final object. Is this definition 'standard'?

Secondly, the definition of a sheafification of a presheaf in terms of the obvious universal property makes sense for any category C (for which the notion of sheaf makes sense). But what assumptions must be placed on C in order for such a sheafification to exist? For presheafs of sets I know the construction via the étale space of the presheaf (namely, the sheafification can be constructed as the sheaf of sections of the projection E->X of the etale space E onto X). This construction works in general right?

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6 Answers 6

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A presheaf $F$ with values in $C$ is a called a sheaf if, for every object $X$ and every covering sieve $R$ of $X$, the natural maps

$F(X) \rightarrow F(Y)$

for each Y in R induce an isomorphism

$F(X) \xrightarrow{\sim} \varprojlim_{Y \in R} F(Y)$

This definition makes sense without any assumptions on $C$.

The sheafification construction makes use of filtered colimits and essentially arbitrary limits (if you are interested in sheaves on a particular topology then you might be able to restrict the class of limits that need to be considered). It is defined by iterating the construction

$F^+(X) = \varinjlim_{R} \varprojlim_{Y \in R} F(Y)$

where the $\varinjlim$ is taken over covering sieves of $X$. If $F$ is set-valued, the associated sheaf of $F$ is $F^{++}$.

I don't know what conditions on $C$ are necessary to make the sheafification of a presheaf in $C$ a sheaf, but I wouldn't expect the construction to behave very well unless $C$ is a fairly special category.

(Categories of algebraic structures on sets defined by finite inverse limits would qualify as "special", essentially because filtered colimits commute with finite inverse limits.)

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To answer your last question, "This construction works in general right?", the answer is no. The espace etale construction of sheafification heavily relies on the existence of "elements" in the objects of your category C (because its stalks are defined via germs which are defined via equivalence classes of elements), so basically it only works for concrete categories, and only certain concrete categories at that.

For a more general construction of sheafification, see the other answers.

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To answer the first question provided one has, as you say, (small) products and equalizers the notion of sheaf makes sense as one has the right diagram corresponding to any cover. But we can just say that $C$ is complete since a category is complete iff it has all products and equalizers.

For the sheafification to exist it is sufficient that $C$ also be cocomplete so that one can take colimits over suitable categories of covering sieves. This comes up in the construction usually denoted by $(-)^+$ which applied twice to a presheaf results in a sheaf.

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Let PS(X,B) denote the category of presheaves on the category with values in category B. We denote by Sh((X,SX),B) the category of sheaves on the topos (CX,SX)(CX is category representing X and SX is pretopology). The assumption for category B is that

B has filtered colimits which commutes with kernels of pairs of arrows. Let HX denote the endofunctor of PS(X,B) which assigns to every presheaf F: CX^op--->B of the presheaf HX(F) defined by HX(F)(N)=colim(Ker(F(M)-->-->F(M product M over N))),where N and M are objects of CX where colimit is taken over Cov(N,t):(Cover of M, t is determined by SX mentioned above). We can easily check that Cov(N,t) is a filtered category. So the colimits we need is filtered colimits.

We can also easily check that F(N)--->HX(F)(N) is a functor for each N belongs to ObCX

i.e. it defines a functor morphism F|--->HX(F)

This functor HX is called Heller functor. It is routine to check HX is left exact. with following property 1 Functor HX maps any presheaf to monopresheaf and maps any monopresheaf to sheaf. So sheafification functor is just HX compose HX.

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There is also this paper by Gray: Category-valued sheaves, BAMS 68, (1962),

Link

who addresses the question.

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My position is that the definition of $\mathcal{C}$-valued sheaves for completely general categories $\mathcal{C}$ is not yet a settled matter. For locally finitely presentable categories $\mathcal{C}$, the usual definition (by products and equalisers, by limits, or by representability) works well, in the following sense:

  1. The category of $\mathcal{C}$-valued sheaves is a full reflective subcategory of the category of $\mathcal{C}$-valued presheaves. Furthermore, the reflector (i.e. sheafification) preserves finite limits.

  2. The category of $\mathcal{C}$-valued sheaves is locally presentable (but not necessarily locally finitely presentable). Furthermore, finite limits commute with filtered colimits.

  3. Continuous maps contravariantly induce functors between the categories of $\mathcal{C}$-valued sheaves – the so-called inverse image functors – and these functors preserve finite limits and arbitrary colimits. Furthermore, the mapping from continuous maps to inverse image functors is a contravariant pseudofunctor.

Categories of algebras for algebraic theories – this is a term of art! – are locally finitely presentable: for example, the category of sets, or abelian groups, or commutative rings, or Lie algebras; but not the category of topological spaces, or Kan complexes, or fields. More generally, categories of algebras for essentially algebraic theories are locally finitely presentable: for example, the category of partially ordered sets, or preordered sets, or groupoids (with a discrete set of objects). So the above should suffice for most purposes.

Now, suppose $\mathcal{C}$ is locally presentable (but not necessarily locally finitely presentable). For the same definition of "$\mathcal{C}$-valued sheaf", it remains true that:

  1. The category of $\mathcal{C}$-valued sheaves is a full reflective subcategory of the category of $\mathcal{C}$-valued presheaves.

  2. The category of $\mathcal{C}$-valued sheaves is locally presentable.

But I do not know whether sheafification preserves finite limits, and it is not true in this generality that finite limits commute with filtered colimits. I also do not know how to construct inverse image functors in this generality, though (as a special case) the usual construction of stalks yields a functor that preserves colimits. As with sheafification, I do not know whether it preserves finite limits. So we lose the basic properties we often take for granted when working with sheaves – which suggests, to me at least, that this definition is being stretched too far.

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