Proof

This follows by general properties discussed at reflective subcategory. We spell out the argument using the theory of localization at a set of morphisms satisfying a calculus of fractions.

Recall from the discussion at sheaf that $Sh_J(C)$ is by definition the full subcategory of $PSh(C)$ on the local objects with respect to the morphisms

of sieve inclusions for all covering families of the coverage $J$. (Here the colimit $\lim_\to$ is the coequalizer of the two injection maps, as indicated. This is spelled out in more detail at sheaf and at sieve.)

Now we invoke the following results:

1. The localization proposition says that every full subcategory of a locally presentable category on the $W$-local objects for a small set $W$ of morphisms is a reflective subcategory, given by the localization at these morphisms;

2. By Gabriel-Zisman's theorem every reflective subcategory is the localization at the collection of morphisms inverted by the left adjoint (which by the localization proposition is the saturation of the original set of morphisms).

3. If $W$ satisfies the axioms of a calculus of fractions then, by the discussion there, this localization is equivalently given by the category $PSh(C)[W^{-1}]$ whose objects are those of $PSh(C)$ and whose morphisms are given by $PSh(C)[W^{-1}](X,A) \simeq {\lim_{\to}}_{\hat X \stackrel{w \in W}{\to} X} PSh_C(\hat X,A)$.

Notice that an object is a local object with respect to the above set of morphisms $W$ precisely if it is local with respect to the set of all small colimits (in the arrow category $Arr(PSh(C))$ ) of such morphims (since the hom-functor $PSh_C(-,A)$ sends colimits in the first argument to limits, and a limit of isomorphisms is an isomorphism).

Let hence $\bar W$ be the completion of $A$ under forming small colimits in $Arr(PSh(C))$.

We claim that the morphisms in $\bar W$ form a calculus of fractions. The first condition to check is that for all morphisms of presheaves $X \to j(U)$ and every covering family $\{U_i \to U\}$ there is a morphism $Y \to X$ in $\bar W$ and a commuting diagram

in $PSh(C)$. (It is sufficient to demand this for $s \in W \subset \bar W$ to deduce the stability conditions for all morphisms in $\bar W$, since by universal colimits in the presheaf topos $PSh(C)$ the pullback of a colimit is a colimit of pullbacks.)

Similarly, to see that we can find $Y \to X$ we use the co-Yoneda lemma to decompose $X$ as a colimit of representables $X \simeq {\lim_{\to}_j} K_j$ and then use universal colimits to deduce that we are looking at a diagram of the form

Since $\bar W$ is closed under colimits, it is hence sufficient that we show the stability condition for $X$ any representable. So we need to fill diagrams of the form

For this now use the single condition on a coverage: that for $\{U_i \to U\}$ a covering family in the site $(C,J)$ we can find a covering family $\{K_j \to K\}$ such that every $K_j \to K$ factors through one of the $U_i \to U$. But this means that also the sieves factor, and we have a commuting diagram

This shows that $\bar W$ satisfies the first condition at factorization system.

The second condition at calculus of fractions demands that if two composites of the form

are equal in $PSh(C)$, then there is a morphism $Y \to X$ in $PSh(C)$ such that the two composites

are equal. But the sieve inclusions are monomorphisms, hence this condition is trivially satisfied (choose $Y \to X$ to be the identity on $X$). Again by decomposing into colimits by the co-Yoneda lemma and using universal colimits and the pasting law for pullbacks, the same follows for general morphisms in $\bar W$

by applying the above on each component $k$ of the colimit.

This gives us the localization $L : PSh(C) \to Sh_J(C)$ as described at calculus of fractions. By the discussion there we have that $Sh_J(C)$ is equivalently given by the category $PSh(C)[W^{-1}]$ with the same objects as $PSh(C)$ and hom-sets given by

So we have that for $X \in PSh(C)$ a presheaf and $A \in Sh_J(C)$ the hom-set $Sh_C(L(X),A)$ is given by

But if $A$ is a sheaf, it is a $\bar W$-local object and hence $PSh_C(\hat X \stackrel{w}{\to} X, A)$ is an isomorphism for all $w \in \bar W$. Hence the above colimit is over a diagram constant on its value at $w = Id : X \to X$ therefore we have a natural isomorphism

This demonstrates the adjunction $(L \dashv i)$.

Proof

By the Yoneda lemma we have

By the above proposition this is

By the proof of the above proposition, using the formulas discussed at calculus of fractions, this hom-set is given by

Proof

Use that the sieve is the coequalizer

and that the hom-functor $PSh_C(-,X)$ sends colimits to limits. More details on this computation are at sheaf.