Proof

Details on the first statement are at sheafification. A full proof for the second statement is at (∞,1)-category of (∞,1)-sheaves (there proven in (∞,1)-category theory, but the proof is verbatim the same in category theory).

Proof

If $A \simeq i \hat A$, then by the $(L \dashv i)$-adjunction isomorphism we have

But by assumption $L(f)$ is an isomorphism, so the claim is immediate.

Conversely, if for all $f$ the function $Hom(f,A)$ is a bijection, define $\hat A := L(A)$ and let $\epsilon_A : A \to i L(A)$ be the $(L \dashv i)$-unit.

By the assumption that $i$ is a full and faithful functor and basic properties of adjoint functors we have that the counit

is a natural isomorphism. By the zig-zag law the composite

is the identity and therefore $L \epsilon$ is an isomorphism and so $\epsilon_A$ is in $W$, under our assumption on $A$.

Using this it follows that

is an isomorphism. Write $k_A : i L A \to A$ for the preimage of $id_A$ under this isomorphism, which is therefore a left inverse of $\epsilon_A$. This immediately implies that also $k_A$ is in $W$, and so we can enter the same argument with $k_A$ to find that it has a left inverse itself. But this means that $k_A$ is in fact an isomorphism and hence so is $\epsilon A$, which thus exhibits $A$ as being in the essential image of $i$.

Proof

Assume first that $f$ is in $W$. Since by assumption $L$ preserves finite limits, it follows that

is still a pullback diagram in $\mathcal{E}$ and hence that $L(z^* f)$ is the pullback of the isomorphism $L f$ and thus itself an isomorphism. Therefore $z^* f$ is in $W$.

Conversely, suppose that all these pullbacks are in $W$. Then use the “co-Yoneda lemma” to write the presheaf $Y$ as a colimit over all representables mapping into it

Forming the pullback along $f$, using that in a topos (such as our presheaf topos) colimits are preserved by pullbacks, we get

Since $L$ preserves all colimits and finite limits, we also get

Since by assumption now all $L(z_i^* f )$ are isomorphisms, also ${\lim_\to}_i L(z_i^* f)$ is an isomorphism and hence three sides of the above square are isomorphisms. Therefore also $L(f)$ is and hence $f$ is in $W$.

Proof

We check the list of axioms, given at Grothendieck topology:

1. Pullbacks of covering sieves are covering :

   First of all, the pullback of a sieve along a morphism of representables is still a sieve, because monomorphisms are (as discussed there) stable under pullback.

   Next, since $L$ preserves finite limits, $L$ applied to the pullback sieve is the pullback of an isomorphism, hence is an isomorphism, hence the pullback sieve is in $W$.

2. The maximal sieve is covering. Clear: $L$ applied to an isomorphism is an isomorphism.

3. Two sieves cover precisely if their intersection covers. This is again due to the pullback-stability of elements of $W$, due to the preservation of finite limits by $L$.

4. If all pullbacks of a sieve along morphisms of a covering sieve are covering, then the original sieve was covering .

   This is the same argument as in the second part of the proof of prop. .

Proof

By prop. and prop. we are reduced to showing that an object $A$ is in $\mathcal{E}$ already if for all monomorphisms $f$ in $W$ the function $Hom(f,A)$ is a bijection.

(…)

Proof

Recalling the defining geometric embedding of any Grothendieck topos into the corresponding category of presheaves

both functors preserve the terminal object (this being the limit over the empty diagram): The direct image because it is a right adjoint and right adjoints preserve limits, and the inverse image because sheafification preserves finite limits.

But the terminal presheaf is clearly the functor $\const_\ast \,\in\, PSh(\mathcal{S})$ which is constant on the singleton set. Therefore $L(const_\ast)$ is the terminal sheaf. But then its underlying presheaf $i\big(L(const_\ast)\big)$ must again be the terminal presheaf, hence still the functor constant on the singleton set.