Proof

The functor $(-)^E$ is the composite $\Pi_E \circ E^*$, and pullback $E^*\colon \mathcal{T} \to \mathcal{T}/E$ preserves epis, so if $\Pi_E$ preserves epis then so does $(-)^E$.

Conversely, for any $f:A\to B$ in $\mathcal{T}/E$, we have a pair of pullback squares:

The lower square and outer rectangle are easily seen to be pullbacks, hence so is the upper square. Since epimorphisms are closed under pullback, the other implication follows.

Proof

This proof was given by Alex Simpson here. Let $q:B\to A$ be an epimorphism from $v:B\to I$ to $u:A\to I$. Then the exponential $u^{I^*E}$ in $\mathcal{T}/I$ is the equalizer of

and

equipped with the obvious projection to $I$. Now we have a pullback square

in which the right-hand map is epi since $E$ is internally projective; hence so is the left-hand map.

Proof

By definition, truth of “$E$ is projective” in the stack semantics means that for any $I$ and any epimorphism $A\to I\times E$, there exists an epimorphism $p:J\to I$ and a section of $(p\times id)^*A \to J\times E$. (We have used the characterization that an object $X$ is projective just when every epimorphism with codomain $X$ is split.)

If $E$ is internally projective, then given an epimorphism $A\to I\times E$ as above, let $J = \Pi_{pr_1}(A)$, where $pr_1:I\times E \to I$ is the projection. Since $I\times E$ is internally projective in $\mathcal{T}/I$ by Lemma , $p:J\to I$ is an epimorphism. And $(p\times id)^*A \to J\times E$ is split by the counit of the adjunction $(pr_1)^* \dashv \Pi_{pr_1}$.

Conversely, suppose the above condition holds, and let $e:B\to A$ be an epimorphism in $\mathcal{T}/E$. Let $I = \Pi_E(A)$, and let $C$ be the pullback of $e$ along the counit $\Pi_E(A) \times E\to A$. Then $\Pi_E(B)$ is equivalently $\Pi_{pr_1}(C)$, where $pr_1:I \times E \to I$ is the projection.

Moreover, $C \to I\times E$ is epi, so by assumption there is an epi $p:J\to I$ such that $(p\times id)^*C \to J\times E$ is split. Since pullback along epis reflects epis, it suffices to show that $p^* \Pi_{pr_1}(C)$ is split. However, we have a pullback square

so by the Beck-Chevalley condition, $p^* \Pi_{pr_1}(C)$ is equivalently $\Pi_{pr_1}(p\times id)^* C$. But $(p\times id)^*C$ is split, and all functors preserve split epis.

Proof

Let $P$ be a projective object. To show that $e^P \colon E^P \to B^P$ is epic whenever $e \colon E \to B$ is epic, choose an epi $\phi \colon P' \to B^P$ where $P'$ is projective (using the assumption of enough projectives). Since $P \times P'$ is projective, there exists a lift through $e$ of the horizontal composite as shown:

this, by currying, provides a lift of $\phi \colon P' \to B^P$ through $e^P$. Since $\phi$ is epic, this immediately implies $e^P$ is epic, as desired.

Proof

Representables, and arbitrary coproducts of representables, are projective, and every presheaf is covered by some coproduct of representables. This implies that projective presheaves are precisely retracts of coproducts of representables. Under the assumption that $C$ has binary products, coproducts of representables, and also their retracts, are also closed under binary products. Thus projective presheaves are closed under binary products. Now apply Proposition .