If $F\colon\mathcal{A}\to\mathcal{B}$ is left adjoint to $U\colon\mathcal{B}\to\mathcal{A}$, then $U$ preserves limits and $F$ preserves colimits.
Can we say something more if $F$ is left adjoint to $U$ and they form an adjoint equivalence between $\mathcal{A}$ and $\mathcal{B}$?
My question arises from the following statement on Wikipedia:
The functor $H\colon\mathcal{I}\to\mathcal{C}$ has limit (or colimit) $\mathcal{I}$ if and only if the functor $FH\colon\mathcal{I}\to\mathcal{D}$ has limit (or colimit) $F\mathcal{I}$.
where $F\colon\mathcal{C}\to\mathcal{D}$ is an equivalence. Is $F$ preserving both limits and colimits? (in the Wikipedia case, $F$ is not part of an adjoint equivalence, but, according to this question, every equivalence can be upgraded to an adjoint equivalence).
When $F$ and $U$ form an adjoint equivalence, the unit $\eta:I_{\mathcal{A}}\to UF$ and counit $\epsilon : FU\to I_{\mathcal{B}}$ are isomorphisms; then their inverses $\epsilon^{-1}:I_{\mathcal{B}}\to FU$ and $\eta^{-1}:UF\to I_{\mathcal{A}}$ are natural transformation, and they satisfy the identities $$F(\eta^{-1})\circ\epsilon^{-1}_F=(\epsilon_F\circ F(\eta))^{-1}=1_F$$ and $$\eta^{-1}_U\circ U(\epsilon^{-1})=(U(\epsilon)\circ \eta_U)^{-1}=1_U.$$ Thus $U$ is also left adjoint to $F$, so that $U$ preserve colimits and $F$ preserve limits.