Parametrized higher semiadditivity and the universality of spans

Using the framework of ambidexterity developed by Hopkins and Lurie, we introduce a parametrized analogue of higher semiadditivity called $\mathcal Q$-semiadditivity, depending on a chosen class of morphisms $\mathcal Q$. Our first main result identifies the free $\mathcal Q$-semiadditive parametrized category on a single generator with a certain parametrized span category $\underline{\mathrm{Span}}(\mathcal Q)$, simultaneously generalizing a result of Harpaz in the non-parametrized setting and a result of Nardin in the equivariant setting. As a consequence, we deduce that the $\mathcal Q$-semiadditive completion of a parametrized category $\mathcal C$ consists of the $\mathcal Q$-commutative monoids in $\mathcal C$, defined as $\mathcal Q$-limit preserving parametrized functors from $\underline{\mathrm{Span}}(\mathcal Q)$ to $\mathcal C$. As our second main result, we provide an explicit `Mackey sheaf' description of the free presentable $\mathcal Q$-semiadditive category. Using this, we reprove the Mackey functor description of global spectra first obtained by the second-named author and generalize it to $G$-global spectra. Moreover, we obtain universal characterizations of the categories of $\mathbb Z$-valued $G$-Mackey profunctors and of quasi-finitely genuine $G$-spectra as studied by Kaledin and Krause-McCandless-Nikolaus, respectively.