Recall that a preadditive category is just a category $\mathcal{C}$ enriched in the category of abelian groups such that composition is linear with respect to the various group operations, so $$f\circ(g+h)=f\circ g+f\circ h,$$ $$(g+h)\circ f=g\circ f+h\circ f,$$ and a preadditive category with one object is a categorification of the notion of a noncommutative ring where we interpret the ring addition as the addition inherited from enrichment and multiplication as composition of morphisms.
Is a preadditive groupoid with one object a categorification of the notion of a skew field, and if so where can I read more about it?
Naively it seems like we now have additive inverses and multiplicative inverses for each object; we only seem to be missing multiplicative commutativity to categorify fields. This leads to a followup question,
Is there a notion of a category where composition of endoarrows is always commutative? That is, a category $\mathcal{C}$ such that for all endoarrows $f,g:X\rightrightarrows X$ we have $f\circ g=g\circ f$?
This seems like a bad definition since it involves equality, so perhaps a better request is a category $\mathcal{C}$ such that composition of endoarrows is commutative up to isomorphism in a (co?)slice category, with the above notion recovered as the 'strict' version.
