Canonical differential calculi via functorial geometrization

Abstract

Given a category E, we establish sufficient conditions on a faithful isofibration E→Mon(V) valued in the category of monoids internal to a monoidal additive category V such that E admits a canonical functor to the category of first order differential calculi in V. Generalizing the procedure of extending a first order differential calculus to its maximal prolongation to this setting, we obtain a canonical functor from E to the category of differential calculi in V. This yields a simultaneous generalization of the de Rham complex on C∞-rings, the K\"ahler differentials on commutative algebras, and the universal differential calculus on associative algebras. As a consequence, such categories E admit natural analogues of the notions of smooth map and diffeomorphism, as well as a functorial de Rham theory. Moreover, whenever two such faithful isofibrations to Mon(V) factor suitably, their corresponding de Rham functors are related via a comparison map. Developing this theory requires first extending the noncommutative geometry formalism of differential calculi from associative algebras to the setting of monoids internal to monoidal additive categories.

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