First-Order Logical Duality

TL;DR

This paper extends Stone duality from propositional to first-order logic, establishing a categorical duality between theories and model groupoids using topos theory, enriching the algebra-geometry correspondence.

Contribution

It generalizes the classical duality to first-order logic by replacing Boolean algebras with Boolean categories and model spaces with topological groupoids, using topos-theoretic methods.

Findings

Established a duality between first-order theories and model groupoids.

Constructed the classifying topos of a decidable coherent theory from its models.

Provided direct proofs and topos-theoretic insights into the syntax-semantics relationship.

Abstract

From a logical point of view, Stone duality for Boolean algebras relates theories in classical propositional logic and their collections of models. The theories can be seen as presentations of Boolean algebras, and the collections of models can be topologized in such a way that the theory can be recovered from its space of models. The situation can be cast as a formal duality relating two categories of syntax and semantics, mediated by homming into a common dualizing object, in this case 2. In the present work, we generalize the entire arrangement from propositional to first-order logic. Boolean algebras are replaced by Boolean categories presented by theories in first-order logic, and spaces of models are replaced by topological groupoids of models and their isomorphisms. A duality between the resulting categories of syntax and semantics, expressed first in the form of a contravariant adjunction, is established by homming into a common dualizing object, now $\Sets$, regarded once as a boolean category, and once as a groupoid equipped with an intrinsic topology. The overall framework of our investigation is provided by topos theory. Direct proofs of the main results are given, but the specialist will recognize toposophical ideas in the background. Indeed, the duality between syntax and semantics is really a manifestation of that between algebra and geometry in the two directions of the geometric morphisms that lurk behind our formal theory. Along the way, we construct the classifying topos of a decidable coherent theory out of its groupoid of models via a simplified covering theorem for coherent toposes.