Exactness, Cohomology, and Uniqueness in First-Order Differential Equations

Abstract

This paper investigates the relationship between the solvability of first-order differential equations and the topology of the underlying domain through the lens of de\,Rham cohomology. We analyze the conditions under which a closed 1-form associated with a first-order ODE admits a global potential, thereby reducing the problem to the exactness of differential forms. While it is well known that exactness is guaranteed on simply connected domains, we show that triviality of the first de\,Rham cohomology group is the more fundamental requirement for global integrability and uniqueness of solutions. In particular, we demonstrate that certain non-simply connected manifolds, such as the real projective plane RP2, still support global solutions due to the vanishing of H1dR. By explicitly constructing examples on RP2 and comparing them with domains like R2 \0\, we illustrate how topological obstructions manifest analytically as non-uniqueness or multi-valued behavior. We further discuss the correspondence between integrating factors and the trivialization of cohomology classes, drawing connections to classical symmetry methods and potential theory. This synthesis of geometric, topological, and analytic perspectives provides a unifying framework for understanding the global behavior of first-order ODEs beyond local existence theorems.