A complex-linear reformulation of Hamilton-Jacobi theory and emergent quantum structure

Abstract

Classical mechanics admits multiple equivalent formulations, from Newton's equations to the variational Lagrange-Hamilton framework and the scalar Hamilton-Jacobi (HJ) theory. In the HJ formulation, classical ensembles evolve through the continuity equation for a real density = R2 coupled to Hamilton's principal function S. Here we develop a complementary formulation, the Hamilton-Jacobi-Schr\"odinger (HJS) theory, by embedding the pair (R,S) into a single complex field. Starting from a completely general complex ansatz = f(R,S)\, ei g(R,S), and imposing two minimal structural requirements, we obtain a unique map = R\, eiS/\, together with a linear HJS equation whose || 0 limit reproduces the HJ formulation exactly. Remarkably, when Re()≠ 0, essential features of quantum mechanics, superposition, operator algebra, commutators, the Heisenberg uncertainty principle, Born's rule and unitary evolution, follow naturally as structural consistency conditions. HJS thus provides a unified mathematical viewpoint in which classical and quantum dynamics appear as different limits of a single underlying structure.