The Field Potential W: A Constructive Foundation for Classical Electromagnetism

This paper presents a constructive reformulation of steady-state classical electromagnetism grounded in a single primitive vector field W, termed the Field Potential. Every electric charge possesses an associated Field Potential, established outward at speed c upon the charge's creation and thereafter co-moving rigidly with it. From the defining relation - W, all electromagnetic fields are derived as geometric projections onto the radial propagation direction and the transverse relative velocity. Three constraints on W—irrotationality, radial alignment, and transverse uniformity—are derived from a minimality principle and interaction geometry, not postulated independently. The framework reproduces Coulomb's law, derives the effective electric field E₄₅₅ = Eₒ / _ from a velocity triangle encoding retardation self-consistently, and obtains the Lorentz factor as the geometric ratio c / cq without spacetime kinematics. The magnetic field emerges as a derived quantity B = (v_ Eₒ) / c², with B = 0 proved as a theorem. The Helmholtz decomposition unifies scalar and vector potentials as projections of W, reducing gauge freedom to a single constant shift. The steady-state Maxwell equations are derived from superposition and Stokes' theorem, not postulated. The potential energy of a moving test charge is U = _ q (V - A v_), vanishing as v_ c. The paper argues that classical electromagnetism can be founded on a more economical and mechanistically transparent basis than the conventional formulation, with the observer playing no role in the ontology and the Lorentz factor emerging from field-encounter geometry.