Dual Magnetic and Electric Dipole Symmetry: Pseudo Angular Momentum in Parity Space and the Electric Landé g-Factor

Abstract

Electric dipole moments (EDMs) are sensitive probes of fundamental symmetries and central to searches for physics beyond the Standard Model. We present a symmetry-based, Zeeman-analogue operator framework that places magnetic and electric dipole physics on parallel footing under electromagnetic duality, and introduce a polar-sector pseudo-angular-momentum degree of freedom in parity space together with an associated electric Landé factor that organizes induced orbital dipoles. Following Ohanian's effective-current formulation of the Zeeman effect, we construct its electric dual: the wavefunction's microscopic polarization admits an equivalent effective magnetic probability-current representation, providing a field-equivalence description of parity-mixed charge displacement. In this notation the total EDM expectation takes the unified form d tot= dB(gE\, Jp+ gEe\, S), with gEe=2d intdB, where Jp captures Stark-induced pseudo-angular momentum and S encodes any intrinsic (spin-aligned) EDM d int from symmetry-violating interactions. We define a natural electric dipole unit (the ``Bohr EDM'') as dB e a0=2μBcα (a0 the Bohr radius and μB the Bohr magneton). As a canonical analytic benchmark, we show in the hydrogenic problem that a static electric field couples within a fixed n manifold through the scaled Runge--Lenz structure, yielding a compact Landé-like description and reproducing the Stark doublet (e.g.\ | d orb|=3dB for the 2s--2pm=0 mixing).