The Aharanov-Bohm Phase Shift and Magnetic Vector Potential A Could Accommodate for Optical Coupler, Digital-to-Analogue Magnetic Field Excess Correlations of Photon Emissions Within Living Aqueous Systems

Abstract

Quantitative convergence for solutions involving electron drift velocity, the magnetic A vector and phase shifts reveal an increment of energy in the range of 10^-20 J that could relate the Aharanov-Bohm phase modulation of the orbital frequency of a Bohr atom to the electrons Compton wavelength. The universal persistence of 10^-12 W per m² whose energy applied the square of the hydrogen wavelength solves for the energy equivalence of the rest mass of an electron could set the conditions for excess correlations between electronic systems that produce magnetic fields through optocouplers. Experimental evidence and quantitative solutions indicate variations of the Lorentz Lemma and circularly rotating magnetic fields whose phase and group velocities are uncoupled could create the conditions for excess correlations. Modification of Basharovs operator of resonance interaction for decoherence and entanglement in the radioactive decay of a diatomic system and Das and Misras estimates for the fractal charge of a photon strongly suggests that the efficacy for optocoupler circuits to generate non-local magnetic field effects in living and non-living aqueous systems originates from a single photon wave across the circuits p-n junctions. A review of the concepts and data indicate that excess correlations involving photons under optimal conditions are measureable within macrosystems