Emphasizing the Electromagnetism According to Maxwell's Initial Interpretation

It is well established that classical electrodynamics, quantum electrodynamics (QED) as well as
Quantum Field Theory (QFT) are grounded on Maxwell's wave theory and on his equations, but it is
much less well understood that they are not grounded on his initial interpretation of the relation
between the E and B fields, but are rather grounded on Ludvig Lorenz's interpretation of this relation,
with which Maxwell disagreed. Maxwell considered that both fields have to mutually induce each other
cyclically for the velocity of light to be maintained while Lorenz considered that both fields had to
synchronously peak at maximum at the same time for this velocity to be maintained, both
interpretations being equally consistent with the equations. Two recent breakthroughs however now
allow confirming that Maxwell's interpretation was correct at least with regard to the subatomic level
because, contrary to the Lorenz interpretation, it allows to seamlessly reconcile Maxwell's
electromagnetic wave theory, so successfully applied at our macroscopic level, with the
electromagnetic characteristics that apply at the subatomic level to localized electromagnetic photons
and to all localized charged and massive elementary electromagnetic particles of which all atoms are
made, and finally allows establishing a clear mechanics of electromagnetic photon emission and
absorption by electrons during their interactions at the atomic level. The education community now
has at its disposal a complete set of demonstration experiments easily reproducible during hands-on
laboratory teaching sessions, ranging from the first Coulomb electric experiment to the 1998 magnetic
experiment to help teaching and confirming every aspect of electromagnetic energy behavior at the
subatomic level.