Abstract
Since the new frames in physics present a divergenceless mathematical framework for the interaction between the electron fields and the zero-point photon fields, they provide a powerful tool for the analysis of the mechanism of the superconductivity. The minimal coupling effective Hamiltonian predicts that the interaction of a single electron field with a normal-mode of the photon can raise its amplitude by a magnitude of more than 10-7, so that, by the participation of the superconductive electron fields of more than 107 in the number, and, under the action of the proposed possible Q enhancement of the mesoscopic in-crystal resonator, a good possibility is present that a unified complex of the electron fields and the zero-point photon fields is cooperatively created in the specimen. Since this mechanism is spin-independent and has no direct relation to the phonon modes, no isotope effect nor serious effect from the magnetic ions is expected. Different from metals, since the oxides have the ionic lattice which is more rigid and more difficult to be excited by the photon fields, the coupling between the resultant electron-photon field complex and the thermal modes of the phonon fields of the lattice should be much smaller.
