Quantum Electrodynamics of Piezoelectric Effect

The present invention

combines non-linear acoustic amplifiers and dampeners in the form of a phase-shifted active acoustic mirror, passive radiators as self-reinforcing electromagnetic circuits, the piezoelectric effect as electron fusion visa vi the multi-axial nodal Full wavelength quantum oscillators using the hysteresis of the three quasi-particles that define the spin, spinon, charge, holon, and path, orbiton, of an electron as the mold to make more electrons in the vacant valence of the piezoelectric material by condensing the truly elemental fermions, the quasi-particles of an electron into an electron by inducing an influx of quantum energy attracted to the positive charge created by the vacant electron being ejected by a transient boson in the medium.
Further investigation into this phenomenon suggests that a reactionary magnetic moment is amplified by the physical stress from the transient boson forcing the ejection of the electron that occupied the valence band of the piezoelectric material. This magnetic moment is actually memory, the hysteresis that dictates the spin charge and orbit of every subsequent electron produced by that quantum oscillator unitary cell. This magnetic moment is responsible for generating a positive electrical field that attracts the quasi-particles (uncondensed fermions) of an electron (Condensed, but “elemental” fermion) from the Quantum Field.
We hypothesize that quantum wells of the crystal lattice in the metal nitride iii-v semiconductors are Full Wavelength third order harmonic resonators for the wave functions of the quasi-particles comprising electrons. Currently  electrons are considered “elemental” fermions, yet they can be composited through a fusion process on the quantum scale as explained by quantum electrodynamics. The quantum wells that produce the most powerful electric charges per force/stress input have additional qualities as of yet unexplained by standard models.
We further hypothesize that due to the necessary material thinness at one end of the resonator to allow for quantum tunneling and electron mobility that the condensing of the quasi-particles into an electron occurs in a plane regular to the direction of electron mobility. That means that all six pieces of information, or metadata, that defines the electron as a fermion with negative charge, up or down spin, and the orbital address within the crystal lattice remain intrinsic to each quantum well. Three pieces of metadata describe the electron itself, its charge, spin, and orbital path. The other three pieces of metadata describing the quantum oscillator-electron system is the spacial context of the quantum oscillator w regard to the electron contained within. This is believed to be pertinent due to the intended exit path of the electron being predetermined at manufacturing, i.e. directed fermion release based on the induction from the transient boson driving electron mobility.
The term, induction, is used for the interaction between medium, the iii-v semiconductors, the electron in the quantum well and the transient boson that causes the ejection of the electron from the quantum well in the crystal lattice. As the transient boson traverses the quantum well the vertical edges in the y-axis compress the quantum cavity providing electromagnetic linear induction forcefully ejecting the electron at a known or knowable velocity in the direction of least resistance in the material until reaching the metallic conductor and continuing its journey.
Why doesn’t the compressed well and electromagnetic induction force the electron into the bottom of the well? The ejected electron is not alone in the quantum well. The quantum well is a full wavelength third order harmonic resonator, which means essentially that there is one whole electron and two separate halves of an electron in the same well. When the walls of the quantum well are compressed the two halves of an electron are brought so closely together that they form an electron in the lowest energy level. Two fermions cannot occupy the same place in space-time and since they have the same charge, they repel one another instantly.
The electron on top drifts towards the conductor while the bottom electron is forced into the bottom of the well in an elastic collision and as it rebounds towards the quantum well’s harmonic center subsequently increases the exit velocity of the top electron in the predetermined direction at device manufacturing. The remaining whole electron is then returned to rest via dampened harmonic oscillations on the y-axis. The space on either side of the electron in the quantum well has a remaining positive charge field which draws additional quantum energy in the form of negatively charged fermion quasi-particles through the quantum vortices which double as magnetic memory instilling each subsequent electron with the same metadata of spin charge and orbit, as the previous electrons.
 Figure 1.
Remember that the Thermodynamic calculation of energy of an electron is an order of magnitude lower than the actual Fermi energy of an electron until the temperature surrounding the electron is two orders of magnitude higher than STP. This means if a peer attempting to verify or discredit our hypotheses uses standard thermodynamics to attempt to do so, they have already failed the rigors of scientific method.
Additionally, the presence of two electrons in every quantum well, one as a whole electron, and the other as two separate halves could answer questions about fractional integer spin dynamics. Setting up an experiment to determine the cog like relationship between the spinning electron and the spinning halves attached to the quantum oscillator walls could answer additional questions and more importantly raise several other questions not before asked which have far reaching consequences for the Standard Model of Physics.

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