Short & Simple
Phased Particle Theory
By Michael A. Carlson
I propose herein a new model
of how matter functions at the atomic level: that phased particles, magnetism
and thermo-fields define the basic interaction of the material universe.
Phased-particle theory is separated into three concepts. The first part addresses the nature of
sub-atomic matter. Sub-atomic particles
of matter are non-reactive to normal matter
(thus, for all practical purposes, invisible to us) until they are
charged with energy. The photon is a
variety of sub-atomic particle that phases into and out of our
three-dimensional universe when a wave of light energy (or photonic energy)
charges the photon. To be absorbed, the
waves of photonic energy that travel through the universe must encounter an
un-energized photon particle that has the correct orientation. The photon
particle becomes dynamic matter with physical characteristics, and is now an
active part of the physical universe. The reason light behaves paradoxically
both as a wave and as a particle, is because it is a particle (photon) when charged
with photonic wave energy and a wave of energy when traveling between photons.
The second part concerns magnetism. All magnetic fields are closed loops of energy, and both electrons and protons are complete magnets, both having north and south poles. The interaction of this elementary magnet within the atom has profound implications for chemistry and for electrical systems, as well as the physical arrangement of protons and neutrons within the atomic nucleus.
The third concept proposes the existence of a field of energy that
surrounds atoms, called the thermo-field. It emanates from every proton within
the atomic nucleus, and it’s how the protons sustain the heat energy of the
atom. All protons maintain two closed
loops of energy, the heat energy of the thermo-field and the magnetic energy of
the magnetic field. The significance of this is that the heat energy field
(thermo-field) of a single proton balances one electron’s orbit. Instead of
reacting to the magnetic energy of the atomic nucleus, the electron’s orbit is
linked to the proton’s thermo-field. This realization about the relationship
between the thermo-field and electrons influences how we can define the states
of matter, as well as other effects. The thermo-field responds to any change of
heat energy as a change in temperature or pressure (field size). We observe the
variability of the thermo-field’s strength and size in response to heat as
measured by temperature, mitigated by the position of the electron’s orbit.
If this model is borne out experimentally, it will have numerous and valuable practical applications in all sciences, particularly applied chemistry and physics.