[1] viXra:0810.0003 [pdf] submitted on 11 Oct 2008
Authors: Maurizio Michelini
Comments: recovered from sciprint.org
Particles moving within the flux of micro-quanta filling the
space have been shown to obey the Relativistic Mechanics and
to undergo a gravitational �pushing� force with G depending
locally on the quantum flux constants. Due to the very little
quantum energy Eo , the ratio Eo/mc2 equals about 10-50 so the
collisions with particles follow the optical reflection
accurately. The simultaneous micro-quanta hitting upon a
nucleon are about 1050, a high number due to the small
wavelength which results close to Planck�s length. Along the
joining line between two particles there is a lack of incident
quanta (missing beam) which determines unbalanced
collisions generating drawing forces between particles by
mutual screening. These forces increment the particle energy,
as shown for instance by the heating during the gravitational
contraction of the galactic gas globules leading to protostars.
This mechanism allows to predict that observations of the
thermal emission from major solar planets may exceed the
power received from solar light. When two particles are very
close, the mutual screening highly increments the missing
beam, giving rise to a short-range strong force which is of the
right strength to hold protons and neutrons within the atomic
nuclei. The belief that nuclear forces are �self-produced� by
nucleons is disproved. Proof is given for the structure of the
simple Deuterium nucleus. The same process originates also a
short-range �weak� force on the electron closely orbiting a
proton, giving rise to the neutron structure which undergoes
β- decay. The mutual strong forces on a nucleon pair are
equal, but the weak force on the bound electron differs largely
from the force on the proton (breakdown of Newton�s action
and reaction symmetry).
Category: High Energy Particle Physics