Authors: Maurizio Michelini
A preceding paper showed that particles moving within a flux of microquanta (filling the space) obey the Relativistic Mechanics and undergo a newtonian-like pushing gravity with G depending on the quantum flux constants. Due to the very little quantum energy E, the ratio E/mc2 is very little, so microquanta follow accurately optical reflection in the Compton s collision with particles. The number of microquanta simultaneously hitting upon a nucleon is very high due to the small quantum wavelength, which equals the Planck's length. Along the joining line of two particles there is a lack of incident quanta (missing beam) which determines unbalanced collisions generating a force between them. The pushing gravity increments the particle energy (through the microquanta collisions) during the contraction of the galactic gas globules leading to protostars. This mechanism predicts that observations of the thermal emission power for major solar planets will 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. Considering the microquanta constants, this force is of the right order to hold protons and neutrons within the atomic nuclei. The old belief that nuclear forces are produced by the nucleons is discarded. Proof is done of the structure of the Deuterium nucleus. The same process originates also a shortrange weak force on the electron closely orbiting a proton, thus originating the neutron structure. While the mutual forces on a nucleon pair are equal, the weak force on the electron differs from the force on the proton (breakdown of Newton s action and reaction symmetry).
Comments: 12 pages
[v1] 6 Aug 2008
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