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Author(s)
The binding energy of the deuteron is calculated
electromagnetically with the Schrödinger equation. In mainstream nuclear
physics, the only known Coulomb force is the repulsion between protons,
inexistent in the deuteron. It is ignored that a proton attracts a
neutron containing electric charges with no net charge and that the
magnetic moments of the nucleons interact together significantly. A
static equilibrium exists in the deuteron between the electrostatic
attraction and the magnetic repulsion. The Heitler equation of the
hydrogen atom has been adapted to its nucleus where the centrifugal
force is replaced by the magnetic repulsive force, solved graphically,
by trial and error, without fit to experiment. As by chance, one
obtains, at the lowest horizontal inflection point, with a few percent
precision, the experimental value of the deuteron binding energy. This
success, never obtained elsewhere, proves the purely static and
electromagnetic nature of the nuclear energy.
Cite this paper
Schaeffer, B. (2014) Electromagnetic Schrödinger Equation of the Deuteron 2H (Heavy Hydrogen). World Journal of Nuclear Science and Technology, 4, 228-236. doi: 10.4236/wjnst.2014.44029.
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