American Journal of Modern Physics
Volume 6, Issue 4-1, August 2017, Pages: 29-45
Received: Aug. 28, 2016;
Accepted: Aug. 30, 2016;
Published: Sep. 26, 2017
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Anil A. Bhalekar, Department of Chemistry, R. T. M. Nagpur University, Amravati Road Campus, Nagpur, India
Ruggero M. Santilli, Thunder Energies Corporation, Tarpon Springs, Florida, U. S. A.
In preceding works, one of us (R. M. Santilli) has shown that, according to quantum chemistry, identical electrons cannot create the strong bond occurring in molecular structures due to their strongly repulsive Coulomb interaction; has constructed hadronic chemistry as a non-unitary covering of quantum chemistry solely valid at mutual distances of 10-13cm; has introduced contact non-Hamiltonian interactions in the deep penetration of the wavepackets of valence electrons that overcomes said Coulomb repulsion, resulting in a strongly attractive bond of valence electron pairs in singlet called ’isoelectronium’ and shown that the new valence bond allows an exact and time invariant representation of the binding energy of the hydrogen and water molecules. By using these advances and our inference that (from the fact that an atomic lone pair of electrons form a coordinate covalent bond identified by G. N. Lewis) the lone pairs of electrons are indeed isoelectronium, in this paper we present, apparently for the first time, a new structure model of the Helium atom under the name of Iso-Helium, in which the two electrons of a given orbital are strongly coupled into the isoelectronium that provided a quantitative description of Pauli exclusion principle. In particular, as a result of the strongly bound state of Santilli isoelectronium, the iso-Helium reduces to be a two-body system, thus admitting exact analytic solution. The presented analytic solution is applicable to all Helium-like systems. Using it we have calculated effective charge on the nuclei of Helium-like systems that are in excellent agreement with the literature values.
Anil A. Bhalekar,
Ruggero M. Santilli,
Two Body IsoElectronium Model of the Heliumic Systems, American Journal of Modern Physics. Special Issue: Issue III: Foundations of Hadronic Chemistry.
Vol. 6, No. 4-1,
2017, pp. 29-45.
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