Application of the BSM-SG atomic models for analysis of nuclear transmutations

<p>Stoyan Sarg Sargoytchev</p>

Application of the BSM-SG atomic models for analysis of nuclear transmutations

Stoyan Sarg Sargoytchev

World Institute for Scientific Exploration, USA

: J Nanomater Mol Nanotechnol

Abstract

According to the Basic Structures of Matter -Supergravitation Unified Theory (BSM-SG), the near field of atomic nuclei exhibits a space micro-curvature. This effect distorts the space-time parameters of the near field, which is one of the reasons that Quantum mechanical models work only with energy levels. The re-examination of scattering experiments from this point of view reveals a complex three-dimensional nuclear structure different from the quantum mechanical models of atoms based on the Bohr atomic model. BSM-SG atomic models are one of major derivations of the BSM-SG theory. Protons and neutrons are not point-like; the atomic nuclei are with a much larger overall size, so the Coulomb barrier is not so strong. This explains the observed nuclear transmutations at accessible temperatures. The pattern of periodic table carries a strong signature of the spatial arrangement of protons and neutrons in the atomic nuclei. The nuclear spin and nuclear magnetic resonance are also identifiable features of the nuclear configuration, so they obtain a classical explanation. The BSM-SG models fit well when modeling of molecules in structural chemistry. They also provide a new opportunity for analysis and prediction of some nuclear transmutations in the field of LENR. This issue is presented in the author’s book “Structural Physics of Nuclear Fusion”. The book describes a new method for theoretical estimation of the binding nuclear energy based on the derived nuclear dimensions of hadrons and derived strong force parameters. This provides considerations for a proper selection of the isotopes for LENR with a lack or minimal radioactive waste.