Nuclear Lattices, Mass and Stability

doi:10.4236/oalib.1101504

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Open Access Library Journal 2 2015

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Nuclear Lattices, Mass and Stability

DOI: 10.4236/oalib.1101504, PP. 1-22

Henry Gu Cao, Zhiliang Cao, Wenan Qiang

Subject Areas: Nuclear Physics, Theoretical Physics, Particle Physics

Keywords: Neutron-Proton Pairing, Particle-Number Projection, Nuclear Lattice, Particle Physics, BCS

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Abstract

A nucleus has a lattice configuration, a mass, and a half-life. There are many nuclear theories: BCS formalism focuses on Neutron-proton (np) pairing; AB initio calculation uses NCFC model; SEMF uses water drop model. However, the accepted theories give neither précised lattices of lower mass nuclei, nor an accurate calculation of nuclear mass. This paper uses the results of the latest Unified Field Theory (UFT) to derive a lattice configuration for each isotope. We found that a simplified BCS formalism can be used to calculate energies of the predicted lattice structure. Furthermore, mass calculation results and NMR data can be used to determine the right lattice structure. Our results demonstrate the inseparable relationship among nuclear lattices, mass, and stability. We anticipate that our essay will provide a new method that can predict the lattice of each isotope without the use of advanced mathematics. For example, the lattice of an unknown nucleus can be predicted using trial and error. The mass of the nuclear lattice can be calculated. If the calculation result matches the experimental data and NMR pattern supports the lattice as well, then the predicted nuclear lattice configuration is valid.

Cite this paper

Cao, H. G. , Cao, Z. and Qiang, W. (2015). Nuclear Lattices, Mass and Stability. Open Access Library Journal, 2, e1504. doi: http://dx.doi.org/10.4236/oalib.1101504.

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