Quantum Nucleardynamics as an SU(2)N × U(1)Z Gauge Theory
Abstract
It is shown that quantum nucleardynamics (QND) as an SU(2)N × U(1)Z gauge theory, which is generated from quantum chromodynamics (QCD) as an SU(3)C gauge theory through dynamical spontaneous symmetry breaking, successfully describes nuclear phenomena at low energies. The proton and neutron assigned as a strong isospin doublet are identified as a colorspin plus weak isospin doublet. Massive gluon mediates strong interactions with the effective coupling constant GR/2= gn2/8 MG2 ≈ 10 GeV-2 just like Fermi weak constant GF/2 = gw2/8 MW2 ≈ 10-5 GeV-2 in the Glashow-Weinberg-Salam model where gn and gw are the coupling constants and MG and MW are the gauge boson masses. Explicit evidences such as lifetimes and cross sections of nuclear scattering and reaction, nuclear matter and charge densities, nucleon-nucleon scattering, magnetic dipole moment, gamma decay, etc. are shown in support of QND. The baryon number conservation is the consequence of the U(1)Z gauge theory and the proton number conservation is the consequence of the U(1)f gauge theory.
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