Derivation of the Neutron Magnetic Moment and Spin from Qc Pairing Asymmetry within the VTI Framework

Author(s)	Prof. Dr. Vijay T. Ingole, Dr. Anant S. Wadatkar
Country	India
Abstract	The neutron possesses a well-established magnetic dipole moment despite its electrical neutrality, indicating the presence of internal charge dynamics. In this work the neutron is examined within the Vacuum Tension Interaction (VTI) framework, where the neutron is modeled as a confined assembly of discrete quantum-charge units (Qc). The Qc population contains an odd number of units, producing a pairing asymmetry in which most Qc units form spin-paired states while a single unpaired Qc unit determines the magnetic moment and net spin of the neutron. Using the confinement energy derived from the earlier neutron structural analysis and the characteristic internal Qc separation scale, the magnetic dipole moment is obtained from classical current-loop relations. The predicted magnetic moment agrees with the experimentally measured neutron magnetic moment to within close limits. The results suggest that neutron spin and magnetism may emerge naturally from the structural asymmetry associated with the unpaired Qc unit within the neutron.
Keywords	Neutron magnetic moment, Neutron spin, Quantum charge units (Qc), Vacuum Tension Interaction (VTI) framework, Internal charge structure, Magnetic dipole moment, Nuclear magneton
Field	Physics > Energy
Published In	Volume 7, Issue 2, March-April 2026
Published On	2026-03-12

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