Is the nuclear attraction just magnetic moment interaction between nucleons?

Abstract By reexamining the magnetic moment interaction between nucleons, it is argued in this article that the formula for calculating magnetic induction generated by magnetic moments derived from electrodynamics under far-field conditions is unsuitable for calculating near-field interactions between magnetic moments. When nucleons undergo magnetic moment interactions under near-field conditions, there is a strong magnetic flux coupling, similar to that in a transformer circuit.By assuming magnetic flux quantization generated by nucleons, the magnetic induction intensity can reach 105 T, providing enough magnetic attraction to overcome the Coulomb repulsion. A reasonable explanation for the binding energy of atomic nuclei under magnetic moment interaction conditions was provided. It is suggested that the upper limit of binding energy resulting from the magnetic moment interaction between protons and neutrons is approximately 125 MeV. The article analyzes the possibility of the existence of 2He nuclei composed of only protons and explores the relationship between neutron decay and strong magnetic fields. In the analysis of the magnetic structure of 4H nucleus, it is pointed out that the magnetic moment interaction is likely the fundamental reason for nuclear force saturation and multi-body force.A reasonable explanation for nuclear force can be provided through the hypothesis of nucleon magnetic flux quantization and the modification of the magnetic moment-field formula derived under far-field conditions. It suggests that nuclear force and strong interaction are likely to be electromagnetic forces. Furthermore, atomic nuclei may only be made up of buckyballs with equal amounts of positive charge and no net charge.