@article{Ozawa_2022, title={M-3: The Emergence of Strong Interaction: Particle Physics}, volume={2}, url={https://hscience.org/index.php/hij/article/view/29}, DOI={10.55672/hij2022pp91-96}, abstractNote={<p>The conclusion of this paper is that the strong interaction that emerged as the universe developed through the ‎mediation of two pairs of four types of neutrinos (v_µ ,v ̅_µ ,v_e ,v ̅_e) acted on two pairs of four types of ‎quarks/anti-quarks (u,u ̅,d,d ̅) to form two particle groups each having an electrical charge composition of (+1, -1, ‎‎0, 0) the π-on group (π^+,π^-,π^±,π^0 ) and the nucleon group ( p, p ̅, n, n ̅), which became the ‎constituent materials for 120 types of atomic nuclei/anti-atomic nuclei. That is, the emergence of strong interaction ‎is the physical force that shouldered the central role within the causal chain that was the development of the ‎universe: From neutrino and quark/anti-quark → nucleon/anti-nucleon → electron/positron, atomic nuclei/anti-‎atomic nuclei → elements/anti-elements and so on. The quark chromodynamics on strong interaction of the ‎Standard Model however accounts for the emergence of strong interaction as basically the result of the union of ‎three colors/anti-colors of quarks/anti-quarks and is, therefore, no more than the result of a random accident. Hence, ‎the principle of strong interaction according to the Standard Model is not a causal property that emerged in line ‎with the flow of the development of the universe. For that reason, it is not possible for this principle to organize and ‎connect the past, the present, and the future in a sophisticated manner.‎</p>}, number={3}, journal={Hyperscience International Journal}, author={Ozawa, Naohiro}, year={2022}, month={Sep.}, pages={91–96} }