In this study, the relationship between the elementary masses and elementary charges of quarks and electrons is considered in connection to the strong nuclear force and the color charge. The relationship is further considered in connection with the matter-antimatter asymmetry problem, and the decay times for different particles. The results strongly suggest that the quarks can be expressed as charge equalization of the electron, and that the coincidence of the charges has no alternative way to be unified with the elementary masses. To solve these problems, a new standard model with a second group of antiparticles is proposed, and the strong nuclear force is considered as an interaction between equalized electric charges instead of being a fundamental force, which also explains its short-ranged high strength. A new periodic table of elements is proposed to unfold the overall number of elementary charges that make up the atomic nucleus of different elements.
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