The Universe Expansion evidences the possibility of thermodynamic dissipative structures, constituted by short-lived particles decaying and releasing energy, to form more stable ones during the period of 10^-26 to 10^-11 s. The thermodynamic of these processes favor the models, in which the cooling effects of expansion could be balanced by the temperature generated in the primordial absorption of bosons, particles decay and annihilation. The microscopic chronology during the state of plasma, maintains asymptotic freedom which allows multiple quark and antiquark aggregations, preventing massive annihilations. In the primordial quark-antiquark-gluon plasma emerges the Muons that show a 1% asymmetric annihilation, in the decay of B-mesons. This could be integrated into the cyclical elimination of antimatter, by incorporation into matter of the energy from environment bosons or pair annihilation. The self-duplication of pions provides such a mechanism because their constitutive quarks resist separation forces by generating gluons. Annihilation energy could be returned as a 99% that jointly with a 1% contributed by the resting mass of quarks, could create nucleons. The plasma evolved from pions and quarks annihilations, would have a large population of positrons, electrons and high energy photons. It is shown that coupling between reactions, allows nucleons cycles in which electrons, positrons and gamma radiation could be absorbed, generating neutrinos/antineutrinos. Hence, quantum chronology in a dynamics of open thermodynamics coupling becomes compatible with the description of the space-time like a continuum. In this, the universal constants, allows integrating dissipative potentials at different scales and within a large diversity of configurations, into the evolutive architecture of the universe.