Strong reactions in quantum super PDEs. III: Exotic quantum supergravity

Abstract

Following the previous two parts, of a work devoted to encode strong reaction dynamics in the A. Pr\'astaro's algebraic topology of quantum super PDE's, nonlinear quantum propagators in the observed quantum super Yang-Mills PDE, (YM)[i], are further characterized. In particular, nonlinear quantum propagators with non-zero defect quantum electric-charge, are interpreted as exotic-quantum supergravity effects. As an application, the recently discovered bound-state called Zc(3900), is obtained as a neutral quasi-particle, generated in a Q-quantum exotic supergravity process. Quantum entanglement is justified by means of the algebraic topologic structure of nonlinear quantum propagators. Quantum Cheshire cats are considered as examples of quantum entanglements. Existence theorem for solutions of (YM)[i] admitting negative local temperatures ( quantum thermodynamic-exotic solutions) is obtained too and related to quantum entanglement. Such exotic solutions are used to encode Universe at the Planck-epoch. It is proved that the Universe's expansion at the Planck epoch is justified by the fact that it is encoded by a nonlinear quantum propagator having thermodynamic quantum exotic components in its boundary. This effect produces also an increasing of energy in the Universe at the Einstein epoch: Planck-epoch-legacy on the boundary of our Universe. This is the main source of the Universe's expansion and solves the problem of the non-apparent energy-matter ( dark-energy-matter) in the actual Universe. Breit-Wheeler-type processes have been proved in the framework of the Pr\'astaro's algebraic topology of quantum super Yang-Mills PDEs. Numerical comparisons of nonlinear quantum propagators with Weinberg-Salam electroweak theory in Standard Model are given.