Superparticles from the Initial Universe and deduction of the Fine Structure Constant and Uncertainty Principle directly from the Gravitation Theory

In a previous work it was shown that the gravitational and inertial masses are correlated by an adimensional factor, which depends on the incident radiation upon the particle. It was also shown that there is a direct correlation between the radiation absorbed by the particle and its gravitational mass, independently of the inertial mass. This finding has fundamental consequences to Unified Field Theory and Quantum Cosmology. Only in the absence of electromagnetic radiation the mentioned factor becomes equal to one. On the other hand, in specific electromagnetic conditions, it can be reduced, nullified or made negative. This means that there is the possibility of the gravitational masses can be reduced, nullified and made negative by means of electromagnetic radiation. This unexpected theoretical result was recently confirmed by an experiment (gr-qc/0005107). A fundamental consequence of the mentioned correlation is that , in specific ultra-high energy conditions, the gravitational and electromagnetic fields can be described by the same Hamiltonian , i.e., in these circumstances, they are unified. Such conditions can have occurred inclusive in the Initial Universe , before the first spontaneous breaking of symmetry. Taking as base this discovery, and starting from the gravitational mass of superparticles from the Initial Universe we show here that it is possible to deduce the reciprocal fine structure constant and the uncertainty principle directly from the Gravitation Theory(Unified Theory).