Water oxidation of photosynthesis at the oxygen evolving complex (OEC) is driven by the polarization field induced by the photoelectric hole. By highlighting the role of the polarization field in reshaping the spin-orbit coupling deduced from the Dirac quantum mechanics, we reveal in this work the characteristics and underlying mechanism in the relatively simpler OEC evolutions within the states S0 - S2 prior to the water oxidation. The characteristic shifts of the density of states (DOS) of the electron donor Mn atom are observed in the vicinity of the Fermi surface to occur with the spin flips of Mn atoms and the change of the Mn oxidation states during the electron transfer. Notably, the spin flips of Mn atoms point to the resulting spin configuration of the next states. It is found that the electron transfer tend to stabilize the catalyst OEC itself, whereas the proton transfer pushes the evolution forward by preparing a new electron donor. Meanwhile, it shows that the Mn-O bonds around the candidate Mn atom of the electron donor undergo characteristic changes in the bond lengths during the electron transfer. These concomitant phenomena uncovered in first-principle calculations characterize the essential equilibrium of the OEC between the state evolution and stability that forms a ground of the dynamic OEC cycles.