Super Quantum Neuroelectromagnetic Dynamics of Action and Percept Potentials

The spatiotemporal selectivity of neurons to sensory stimuli that underlie the center and surround receptive fields represents the anticommutative and, thus, symmetry that defines sensorimotor transformation. However, owing to the nonabelian nature of the irresponsiveness of neurons to sensory stimuli characterized by inexcitations, symmetry and, thus, transformation does not become apparent. Hence, a neuroscientific model that describes the precise mechanism of the nonabelian gauge group in the brain is unknown. Using quantum field theory, we show visuomotor transformation of natural images in which the superposition of opposite parallel cortical columns creates visual fields and annihilates motor fields. The creation and annihilation operators, magnetic and electric charged particles, are opposed inertia systems that act on each other by raising and lowering each others particles, leading to momentum-energy trade-offs, in our case, retinotopic gain and retinomotion loss, and vice versa. The magnetic charged particles K-, Cl+, Na-, intrinsic to a magnetic neuron, nabla, are predicted to exist opposite parallel to the electrically charged particles Na+, Cl-, K+ of the electrical pyramidal neuron in the neocortex. The implication is that the physical neocortex or electric brain is in concert with a nonphysical complex neocortex or magnetic brain that is hardly detectable but much alive and proactive.