Nicolai Levashov. Spirit and mind. Vol.1

            are  inorganic  atoms,  molecules  and  ions.  Additionally,  photons  are  of  varying
            wavelength  (λ)  and  frequency  (f),  representing  every  color  of  the  spectrum  and
            therefore form their own characteristic pattern of atoms and molecules according to
            their respective wavelengths. Thus, the photon's wavefront alters the dimensionality
            level at the point of penetration, at distance λ/4 from the top of the wave, while the
            cell's microspace dimensionality remains the same as it was before the arrival of the
            wavefront.

                  At  distance  λ/2  from  the  top  of  the  wave,  the  microspace  dimensionality
            decreases by an amount commensurate with the wave's amplitude. That is, a photon
            moving within a light-sensitive cell creates a dimensionality gradient which enables

            those molecules, atoms and ions commensurate with its wavelength to generate new
            chemical compounds. At the same time, the photon itself is absorbed (see Fig. 13).

                  This process unfolding inside the light-sensitive cell leads to a surplus of ions.
            Further, the qualitative structure and the number of surplus ions are determined by
            the wavelength of the photon absorbed. Following these events, the initial (and usual)
            dimensionality of the cell returns. During the period of cell "disturbance" the cell is
            unable to absorb other photons; for this reason the light-sensitive retina is incapable
            of "seeing" the twenty-fifth frame...

                  The  color  signals,  which  are  produced  by  the  photons'  varying  wavelengths,

            become an ionic code, which starts its journey to the occipital and temporal cerebral
            cortex via the neurons of their optic zones through a series of specialized cells. The
            ionic code (really a redistribution of the ions) reaches the light-sensitive cells through

            synapses (contact zones), triggering a forced redistribution of ions inside the bipolar
            cells.

                  In turn, the bipolar cells transfer their altered qualitative state to the ganglion
            cells,  following  which  the  resulting  electrochemical  redistribution  is  transmitted
            along  the  optic  nerve  fibers  to  the  occipital  and  temporal  cerebral  cortex  via  the

            neurons of its optic zones. Thus, through the axon bundles which make up the optic
            nerve, a signal in the form of ionic redistribution (ionic coding) reaches the neuronal
            bodies of the brain. (See Fig. 71).































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