ABSTRACT
Intimately involved with growth and development biological dif-
fusion includes random motions and non-random electric (E) and
magnetic (H) field offsets of charged and dipolar entities. Diffusion
applies to biology generally, to the cell cycle and the body’s
mechanisms for repair and maintenance in particular. Diffusive
phenomena concern particles of relatively large atomic mass and
biophotons of tiny mass. Self-field theory (SFT) brings fundamental
factors to the theory of diffusion. Having internal structure biopho-
tons can change state abruptly, inducing cascades at discrete energy
levels and frequencies. In SFT E and H fields are opposite forms
of motion, analogous to charge. H fields remove energy, while E
fields add energy, for example, the earth’s polar zones are regions
of high H fields, where the earth loses energy, while the equatorial
zone is a high-E field region, where the earth gains energy. Chemical
cascades occur at ‘thermal’ energies, for example, rain formation
via storm clouds, and ‘non-thermal’ energies, for example, cell
division.Mechanisms of growth and repair include cascades. Various
effects are excluded from classical electromagnetics (CEM) heat
analyses. But Planck’s blackbody theory applies to all frequencies. In
many viscous models of diffusion motion is assumed translational,
ignoring rotational effects. Theory and observations of rotation of
cell nuclei or proteins within membranes help explain window
observations of Adey at low levels of extremely-low-frequency
(ELF) exposure, significantly below international standards of
exposure limits. The physical mechanism is the EM excitation of a
dipole, similar to SFT’s dipole-dipole gravitational interaction. Both
physical mechanism and its biophysical analogue support Adey’s
window effects in embryonic colonies.