Waveguides aren't just transmission lines but rather
due to there design complexities make-up complete
Resonant Inductive Capacitive Circuitry...
I started out with 2-cavities from several
old C-band dish antennas and joined the sections
of the resonant cavities together at their choke
joints, milled several apertures or holes, along
with a groove in the choke joint, and a set of slotted
line antenna in the floor of the waveguide to act
as my atom trap and optically coupled photons into
the waveguide with a set of lens apertures. I fabricated
a multi-element transformer form ferrite beads with
spark gap switching.
The design concept
is modeled after Nikola Tesla, Moray and Plauson's
"Radiant Energy Converters", its the forbidden free
energy technology that academia claims as impossible.
Funny thing about splitting the atom is
you get lots of free energy...
Cavity-QED, Atom-Coupled Optical Waveguides, ZPE
Primarily the focal length or optical coupling
is equivalent to the size of an atom i.e. the focal
point is one atom across at the focal length of
the lens, and trapped via the dipole effect of the
slotted line antenna, also take into consideration
the polarization or rotation of the light wave,
e.g. when the light is focused to a point you have
this shape "V" plus the rotation which effectively
causes the wave to spin in the manner of a vortex,
hence there is an implosion, or inversion of energy
into the waveguide. In other words the energy is
caused to cohere and corkscrew itself into the waveguide...
An associative analogy would be to compare
the low frequency with that of a small valve on
a spray-can i.e. the small valve atop the spray-can
controls a larger pressure likewise the low frequency
controls the high frequency pressure in this energy
Interesting aspects of
atomic behavior in the presence of strong driving
fields appear when the driven atom resides not in
free space, but in a region (such as an optical
cavity) that displays a frequency-dependent photon-mode
density. Optical excitation provides an important
means of controlling the internal state of quantum
systems. Optical sources are important to areas
such as quantum state preparation, quantum computing
and coherent control.
Cavity atoms experience
significant squeezing under the influence of strong
driving fields. These squeezing effects are intrinsically
connected to the polarization of dressed state populations
by tuning the cavity appropriately close to the
atomic transition frequency we may induce a non-vanishing
inversion of the dressed-state's setting the standard
for optimal conditions for atomic squeezing.
This mechanism is associated with the coupling
of the atom to the zero point electromagnetic fields,
empty-cavity transmission resonances are found to
split in the presence of the atoms and under these
conditions the cavities temporal responses are found
to be oscillatory.
Robert A. Patterson