An Electrical Power Source Is a Dipolar Antenna For Free Reception of Energy

An Electrical Power Source Is a Dipolar Antenna For Free Reception
of Energy
An electrical power source is in fact only a dipolar antenna for reception of potential
(hidden bidirectional Whittaker/Ziolkowski waves). All the current you run back through
the back emf of the source, to perform dissipative work inside it, is something you yourself
are doing to the source. It is not a priori a characteristic of the source!
If no work is done inside the source's internal bipolar separation of charges (i.e., if no
electron or ion current is forced back up from the ground return line against the sourceantenna's
potential and therefore against its back emf), then the dipolar source-antenna will
last essentially forever, or until something corrodes or breaks mechanically.
The flow exchange of energy between the vacuum and the dipolar source-antenna is freely
driven by all the charges of the universe, in accordance with Puthoff's cosmological
feedback loop. [Ref 17]
Massless Displacement Current
Technically one is using massless displacement current to charge the capacitor, rather than
electron mass flow current. It is real energy flow nonetheless; just in work-free,
dissipation-free form. As is well-known, one plate of a capacitor already charges the other
plate by just this very massless displacement current, transporting real EM energy across
the gap between the plates in the process. The electrons themselves do not cross the gap.
Displacement current is already well-known to be "free" energy transport without any
dissipation as power and work. By drawing massless displacement current only from the
source-antenna instead of electron flow current, you can draw work-free, dissipation-free
energy as long as you wish, as often as you wish, and as much as you wish, without ever
dissipating the source-antenna. You just have to collect it onto some trapped electrons or
other charges, such as in a capacitor's plates, then switch the collected energy (charged
capacitor) separately across a load, in a separate discharge circuit, to discharge through the
load as work.
The real trick is to prevent the electrons in the circuit from moving and providing mass
"energy dissipation" current inside the source during the collection process. In the original
paper, we explained that this could be done by using as a collector a degenerate
semiconductor material, with extended electron gas relaxation time. In this paper we have
explained how this can be done by step-charging an ordinary capacitor as a collector. We
have also included specific references proving (both experimentally and theoretically) that
this is correct. With the requirement for special materials removed, there is no reason that a
competent researcher cannot develop a step-charged capacitor device to prove it
experimentally for himself or herself.