From:
Tom Bearden
Sent: September 12, 2006
Negative
Impedance: What It Is and How
It Works
Dear
Professor X:
There are
essentially two different uses of the term “negative
resistor” in electrodynamics.
The normal
usage means a circuit element in which more electrical output power (VI)
comes out than what goes in
directly, in just that part of
the circuit. However, the extra output power for that
section is still taken from the main circuit, so the operator
himself still has to input and pay for that
extra energy himself. So the usual “negative
resistance” circuit does not add a single watt
of extra power to the overall circuit.
So that
standard negative resistor
concept and usage is not a big deal, and such circuit subelements are
well-known to all good electronic engineers. Their problem is that
one still has to input the extra energy oneself, and pay for it. We quote
Wikipedia, which considers only positive energy EM and positive energy EM
flow:
“….Negative resistance or negative
differential resistance is a property of electrical circuit elements
composed of certain materials
in which, over certain voltage ranges, current is a decreasing function of
voltage. This range of voltages is known as a negative
resistance region.
Some writers prefer to reserve
the term negative resistance
for situations in which the negatively-sloping
portion of the load line passes through the origin, so that
a positive absolute value of voltage is associated
with a negative absolute value
of current. Such a circuit must contain an energy source, and can be used
as a form of amplifier. However, the use of the term negative
resistance to encompass negative
differential resistance is more common.
Absolute negative
resistances without an external energy source cannot exist as they would
violate the law of conservation
of energy.”
We note that
an absolute negative resistance
is permissible, without violating
conservation of energy, so long
as the active vacuum environment furnishes the extra required energy. The
circuit then is merely a COP>1.0 system, due to an extra energy input from
the environment, and analogous to a common home heat
pump whose efficiency is only about 50% (so that
half of all the energy input is wasted), but which receives so much excess
heat from its external
environment that it can still
output three to four times as much heat
energy as the electrical energy the operator
must pay the power company to provide. So the COP of that
50% efficient heat pump is COP
= 3 to 4, as is well-known.
So another
occasional usage is when a circuit element
does output more power
(VI) than what the operator
inputs, and the extra output power
is not taken from the main circuit, but is freely received
from the active vacuum environment via its ongoing interaction with the
charges (particularly in that
section). In this case, the operator
does not have to input and pay for that
extra input energy himself, since the active vacuum environment freely
furnishes it.
This latter
circuit is actually an asymmetric Maxwellian
system, of the kind arbitrarily
discarded by Lorentz in 1892, and still arbitrarily discarded today in
electrical engineering departments and texts.
This latter
negative resistor case is
almost always
attacked or disputed, since –
so the skeptics say – it must violate
conservation of energy. To the
contrary, it merely requires an input of extra energy freely from the
local vacuum environment, which is additional to the energy input by the
operator and paid for by him.
The resulting negative
resistance will not
output more energy that was
totally input from all sources,
but it will output more energy than was input
by the operator
alone and paid for by him.
What
is usually unknown by engineers (and even many scientists) is that
the conventional strangled electrodynamics model so widely accepted has
serious errors, such as assuming (1) a flat
spacetime in which the circuit is embedded, and (2) an inert vacuum in
which the circuit is embedded. In
this seriously flawed 1880s/1890s EE model, then, there is
no energetic interaction
at all between the circuit and
its local active vacuum/spacetime. The model simply does not include such
an interaction because it assumes an inert vacuum. Most skeptics also do
not realize that, since all EM
fields and potentials and their observable EM energy are produced by their
associated charges, and those
charges have no observable energy input even though they have an
observable energy output, the present CEM/EE model – and the skeptics who
embrace it – is an unintentional advocate
of creating energy from nothing
, in total violation
of the conservation of energy
law!
Indeed –
and here’s one to stretch one’s imagination!
– it can even be argued (and it has been authoritatively
stated!) that
in general relativity there
also is no absolute
conservation of energy law!
While this aspect is not encountered unless appreciable spacetime curvature
exists, it nonetheless seems valid for sufficiently powerful GR effects.
This peculiarity of general relativity
was first noticed by the great
Hilbert, not long after Einstein advanced the general theory of relativity.
E.g., quoting Hilbert:
"I assert... that for the
general theory of relativity,
i.e., in the case of general invariance of the Hamiltonian function,
energy equations...
corresponding to the energy equations
in orthogonally invariant theories do not exist
at all. I could even take this
circumstance as the characteristic feature
of the general theory of relativity."
[D. Hilbert,
Gottingen Nachrichten,
Vol. 4, 1917, p. 21.].
Quoting
Logunov and Loskutov:
"In formulating the equivalence
principle, Einstein actually abandoned the idea of the gravitational
field as a Faraday-Maxwell field, and this is reflected in the
pseudotensorial characterization
of the gravitational field that
he introduced. Hilbert was the first to draw
attention to the consequences
of this. … Unfortunately, …
Hilbert was evidently not understood by his contemporaries, since neither
Einstein himself nor other physicists recognized the fact that
in general relativity conservation
laws for energy, momentum, and angular momentum are in principle
impossible."
[Logunov
and Loskutov, "Nonuniqueness of the predictions of the general theory of
relativity," Sov. J. Part.
Nucl., 18(3), May-June 1987, p. 179.].
Penrose
gives a good discussion on the situation
vis a vis general relativity
versus the conservation of
energy law. Quoting Penrose:
“We seem to have lost those most crucial conservation
laws of physics, the laws of conservation
of energy and momentum!”
[Penrose
then adds the Killing symmetry arbitrarily, to get conservation
again, whenever the Killing vector applies and gravity is separated.].
“These conservation laws hold
only in a spacetime for which there is the appropriate
symmetry, given by the Killing vector
ĸ….
[These considerations] do not
really help us in understanding what
the fate of the conservation
laws will be when gravity itself becomes an active player. We still have
not regained our missing conservation
laws of energy and momentum, when gravity enters the picture. ... This
awkward-seeming fact has, since the early days of general relativity,
evoked some of the strongest objections to that
theory, and reasons for unease with it, as expressed by numerous
physicists over the years. … in fact Einstein’s theory takes account of
energy-momentum conservation in
a rather sophisticated
way –
at least in those circumstances
where such a conservation law
is most needed. …Whatever
energy there is in the gravitational
field itself is to be excluded from having any representation…”
[Roger Penrose, The Road to Reality, Alfred A. Knopf,
New York, 2005, p. 457-458.]
So as can
be seen, the “solution” accepted by many general relativists
is to just arbitrarily toss out the gravity and gravitational
energy density of spacetime in a given troublesome case, and the problem
of nonconservation of energy
and momentum then vanishes. In short, one must separate
the spacetime itself from the fields, and then the problem is avoided!
However, simply
avoiding the problem itself is
not solving the problem!
Further, considering the neglected and unaccounted giant Heaviside energy
flow always accompanying every Poynting EM energy flow, and dramatically
increasing the local energy density because of that
flow, the gravity effect is always
at least of importance. So in
general the Killing vector “solution” is nearly always untenable, and thus
is unsatisfactory.
I
personally prefer to just leave that
unresolved argument to the general relativists!
As might be suspected, that
aspect of the GR theory is seldom mentioned and is little-known. And for
most normal situations and
practical purposes, energy is (or may be considered to be) essentially
conserved. But it is also true that
in GR such things as energy, momentum, and angular momentum are
relative,
and not absolute
at all. Even an actual physical
event is relative. To one
observer, an event (such as the violent death
of an individual) can already have happened, whereas to another observer
in another frame it has not yet happened
at all.
Each observer is correct relative
to his own individual frame, but neither sees or
experiences anything “absolute” in the general sense.
Energetic
spacetime also presents some very peculiar
capabilities. E.g., if
spacetime in a given region is curved and/or twisted in a certain way, a
continuous “outflow” of energy occurs from that
region outward to surrounding regions, as a dynamic constituent of that
peculiar curvature/torsion. The
energy outflow will freely continue so long as the curvature/torsion
of that “distorted ST region”
is not reversed or does not “decay”, and the decay time can be quite long.
So a “static” curved spacetime
source can furnish a real energy flow for an indefinite time, even as long
as the universe persists. We may, of course, extend the GR model itself to
include an active vacuum, in which case the conservation
law can be restored by accepting that
the continuous energy outflow means that
the energy is extracted from the seething virtual state
vacuum (seething curved/twisted dynamic spacetime). The source charge,
e.g., can be taken as one concrete example of such a source, involving
just such a region of sharply curved and twisted vacuum/spacetime, in the
extremely small region of the source charge particle itself. On the other
hand, that is also an extension
to the “normal” conservation of
energy law, by considering an additional source for the energy input.
So as an
engineer, I personally prefer to maintain the long-trusted and demonstrated
(at least in a single
well-behaved frame!) conservation
of energy law by an extension of it to consider both virtual state
active vacuum and observable energy flow through space, associated
with any source charge (or dipolarity). In modern physics, the so-called
classical “isolated charge” is
not isolated
at all, but polarizes its
surrounding space/vacuum with a virtual charge of opposite sign. So any
observable charge is part of a
source dipole ensemble a priori. Further, each of the two
charges is considered infinite, and each also has infinite energy. It is
just that
the two infinite quantities mathematically
have a finite difference, which is what
our classical instruments observe and detect! E.g., quoting Nobelist
Weinberg:
"[The total energy of the
atom] depends on the bare mass
and bare charge of the electron, the mass and charge that
appear in the equations of the
theory before we start worrying about photon emissions and reabsorptions.
But free electrons as well as electrons in
atoms are always emitting and
reabsorbing photons that affect
the electron's mass and electric charge, and so the bare mass and charge
are not the same as the measured electron mass and charge that
are listed in tables of elementary particles. In fact, in order to account
for the observed values (which of course are finite) of the mass and
charge of the electron, the bare mass and charge must themselves be
infinite. The total energy of the
atom is thus the sum of two
terms, both infinite: the bare energy that
is infinite because it depends on the infinite bare mass and charge, and
the energy shift … that is
infinite because it receives contributions from virtual photons of
unlimited energy."
[Steven
Weinberg, Dreams of a Final Theory, Vintage Books,
Random House, 1993, p. 109-110.].
Suddenly we
see there are serious problems (flaws) in some of the basic assumptions
and definitions of thermodynamics. In thermodynamics, a “closed” system is
defined as a system wherein mass flow does not cross its boundaries. But
energy flow across its boundaries is permitted. Well, today we know that
energy and mass are the same thing. If mass is prohibited from crossing
the system boundary, that is a
form of energy that is not
restricted from crossing the boundary. Also, an “isolated”
system is defined as one in which neither energy nor mass crosses the
system boundaries. Well, there exists no such system in the entire
universe. Every electric charge and magnetic pole in every system is in a
continual seething exchange of virtual energy and virtual mass with its
local and surrounding vacuum. So suddenly that
“definition” bites the dust.
There are
thus quite a few things in thermodynamics – particularly the “old”
equilibrium thermodynamics – that
have been falsified and thus require that
the fundamental model be changed.
And
finally, thermodynamics presently really doesn’t deal with negative
energy. Yet the universe is teeming with it. So the present
thermodynamics models still do not adequately
“fit” the phenomenology we actually observe in the universe.
It is well
for the engineer to remember that
scientifically we actually know
nothing absolutely! All we have are our models, and what
the model predicts or the models predict is all we can know
scientifically. Really good scientists are quite aware of this. E.g.,
quoting Hawking:
"All we ever know is our models, but never the reality that
may or may not exist behind the models and casts its shadow upon us who
are embedded inside it. We imagine and intuit, then point the finger and
wait to see which suspect for truth turns and runs. Our models may get
closer and closer, but we will never reach direct perception of reality's
thing-in-itself."
[As given
by George Zebrowski, "The holdouts," Nature,
Vol. 408, 14 Dec 2000, p. 775,]
Or as put
very bluntly by Silverman for charge itself:
"The theory of quantum electrodynamics provides a comprehensive and (as
far as experiment has been able to confirm) correct description of the
interaction of charged matter
with electromagnetic fields. And yet, curiously enough, we do not know
exactly what charge is, only what
it does. Or, equally significantly, what
it does not do."
[M. P. Silverman, And Yet It Moves: Strange Systems and Subtle
Questions in Physics,
Cambridge
University Press,
Cambridge, 1993. p. 127].
This is
also true of energy. E.g., quoting Nobelist Feynman:
"It is important to realize that
in physics today, we have no knowledge of what
energy is."
[Richard P. Feynman, Robert B. Leighton, and Matthew
Sands, The Feynman Lectures on Physics, Addison-Wesley, Reading,
MA, Vol. 1, 1964, p. 4-2].
And the “EM
force fields in space” that we
study in classical electromagnetics and electrical engineering, also do
not exist. There are no forces or force-free fields in space, but only in
matter. So there are no
electromagnetic force fields in space, but only in charged matter.
Nobelist Feynman pointed this out in his three volumes of sophomore
physics in 1964. Quoting Feynman:
"…the existence of the positive charge, in some sense, distorts, or creates
a "condition" in space, so that
when we put the negative charge
in, it feels a force. This potentiality for producing a force is
called an electric field."
[Richard P. Feynman, Robert B. Leighton, and Matthew
Sands, The Feynman Lectures on Physics, Addison-Wesley, Reading,
MA, Vol. 1, 1964, p. 2-4].
"We may think of E(x, y, z, t) and B(x, y, z, t) as giving the forces that
would be experienced
at the time t by a charge located
at (x, y, z), with the
condition that placing the
charge there did not disturb the positions or motion of all
the other charges responsible for the fields."
[ibid, vol. II, p. 1-3.]
Further,
Lorentz’s symmetrization of
Heaviside’s severely truncated
version of Maxwell’s theory also simply tossed out all asymmetrical
Maxwellian systems, and retained only symmetrical systems. This includes
all systems that receive and
use virtual state energy from
the vacuum, and it includes the source charge, the electrical dipole, and
magnetic dipole. All exhibit broken symmetry, as predicted by Lee and Yang
and proved by Wu et al. in 1957.
The dipole
(opposite charges) must
exhibit broken symmetry, because that
has been experimentally proved by Wu and her colleagues shortly after such
was predicted by Lee and Yang. Further, broken symmetry means that
“something virtual has become observable.” Quoting Nobelist Lee:
“…the violation of symmetry
arises whenever what was
thought to be a non-observable turns out to be actually an observable.”
[T. D. Lee,
Particle Physics and Introduction to Field Theory, Harwood Academy
Publishers, Chur, New York, and London, 1981, p. 181.].
In particle
physics, of course the virtual state
vacuum/spacetime is already considered extremely energetic and active, and
of course there are
interactions ongoing between any circuit (particularly its charges) and
the local active vacuum/spacetime. E.g., for a few quotations:
"…curved empty space is a dynamic entity, as competent to store and carry
energy as are ordinary elastic materials
and electromagnetic waves."
[John A. Wheeler and
Seymour Tilson, "The Dynamics
of Space-Time," International
Science and Technology, Dec. 1963, p. 62.]
"The electromagnetic field distorts space by creating
regions of greater density of
energy and stress … where lines of force are more closely spaced. But
energy implies mass; and mass is the source of a gravitational
field which, in relativity, is
identical with a curvature of
space. So, in essence, the curvature
in space created by the
electromagnetic field is the electromagnetic field; and this curvature
can in principle be detected by purely geometric measurements."
[John A. Wheeler and
Seymour Tilson, "The Dynamics
of Space-Time," International
Science and Technology, Dec. 1963, p. 72.].
"...the concept of a 'single particle' actually breaks down in relativistic
quantum field theory with interactions, because the interactions between
'the particle' and the vacuum fluctuations
(or virtual quanta) cannot be ignored."
[I. J. R. Aitchison, "Nothing's Plenty: The Vacuum in Modern
Quantum Field Theory," Contemporary Physics, 26(4), 1985, p. 357.].
In the
modern thermodynamics of nonequilibrium steady state
(NESS) systems there are already known
areas recognized to allow violation
of the old second law of equilibrium thermodynamics (the older stuff that
contains also some errors). To see a list of some of these areas, see
Dilip Kondepudi and Ilya Prigogine, Modern Thermodynamics: From Heat
Engines to Dissipative
Structures, Wiley,
New York, 1998, reprinted
with corrections 1999. Areas known to violate
the old second law of equilibrium thermodynamics are given on p. 459. One
area is strong gradients
(as used in the MEG and many other systems such as Bedini’s battery-charging
processes) and another is memory of
materials (as
used in the MEG in the nanocrystalline core materials
and layered crystalline structures to invoke the Aharonov-Bohm effect). We
strongly comment that these
known, recognized mechanisms allow macroscopic and significant violations
of the Second Law that are
directly usable in real systems and circuits.
When one
“potentializes a circuit”, one actually first
changes the energy density of the local
vacuum, or – more exactly – one actually changes the master
potential (total energy density) of that
vacuum energy. So one changes and potentializes (excites)
the energetic local vacuum
itself, so that it now
contains extra energy and activity. The ongoing seething interactions
between the now-excited local vacuum and each charge in the “potentialized
circuit” are thus directly increased by this excitation
of the local vacuum’s activity. The potentialization
of the actual charges is just a cover story hiding the increased energetic
exchange between the local vacuum and those charges in the circuit. The
“potentialization of the
circuit” is an effect that is
generated by the primary
“potentialization/excitation”
of the local active vacuum/spacetime.
And that
is the vacuum engineering process
that is actually done and used
when one simply adds voltage to a
circuit to “potentialize the circuit”. Potentializing a
circuit or system is – to the system – a negative
entropy operation, because it
moves the system farther away from equilibrium (maximum entropy condition)
and thus lowers its entropy. If we refer to the dissipation
of usable potential energy from a circuit or system as “production of
positive entropy in that
system”, then algebraically we must refer to the addition of usable
potential energy to that
circuit or system as “production of
negative
entropy in that system”.
Note the
following:
A circuit
is said to produce or involve production of positive entropy, when it
dissipates
some or all of its usable potential energy.
Thus, a
circuit must be said to experience or involve production of negative
entropy, when it receives or absorbs (gains)
additional usable potential energy.
Depotentialization involves
positive entropy production.
Potentialization
involves negative entropy
production.
Both
involve an interaction between the local vacuum and the charges in the
circuit or system.
For a given
set of charges in a given circuit or system, the EM energy is added by
potentialization (excitation),
and dissipated by depotentialization
(de-excitation). Once we accept
depotentialization as involving
a positive entropy operation,
then we must algebraically accept potentialization
as involving a negative entropy
operation. Oddly, the first is
accepted in the teaching of thermodynamics, but usually the second is not
accepted.
The statements
hold without any change in the magnitude of charge. E.g., quoting Shrader:
"A source of electric energy does not increase the number of free
electrons in a circuit; it merely produces a concerted pressure on any
aimlessly moving electrons."
[Robert L. Shrader, Electronic Communication,
Sixth Edn., MacMillan/McGraw-Hill,
New York,
NY, 1991, 1993 Imprint, p.
6.].
In other words, lowering the entropy of a system (a negative
entropy operation of/on the
system) is marked by an increase of the pressure or force on the Drude
electron gas, and increasing the entropy of a system (a positive entropy
operation of/on the system) is
marked by a decrease of the pressure of force on the Drude electron gas.
In the negative entropy operation,
usable potential energy flows into the local vacuum, and increases the
energetic exchange between charge and vacuum. In the positive entropy operation,
potential energy flows away from the local vacuum, lowering the local
vacuum’s energetic exchange between charge and vacuum.
Once the
local vacuum is potentialized (excited), it will freely alter its ongoing
interaction with the local charges to give them extra energy and power
(extra “pressure”), and it will continue to do so indefinitely – including
freely giving energy to additional charges brought into the exchange
region – unless a depotentializing operation
is subsequently done to reduce the excess potential energy of that
local vacuum back to its quiescent state.
But that is the operation
of an asymmetrical
Maxwellian system a priori. Unfortunately,
in 1892 Lorentz arbitrarily symmetrized the Heaviside equations
and arbitrarily discarded all
asymmetrical Maxwellian systems, just to get simpler equations
easier to solve. Hence he arbitrarily discarded from the model any ability
to accurately describe all
those Maxwellian systems where the (1) local interacting vacuum is
potentialized, (2) the altered local vacuum is freely furnishing or creating
excess energy (or “pressure”) to and on the circuit charges, and (3) the
circuit is then using some of that
excess free energy-from-the-vacuum interaction to power its loads,
at least partly “for free” with
excess energy that the operator
did not have to pay for. Instead, the Lorentz-symmetrized equations
now allow or prescribe only a “symmetrical” circuit with equal and
opposite forward and back emf (electrical circuit) or with equal and
opposite forward and back mmf (magnetic circuit).
Since all
our EEs are still taught only
symmetrical circuit design and circuits, they only build
circuits which deliberately
depotentialize their local active vacuum so as to deny any practical
circuit use of the interaction of that
former potentialization of that
local vacuum environment. For a system to exhibit practical use of the
circuit’s ubiquitous interaction with the vacuum so as to freely power
loads, it must be an asymmetrical Maxwellian system
a priori – the very kind
of permissible Maxwellian system that
Lorentz arbitrarily discarded from the EE model and that
all modern electrical power engineers still blindly discard.
Such
asymmetrical Maxwellian systems freely taking and using excess EM energy
from the local excited vacuum interaction are not prohibited by nature,
but only by arbitrary symmetrization
of the Heaviside equations – by
Lorentz and by all our electrical engineering departments, professors, and
textbooks.
So the true
negative resistor, where the
circuit is deliberately made
asymmetrical so that one part
of it can in fact freely receive use some of that
available excess energy from its potentialized vacuum, has been
arbitrarily though unwittingly eliminated
from electrical engineering since Lorentz’s symmetrization
of the Heaviside equations in
1892.
The
fundamental charge and dipole are in fact true negative
resistors.
Nevertheless, from time to time various inventors do stumble onto an
asymmetrical Maxwellian circuit so arranged that
a true “negative resistance”
results. In that case, excess
energy is received by the asymmetry from the seething virtual state
vacuum and then used to help power the loads, rather
than the excess energy being input and paid for by the operator.
Encouragingly, modern theorists and experimenters are beginning to close
in once again on such asymmetric circuits and their engineering of the
vacuum itself, and thereby circuits that
are getting extra usable energy from the vacuum. Chung’s negative
resistor is one such development. We will mention another shortly
(Solomon’s work).
In
conventional CEM/EE theory, there are grave experimental anomalies that
either destroy the conservation
of energy law entirely, or require that
all EM energy – in all fields and potentials – comes from the vacuum
anyway, via that interaction
between the potentialized local vacuum and the charges.
(a)
First, there is the
source charge problem – how an ordinary charge just sits
there and continuously pours out real, observable, measurable, and usable
EM energy in all directions – while there is no
observable energy input
detectable by any known instrument. Either the outpouring of usable EM
energy has to be obtained from the virtual vacuum, or else the charge
freely creates all its output
energy, and its associated EM
fields and their energy, from nothing
at all. In the latter
case, that would destroy the
energy conservation law and all
of physics and thermodynamics along with it. So the source charge problem
has been expunged from all the texts and EE curricula.
(b)
Another grave anomaly is the fact that
simply laying a charged capacitor on a permanent magnet, so that
the E-field of the capacitor and the H-field of the magnet are
at an angle – produces a true,
certified “free energy machine” that
steadily and continuously pours out real EM Poynting energy, without any
further energy input by the operator.
Again, either the energy steadily flowing is extracted from the local
vacuum via the source dipolarities and their broken symmetry, or else the
contraption is freely creating
energy out of nothing
at all. Again, this would
destroy the conservation of
energy law, and physics and thermodynamics along with it. E X H = S is a
standard formula for S, the Poynting energy flow, and E and H may indeed
be “static” fields.
Quoting Buchwald on the latter
situation:
"[Poynting's result] implies that
a charged capacitor in a constant magnetic field which is not parallel to
the electric field is the seat
of energy flows even though all macroscopic phenomena are static."
[Jed Z. Buchwald, From Maxwell to Microphysics, University of
Chicago Press,
Chicago and
London, 1985, p. 44].
For the
reader’s clarity, we point out that
a magnetic “pole” is actually a magnetic
charge.
Anyway,
merely crossing the so-called “static”
magnetic field of a magnetic dipole with the “static”
electric field of an electric dipole produces an absolutely legitimate
free energy device which continually receives virtual state
energy from the seething vacuum interaction and steadily pours out real,
measurable photons in a steady Poynting energy flow stream
at light speed in all
directions. In other words, it freely establishes a nonequilibrium steady
state (NESS)
thermodynamic system that
continually absorbs virtual energy from the vacuum, transduces it into
observable energy, and re-emits the energy as a steady and ongoing real EM
energy flow.
And it also
continuously violates the hoary
old second law of equilibrium thermodynamics.
The
so-called “free energy problem” is not a problem in producing real flows
of EM energy from the vacuum! That
is already universally and freely done by every charge and every dipole
(and every crossed E and H field combination)
in the universe! Instead, it is a problem of going back and learning to
build asymmetrical interception and
collection systems, of precisely the type that
Lorentz discarded in 1892, and that
all electrical engineering departments, professors, and texts still
arbitrarily discard. Presently we only build
symmetrical Maxwellian
systems which – when they intercept the free energy flows from the vacuum
that are being provided by the
source dipolarity – deliberately
take half the received and collected free energy and dissipate
that half to do nothing but
destroy the source dipolarity of the generator
by doing work to scatter its
charges. Since a real system has
at least a few losses in its
external circuit, the present
symmetrical EM systems actually kill their own extraction of free EM
energy from the vacuum, faster than they collect and use some of it to
power the loads and losses.
Cranking
the shaft of a generator has
nothing directly to do with the flow of EM energy that
pours out of the generator
terminals and through space outside and along the conductors of the
attached external circuit!
Specifically, the mechanical energy (or part of it)
is not changed in form to
provide the Poynting energy flow pouring from the generator
terminals. That energy flow
comes directly from the virtual energy of the vacuum, extracted and
transduced into observable energy via the dipolarity inside the generator,
once the internal dipolarity of the
generator has been physically
established. For a diagram showing how a generator
actually powers its circuit, and what
cranking the shaft of the generator
actually does, and where the outpoured energy from the generator
terminals comes from, and why it is not self-sustaining in our present
generators and circuits, see T.
E. Bearden, “Engineering the Active Vacuum: On the Asymmetrical
Aharonov-Bohm Effect and Magnetic Vector Potential A vs. Magnetic Field
B.”
Because of
the proven broken symmetry of opposite charges (i.e., of a dipole), any
permanent magnet or charged capacitor (or electret) produces a steady flow
of real EM energy (real photons) from the vacuum, establishing and
continually replenishing its associated
static fields. Any so-called
“static field” is actually such
a steady flow of real energy. The
static EM field is made of
finer parts (photons) in continuous motion, as pointed out
in the beautiful “unfrozen waterfall”
analogy by Van Flandern. Quoting:
“To retain causality, we must distinguish two distinct meanings of the
term ‘static’. One meaning is
unchanging in the sense of no moving parts. The other meaning is sameness
from moment to moment by continual replacement of all moving parts. We can
visualize this difference by thinking of a waterfall.
A frozen waterfall is static
in the first sense, and a flowing waterfall
is static in the second sense.
Both are essentially the same
at every moment, yet the latter
has moving parts capable of transferring momentum, and is made of entities
that propagate.
…So are … fields for a rigid, stationary
source frozen, or are they continually regenerated?
Causality seems to require the latter.”
[Tom Van Flandern, “The speed of gravity – What
the experiments say,” Physics Letters A, Vol. 250, Dec. 21, 1998,
p. 8-9].
Indeed, a
permanent magnet in one’s hand, or a charged capacitor or electret in
one’s hand, constitutes a working, operational
“free energy from the seething vacuum” device, but one which only produces
a rock-steady outflow of photons, continually establishing and
replenishing their “static”
field(s). All “static” EM
fields and potentials are thus “static”
in the sense of being composed of smaller parts in continual motion and
replacement – like an unfrozen waterfall
in the analogy advanced by Van Flandern.
To further
develop the presently restricted old EM theory, encouragingly there are
again leading theorists who are pursuing energy from the vacuum. E.g.,
quoting M. W. Evans:
"…the acceptance of a structured vacuum described by an O(3) gauge group
leads directly to the existence of novel charges and currents in the
vacuum. These are conserved, or Noether, currents and charges and are
clearly topological in origin. They spring from the fact that
the vacuum is a topological space. Four such entities emerge: [1] A
topological vacuum electric charge, also proposed empirically by Lehnert
et al. [2] A topological vacuum electric current, also proposed
empirically by Lehnert et al. [3] A topological vacuum magnetic charge,
proposed also by Barrett and Harmuth. [4] A vacuum topological magnetic
current, proposed also by Barrett and Harmuth.
Each of these four objects can provide energy, which can be
loosely termed 'vacuum energy': energy coming from the topology of the
vacuum."
[Myron W. Evans, "O(3) Electrodynamics," in Modern Nonlinear Optics,
Second Edition, 3 Vols., edited by M.W. Evans, Wiley, New York, 2001, Part
1, p. 84].
We note Bo Lehnert is an important scientist in the
Swiss
Academy, while
Harmuth and Barrett are pioneers of modern ultrawideband radar, which was
considered impossible and viciously opposed when first proposed.
Rigorous
proof that eliminating
the arbitrary Lorentz condition provides EM systems having free additional
energy currents from the vacuum is given by M. W. Evans et al., “Classical
Electrodynamics without the Lorentz Condition: Extracting Energy from the
Vacuum,” Physica Scripta, Vol. 61, 2000, p. 513-517.
Evans, of
course, has now successfully developed what
appears to be the first highly successful unified field theory – the
Einstein-Cartan-Evans theory – and it may prove to be one of the most
exciting developments in physics.
For
rigorous theoretical proof that
real physical systems are allowed to produce continuous negative
entropy, in violation of the
old second law of equilibrium thermodynamics, see D. J. Evans and Lamberto
Rondoni, "Comments on the Entropy of Nonequilibrium Steady States,"
J. Stat. Phys.,
109(3-4), Nov. 2002, p. 895-920.
We nominated
the source charge and dipole as concrete examples of real physical systems
that do exhibit such violation.
Indeed,
Maxwell himself (he was also a thermodynamicist of note) was fully aware
more than a century ago that
the smaller parts of real macroscopic systems do in fact continually and
appreciably violate the hoary
old second law anyway. Quoting Maxwell:
"The truth of the second law is … a statistical,
not a mathematical,
truth, for it depends on the fact that
the bodies we deal with consist of millions of molecules… Hence the second
law of thermodynamics is continually being violated,
and that to a considerable
extent, in any sufficiently small group of molecules belonging to a real
body."
[J. C. Maxwell, “Tait's Thermodynamics II,” Nature
17, 278–280 (7 February
1878)].
See also G.
M. Wang, E. M. Sevick, Emil Mittag, Debra J. Searles, and Denis J. Evans,
"Experimental Demonstration of
Violations of the Second Law of
Thermodynamics for Small Systems and Short Time Scales," Phys. Rev.
Lett., 89(5), 29 July 2002, 050601.
This paper experimentally demonstrated
the operation of the integrated
transient fluctuation theorem,
which predicts appreciable and measurable violations
of the second law of thermodynamics for small systems over short time
scales. Entropy consumption (production of negative
entropy) is experimentally shown to occur over colloidal length and time
scales, for up to two seconds and
at micron size scales.
A simple
field gradient (e.g., a gradient of the energy density across a vacuum
region) can in fact cause the excited vacuum to steadily emit extra
energy, as it does in and from a charged capacitor or electret, or in and
from a permanent magnet. After all, a dipole in one sense involves a
change in energy density of spacetime, between one pole (charge) and the
other.
A true negative
resistor also often involves negative
energy rather than positive
energy. Again, a sharp field gradient across a small region of space will
generate “anomalies”.
Specifically, a sudden field gradient will generate
a surge of extra electrons lifted directly from the local Dirac sea vacuum
itself, giving a sudden momentary surge of ordinary electrons (often
called the “Lenz law” current). At the same time, the remaining but
unaccounted Dirac sea holes – from which the electrons were suddenly
lifted – are negative
mass-energy electrons. As such, they move in the opposite
direction as the positive mass-energy electrons that
were lifted out of the sea.
As a source
charge, a Dirac hole (negative
mass-energy electron) continuously emits
negative-energy
photons, thus establishing and continually replenishing associated
negative
energy EM fields and potentials spreading
at light speed. The negative
mass-energy holes also gravitationally
repel normal mass, and are in turn repelled by it, so the holes tend to
migrate away, particularly from
sharp gradient processes in the sun, planets, etc. The resulting cumulations
of Dirac holes in deeper space is the so-called “dark matter”
the astrophysicists are so avidly seeking. Their associated
negative energy fields are the
“dark energy” also so avidly sought by the astrophysicists. If we develop
the use of Dirac holes (dark matter)
and their negative EM energy
fields (dark energy) in laboratory
equipment, we also can then rapidly develop practical antigravity devices
and systems.
Indeed,
both dark matter and dark
energy can be easily evoked in real “sharply pulsing” EM circuits in the
laboratory, and their strange
phenomenology can be directly studied on the bench. Bedini, e.g., has been
using dark energy (pulses of negative
EM energy) in his patented battery
charging processes for some time now, but refers to it as “radiant energy”
(which was Tesla’s term for the odd energy being seen).
There also
are significant antigravity implications
of resonance in very strong negative
energy regions – such as in the binding energy of the nucleons of a
nucleus. The Sweet device experimentally demonstrated
proof of this fact.
The Sweet
VTA device – a further extension of the great
Gabriel Kron’s negative
resistor developed
at
Stanford
University on a Navy
contract in the 1930s – resulted in an output of almost entirely negative
EM energy. The reason was that
Sweet established self-resonance in the
binding energy of the nucleons
in the barium
atoms in his conditioned barium
ferrite magnets. Since binding energy is
negative
energy (already commonly known and so accepted), and since
the EM fields are extraordinarily powerful
at the short distances between
nucleons in a nucleus, then his device was outputting oscillating
negative energy
at very high gain. The unit had
a COP = 1,500,000 in its 500 watt
version, and this could be increased by simply adding extra load
impedance! One had to be careful in such addition, because evoking too
high a COP would result in direct explosion (like a hand grenade!) of the
barium ferrite magnets. Sweet in fact exploded several such magnets,
fortunately without being
wounded or killed. We will further discuss the Sweet VTA and its
antigravity experiment shortly, after first explaining a bit more about
negative EM energy and its
strange behavior.
We return
to Sweet’s device in a moment, but first digress to discuss the strange
behavior of negative energy EM
energy flows, as compared to the standard positive energy EM energy flows.
Positive
energy EM energy flow is a flow of “naturally
divergent” EM energy. The energy is always trying to diverge out away from
its direction or path of flow,
and escape back to the environment. What
we call “conductivity” is the ability of the path
or conductor to hold that
divergence effort in check along that
conductor or path. So along a
perfect conductor, one will have the same amount of positive energy flow
out of a conducting section, as one had going into that
section.
What
we call “impedance” is a priori a
lowering of the conductance. So if the positive energy flow
meets an impedance in its path,
in that impedance the
conductance is lowered, and so in the impedance section the flow is not
totally held in along the line of flow. Hence part of the positive energy
flow will be diverged out of the impedance and away from the intended path,
back to the external environment. Hence the positive energy flow
exiting the impedance and
along the original path of
flow, will be less than the amount of positive energy flow
entering the impedance
region.
Negative
energy EM energy flow is a flow of “naturally
convergent” energy. Excess negative
energy flow is always trying to converge – from the external environment –
into that line or path
or conductor of negative energy
flow. What we call
“conductivity” is – in this case – the ability of the path
or conductor to hold back
that excess environmental negative
energy that is trying to
converge into the flow along the path
and thus enlarge that flow. In
a perfect conductor or path, that
“holding back” the excess convergent negative
energy is 100% successful. So from any section of a 100% conductive path,
the negative energy flow
exiting that
section along the original line of flow will be equal to the negative
energy flow entering
that section along the path.
But when
the negative energy flow path
contains an impedance, that
impedance again is a “reduction” in the normal holding action of the
conductive path. Hence for a
negative energy flow, in that
“standard impedance” region the “hold-back the extra in-converging action”
is reduced. So excess negative
energy flow-in from the external environment will be
added to the original negative
energy flow through that
impedance region. Hence the negative
energy flow exiting
the impedance section along the original flow path
and direction, will be greater
than the negative energy flow
entering the
impedance section along the original flow path
and direction. In short, the ordinary impedance (of an ordinary
resistance, capacitance, or inductance) will act as a “true negative
impedance”, with an automatic
gain in the throughput of negative
energy across it. The excess negative
energy of course is furnished freely by the surrounding vacuum
environment.
And that
action produces a “true negative
resistor”. Actually the impedance (e.g., a resistor) is totally normal; it
is the particular type of EM energy flow – along with its fundamentally
particular behavior – that has
changed.
With
positive energy flow,
impedance “feeds energy away from the path
and back to the active environment”, decreasing the flow of positive
energy proceeding further in the circuits. This is known and evidenced as
“losses” in the energy flow of the operating
system, or just “system losses” for short.
With
negative
energy flow, impedance “feeds excess energy flow from the active
environment into the ongoing flow”, increasing the flow of negative
energy occurring in the circuit. This is known and evidenced as “free
gains” in the energy flow of the system.
If one
charges a battery, e.g., using
negative energy – as in Bedini
processes – one sends iterative
negative energy pulses to the battery,
with the battery seemingly
connected “backwards”. The charging process cares not whether it receives
positive energy from one direction, or negative
energy from the other direction. If it receives positive energy, some of
the input energy is lost back to the environment due to the impedance of
the battery, and so the COP
<1.0 of the charging process. On the other hand, if it receives negative
energy, some excess negative
energy will also be gained directly from the local vacuum environment, due
to the same battery impedance.
Hence the overall COP>1.0 for the negative
energy charging process.
This is a
true “overunity” COP process used routinely by Bedini for years. It gives
him a very good COP>1.0 battery
charging process, where COP = 3.0 to 8.0 is readily achieved once one has
worked out the control and use procedures for using negative
energy.
And here is
what almost seems to be “sheer
magic”. Note that “negative
resistors” in the sense spoken of here, for real negative
energy flow, can be serially “staged”. Ten stages of such serial negative
resistors, each with gain 10, will result in an overall gain of 10
billion! All the enormous extra energy has been freely received from the
seething active external vacuum environment.
To change
negative energy back into
positive energy is also straightforward. Simply charge a capacitor
(reversed) with negative
energy. Then switch away the capacitor and switch it into another circuit,
connected normally. The capacitor will now discharge ordinary positive
energy in that second circuit,
in quite ordinary fashion.
Indeed,
some conventional but forward-looking scientists and engineers
at various universities are now
experimenting with negative
energy EM energy, and they are getting and reporting solid results.
E.g.,
see Dan Solomon, "Some new results concerning the vacuum in Dirac’s hole
theory," Physica Scripta, Vol. 74, 2006, p. 117–122.
Abstract: “In Dirac’s hole theory
(HT), the vacuum state is
generally believed to be the state
of minimum energy. It will be shown that
this is not, in fact, the case and that
there must exist states in HT
with less energy than the vacuum state.
It will be shown that energy
can be extracted from the HT vacuum state
through application of an
electric field.”
Our comment
is that adding a field (e.g., a
gradient of a potential) across a region of space is a violation
of Lorentz symmetry, since the “uniformity” and thus the symmetry of the
vacuum energy density is directly altered in that
region. Also, one should note the importance of Physica Scripta,
which is the journal produced by the
Royal
Swedish
Academy of Sciences
– which awards Nobel Prizes. Solomon references work in this area,
performed by himself and several other researchers for some time (since
1999). Quoting Solomon (clearly showing the involvement of negative
energy):
“In Dirac’s hole theory (HT), the
vacuum state is generally
believed to be the state of
minimum energy. …this is not, in fact, the case and states
[exist in HT] with less energy than the vacuum state.
…energy can be extracted from the HT [hole theory] vacuum state
through application of an
electric field.”
If this
group continues and grasps the fact that
the Dirac holes are the astrophysical “dark matter”,
and their resulting negative
energy fields are the astrophysical “dark energy”, they will have solved
the problem of dark matter and
dark energy, etc., and will likely be given the Nobel award.
To show
additional importance of negative
energy EM energy work, we return to the Sweet device – a derivative
and extension of Kron’s true negative
resistor
at
Stanford
University in the
1930s. Since Dirac holes (negative
mass-energy electrons) are produced, and since they produce antigravity rather
than gravity, it meant that the
Sweet device could be used to examine actual practical antigravity. By
much back-of-the-envelope calculation,
estimating, and guessing, I
designed an extension to the Sweet unit that
should produce measurable and testable antigravity but remain safe in the
laboratory and not explode
Sweet’s barium ferrite magnets. I convinced Sweet to build the extension –
which was basically an additional load impedance, which could be switched
in 100 watts
at a time for five additional
steps. He then performed the antigravitational
experiment in
California, reading the results on the
phone to me (I was here in
Huntsville,
Alabama). As he switched in
each 100 watts, Sweet
meticulously measured the weight of the VTA itself on the bench and
reported that weight. The unit
steadily and smoothly lost 90% of its weight on the laboratory
bench. This had met the purpose of the experiment. I prepared a paper for
a symposium, which among other things showed a graph of the actual results
of that experiment. I put
Sweet’s name first on the paper since he was the actual inventor, not me.
The paper is Floyd Sweet and T. E. Bearden, "Utilizing Scalar
Electromagnetics to Tap Vacuum Energy," Proc. 26th Intersociety Energy
Conversion Engineering Conference (IECEC '91),
Boston,
Massachusetts, 1991, p.
370-375.
Shortly
afterwards, a very professional
attempt was made on Sweet’s
life, although by a sheer quirk of fate
he survived. He was continually called
at all hours of the night and
his life threatened. He was
accosted in the supermarket etc., and also repeatedly
threatened in broad daylight.
Sweet was quite feeble, and this so frightened him that
he refused to try to do anything further with the antigravity unit, in
fear for his life. But before he died, he told me that
he also (later that
same day of the original experiment) pushed the unit even more, to 1500 watts
instead of the 1,000 watts of
my designed experiment, with the unit tethered by a cord to a bedpost in
his apartment. According to Sweet, the unit levitated
to the end of the cord and tugged tightly upward on it. He put another
cord on one side, so he could tilt that
side up and down. By tilting that
side down, the unit would fly around in a circle on the tether cord.
Tilting the side up, the unit would reverse and fly around in a circle in
the other direction.
So one of
the things that also comes out
of true EM negative energy
experiments and research
at high gain is the development
and usage of practical antigravity. Since “dissipated”
negative energy is cooling rather
than heating, the use of negative
energy for electrical power would also greatly
decrease the present electric power production’s contributions to global
warming. Because amplification
of the COP is so easy (merely increase the load impedance, and the
environment automatically
inserts more negative energy,
freely!), it means that
eventually a power supply for New York City could be a simple flashlight battery
(or electret, or charged capacitor) powering a very small negative
energy generator, whose negative
energy flow output was directed along a conducting path
(transmission line) having a series of impedances. Development and use of
negative energy systems will
also usher in the entire age of “decentralized” electrical power systems.
In summary,
not only do we need to unleash our sharp young doctoral candidates
and post doctoral scientists on correcting the sadly flawed old CEM/EE
model, but we also should unleash them on developing and applying negative
resistors and particularly the use of negative
EM energy in real circuits and systems.
What
is so desperately needed is for
the scientific community to dramatically
increase funding efforts in negative
energy such as that by Solomon
and his colleagues, and insist that
the present flawed electrical engineering and equilibrium thermodynamics
models be corrected and upgraded. If that
is done, it will truly usher in the real science of the 21st
century very quickly.
We need to
always follow Einstein’s poignant admonition:
"...the scientist makes use of a whole arsenal of concepts which he
imbibed practically with his mother's milk; and seldom if ever is he aware
of the eternally problematic
character of his concepts. He uses this conceptual material,
or, speaking more exactly, these conceptual tools of thought, as something
obviously, immutably given; something having an objective value of truth
which is hardly even, and in any case not seriously, to be doubted. ...in
the interests of science it is necessary over and over again to engage in
the critique of these fundamental concepts, in order that
we may not unconsciously be ruled by them."
[Albert Einstein, "Foreword," in Max Jammer, Concepts of Space: The
History of Theories of Space in Physics, Harvard University Press,
Cambridge,
Massachusetts, 1969, p.
xi-xii.]
Very best
wishes,
Tom Bearden
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