irving Dardik, et al. -- Superwave Cold Fusion

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**Irving DARDIK*, et al.***

**Super Wave Cold Fusion**

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![](pulselcl1.jpg)

[**http://www.energeticstechnologies.com/**](http://www.energeticstechnologies.com/)

**For more information, please contact:**

**Energetics Technologies LLC**   
**Office: (856) 983-5050**   
**Fax: (856) 983-5539**   
**info@superwavefusion.com**

**All media requests please contact:**

**Rick Kramer Media LLC**   
**Office - (856) 810-0303**   
**info@rickkramermedia.com**

**The SuperWave Fusion Process**

SuperWave Fusion is an excess-heat producing reaction created
by a SuperWave-induced interaction of palladium and deuterium.
Click on the video to view an animation depicting how this
process is believed to work.

This energy producing interaction is driven by a complex,
nested, waves-waving-within-waves signal discovered by the
companys Chief Visionary Officer, Dr. Irving Dardik. In the
current apparatus, this proprietary SuperWave signal is
delivered via an electric current to a custom module containing
a palladium cathode and D2O (deuterium instead of hydrogen in
the water molecule). The end result is the release of energy as
the deuterium atoms disassociate from the heavy water and load
into the palladium lattice, allowing their wave-based energy
structures to interact. The principal outputs from this
interaction are heat and apparently small quantities of 4He, a
non-radioactive isotope of Helium. Research to verify the 4He is
currently underway.

Energetics Technologies SuperWave Fusion has the potential
to:

\* Provide an inexpensive, inexhaustible fuel source   
\* Produce no significantly measurable hazardous by-products   
\* Revolutionize the concept of energy production   
\* Be a groundbreaking Green Energy source

Energetics Technologies proprietary SuperWave Fusion has
already demonstrated the production of extraordinary amounts of
excess heat. The SuperWave driven cells have generated OVER 25
times (2,500%) the amount of energy that was used to operate the
system.

![](superwavecell.jpg)

**SuperWave Fusion Electrolytic Cell combined with Ultra
Sound Excitation**

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**PUBLICATIONS**

**On Cold Fusion:**

Energetics Technologies paper as presented in 2008 at ICCF-14,
the International Conference on Condensed Matter Nuclear
Science.   
http://superwavefusion.com/pdf/Energetics\_ICCF-14\_paper.pdf

Energetics Technologies paper as presented in 2005 at ICCF-11,
the International Conference on Condensed Matter Nuclear
Science.   
http://superwavefusion.com/pdf/Energetics\_ICCF-11\_paper.pdf

Dardik, I., Banover, H., El-Boher, A., Gazit, D., Golbreich,
E., Greenspan, E., et al. Intensificationof low energy nuclear
reactions using Superwave Excitation.Tenth International
Conference on Cold Fusion, Cambridge MA, 24-29 August, 2003.
World Scientific Publishing Co., pp. 61.

I. Dardik, T. Zilov, H. Branover, A. El-Boher, E. Greenspan, B.
Khachatorov, V. Krakov, S. Lesin and M. Tsirlin, Excess Heat in
Electrolysis Experiments at Energetics Technologies, Proceedings
of the Eleventh International Conference on Cold Fusion,
Marseilles, France, 31 October-4 November 5, 2004. World
Scientific Co., pp. 84.

Dardik, I., Zilov, T., Branover, H., El-Boher, A., Greenspan,
E., Khachaturov, B., Krakov, V., S., L., and Tsirlin, M.,
Progress in electrolysis experiments at Energetics Technologies,
in 12th International Conference on Condensed Matter Nuclear
Science, Yokohama, Japan, 2005.

I. Dardik, T. Zilov, H. Branover, A. El-Boher, E. Greenspan, B.
Khachaturov, V. Krakov, S. Lesin, A.Shapiro and M. Tsirlin,
Report on Electrolysis Experiments at Energetics Technologies,
Proc. of ICCF-13, Sochi, Russia, June 25-July 1, 2007.

M. C. H. McKubre, F. L. Tanzella, I. Dardik, A. El Boher,
T.  Zilov, E. Greenspan, C. Sibilia and V. Violante,
Replication of Condensed Matter Heat Production American
Chemical Society Low Energy Nuclear Reactions Sourcebook, ISBN
978-0-8412-6966-8, August 2008.

I. Dardik, T. Zilov, H. Branover, A. El-Boher, E. Greenspan, B.
Khachaturov, V. Krakov, S. Lesin, A. Shapiro and M. Tsirlin,
Ultrasonically-excited electrolysis Experiments at Energetics
Technologies, Presented at the ICCF-14, Washington, DC, August
2008.

**On SuperWaves**

Dardik, I. (1995). The law of waves and the invalidation of the
scientific method. Cycles Magazine, 45(2), 49-59.   
[**http://www.dardik-institute.org/doc/law\_of\_vawes.pdf**](http://www.dardik-institute.org/doc/law_of_vawes.pdf)

Dardik, I. (1994). The great law of the universe. Cycles
Magazine, 265-277.   
[**http://www.dardik-institute.org/doc/great\_law.pdf**](http://www.dardik-institute.org/doc/great_law.pdf)

Dardik, I. (1989). Superesonant Wavenergy Theory. Self
Published.

Dardik, I. (2005). Superwave Reality. Proceedings of ICCF 11,
Marseilles, France, 18 July 2005.   
**<http://www.dardik-institute.org/doc/superwave_reality.pdf>**

**On Application of SuperWaves in Biological and
Physiological Systems**

Dardik, I., Cadet, P., Zhu, W., Mantione, K., Rymer, M.,
Reisman, S., et al. (2003). Cyclic exercise induces
anti-inflammatory signal molecule increases in the plasma of
Parkinsons patients. Journal of Molecular Medicine, 485-492.   
**<http://www.dardik-institute.org/doc/Cyclic%20Exercise.pdf>**

Goldsmith, R., Bloomfield, D., Hagberg, S., Reisman,  S.,
Benson, H., Mietus, J., et al. (2002). Implementation of a novel
cyclic exercise protocol in healthy women. The American Journal
of Sports Medicine, 4(2), 135-151.

Dardik, I., Stefano, G. B., Prevot, V., & Cadet, P. (2001).
Vascular pulsations stimulating nitric oxide release during
cyclic exercise may benefit health: A molecular approach.
International Journal of Molecular Medicine, 119-129.   
**<http://www.dardik-institute.org/doc/vascular_pulsation.pdf>**

Dardik, I., Reisman, S., & Petrock, A. M. (2001). Total
wavelet entropy analysis of cyclic exercise protocol on heart
rate variability. Department of Biomedical Engineering, New
Jersey Institute of Technology, Newark, NJ.   
**<http://www.dardik-institute.org/doc/Total_wavelet.pdf>**

Dardik, I. (1997). The origin of disease and health, heart
waves: The single solution to heart rate variability and
ischemic preconditioning. Frontier Perspectives, 6(2), 18-31.   
**<http://www.dardik-institute.org/doc/origin_of_deseases.pdf>**

Dardik, I. (1996). The origin of disease and health: Heart
waves, the single solution to heart rate variability and 
ischemic preconditioning. Cycles Magazine,  46(3), 67-77.   
**<http://www.dardik-institute.org/doc/heartwaves.pdf>**

Dardik, I. (1986). Cardiocybernetics: Relaxation through
exercise. Advances: Journal of the Institute for the Advancement
of Health, 3(3), 56-59.

Dardik, I., H. Branover, A. El-Boher, D. Gazit, E. Golbreich,
E. Greenspan . Intensification Of Low Energy Nuclear Reactions
Using Superwave. Excitation.   
**<http://www.lenr-canr.org/acrobat/DardikIintensific.pdf>**

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**Videos**

[**http://www.youtube.com/watch?v=31tw-Auh\_R4**](http://www.youtube.com/watch?v=31tw-Auh_R4)  
[****http://**www.videospider.tv/Videos/Detail/3230084348.aspx**](http://www.videospider.tv/Videos/Detail/3230084348.aspx)

**The Promise of SuperWave Fusion / Dr.
Irving Dardik**

1 min 36 sec - Jan 13, 2009 -   
SuperWave Fusion's Dr. Irving Dardik speaks about The Promise
of SuperWave Fusion.   
Energetics Technologies SuperWave Fusion promises an
excess-heat producing reaction created ... Dardik would seem to
have a fascination for "wave energy", ...

[****http://**www.youtube.com/watch?v=AEFIisVFt3E**](http://www.youtube.com/watch?v=AEFIisVFt3E)

**Cold Fusion and the Superwave Principle /
Dr. Irving Dardik**

Jan 13, 2009 ... SuperWave Fusion's Dr. Irving Dardik speaks
about Cold Fusion and the Superwave Principle.

[****http://**videosift.com/video/SuperWave-Fusion-Cold-Fusion-at-last**](http://videosift.com/video/SuperWave-Fusion-Cold-Fusion-at-last)

**SuperWave Fusion - Cold Fusion at last?**

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[**http://www.amazon.com/Making-Waves-Irving-Superwave-Principle/dp/1594860440**](http://www.amazon.com/Making-Waves-Irving-Superwave-Principle/dp/1594860440)

**Making Waves: Irving Dardik and His
Superwave Principle**

**by**

**Roger Lewin**

The biography of a medical maverick who is challenging
scientific convention with his astounding approach to achieving
and maintaining health Dr. Irving Dardik's radical notions about
how all matter moves in interconnected waves has drawn deep
skepticism from physicists, and his early attempts to put his
theory into practice in the field of health care got him banned
from practicing medicine in the 1990s. But now, after a decade's
worth of rigorous research that seems to support Dardik's
SuperWave theory, scientists at such esteemed institutions as
MIT, Harvard, and Stanford Research International are signing on
with Dardik's team to probe the possibilities. For example,
Dardik's unique approach to physical exercise, based on his
Principle, has achieved some remarkable successes in reversing
symptoms of chronic disease.

About the Author -- ROGER LEWIN is an award-winning science
writer who worked with Richard Leakey on four books, including
Origins and The Sixth Extinction. Lewin's own books include
Complexity: Life at the Edge of Chaos, Bones of Contention, and
In the Age of Mankind. He lives in Cambridge, Massachusetts.

# Hardcover: 256 pages   
# Publisher: Rodale Books (September 29, 2005)   
# ISBN-10: 1594860440   
# ISBN-13: 978-1594860447

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**EP1656678**   
**PULSED LOW ENERGY NUCLEAR REACTION POWER
GENERATORS**

Also published as:  WO2005017918   
Inventor:  DARDIK IRVING [US] ; LESIN SHAUL   
2006-05-17

**Abstract** -- A low energy nuclear reaction power
generator has different cells in which hydrogenous atoms are
driven by different methods to increase atom-packing in a
lattice and to increase the flux of hydrogenous atoms. An
electrolytic cell is provided containing an
electrically-conductive electrolyte, a glow discharge cell and a
catalyst cell are each provided containing a gas, and a high
pressure electrolytic ultrasonic cell is provided including a
first section containing a gas and a second section containing
an electrolyte, in which is provided an anode-cathode electrode
pair. Applied across these electrodes is a train of electrical
packets, each comprised of a cluster of pulses.; The amplitude
and duration of each pulse, the duration of intervals between
pulses, and the duration of intervals between successive packets
in the train are in a predetermined pattern in accordance with
superwaving waves in which each wave is modulated by waves of
different frequency.   
\

![](plnrpg5.jpg)

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**US2003213696**

**Pulsed electrolytic cell**

Inventor:  DARDIK IRVING   
2003-11-20

**Abstract** -- A low energy nuclear reaction power
generator provided with an electrolytic cell containing an
electrically-conductive heavy or light water electrolyte in
which is immersed an electrode pair whose anode is formed of
platinum and whose cathode is formed of palladium. Applied
across these electrodes is a train of voltage pulse packets,
each comprised of a cluster of pulses. The amplitude and
duration of each pulse in the packet, the duration of the
intervals between pulses, and the duration of the intervals
between successive packets in the train are in a predetermined
pattern in accordance with superlooping waves in which each wave
is modulated by waves of different frequency.; Each packet of
voltage pulses gives rise to a surge of current in the
electrolyte which flows between the electrodes and causes the
heavy or light water to decompose, oxygen being released at the
platinum electrode while deuterium ions migrate toward the
palladium electrode. The successive surges of ions produced by
the train of pulse packets bombard the palladium electrode, to
bring about dense ion packing which results in fusion and heat.

![](pulselcl1.jpg)

![](pulselcl23.jpg)

![](pulslelcl4.jpg)

**BACKGROUND OF THE INVENTION**

**[0002] 1. Field of Invention**

[0003] This invention relates generally to the use of
electrolytic cells for the creation of nuclear fusion and more
particularly to a low energy nuclear reaction power generator
that includes an electrolytic cell across whose anode and
cathode electrodes electrical pulses are applied in a
predetermined pattern conducive to fusion.

**[0004] 2. States of Prior Art**

[0005] The quest for nuclear fusion to provide an
inexhaustible, non-polluting source of energy seeks to exploit
the phenomena of nuclear physics. It is known that when two
nuclei, for example, of deuterium (heavy hydrogen), fuse
together, the combined mass of the fusion product is less, by a
minute quantity, than the tiny mass of the original particles.
The conversion of this tiny mass to a fusion product releases an
incredible amount of energy. Energy, as expressed in the classic
Einstein equation, is equal to mass multiplied by the square of
the speed of light; hence the minute mass yields an enormous
amount of energy.

[0006] It was Edward Teller, the atomic physicist, who in 1942
when an atom bomb had yet to be built, advanced the proposition
that is the bedrock of nuclear fusion. Teller theorized that if
deuterium nuclei were plunged into the fiery furnace having a
temperature of many million degrees Fahrenheit created by an
atomic fission reaction, the colliding nuclei would fuse in this
environment and thereby liberate an incredible amount of energy.
With the hydrogen bomb, Teller's theory became a reality.

[0007] Deuterons are positively charged particles and,
therefore, repel each other. The closer deuterons approach each
other, the stronger their repulsion and the greater the energy
it takes to overcome this repulsion. When the force of the
repulsion reaches its maximum value, it then creates what is
known as the Coulomb barrier. It is only when this barrier is
penetrated and the deuterons are brought to one ten-trillionth
of a centimeter next to each other, that a strong nuclear force
takes over and the particles then fuse. This is the same nuclear
force that prevents nuclei which include positively-charged
protons from flying apart. Fusion also occurs with tritium
nuclei, for tritium is a heavy isotope of hydrogen, but its
nucleus has a proton and two neutrons, whereas a deuterium
nucleus has a proton and a single neutron.

[0008] Thermonuclear fusion will occur when deuterons are
combined at a high enough density and a high enough temperature
for a time period sufficient to effect fusion. The center of the
sun affords conditions conducive to thermonuclear fusion, for
this fiery center is subjected to enormous gravitational forces
and is at a temperature of about 10 million degrees Fahrenheit.
On earth, the gravitational forces are much weaker and it
therefore takes a much higher temperature, in the order of 100
million degrees Fahrenheit, to produce a deuterium-tritium (D-T)
fusion reaction. The D-T thermonuclear reaction is the one
currently being pursued, for it yields more energy than D-D
fusion.

[0009] Following Teller's invention of the hydrogen bomb,
billions of dollars have been spent over the last 40 years
toward contriving devices adapted to force heavy hydrogen nuclei
to fuse together under controlled conditions and thereby
liberate more energy than was expended to confine and heat the
nuclei. One such device of enormous size is known as a Tokomak
within whose toroidal interior powerful magnetic fields confine
and squeeze hot plasma, causing deuterium and tritium ions to
fuse together.

[0010] Hot fusion overcomes the Coulomb barrier by ripping off
atoms from the two heavy forms of hydrogen at extremely high
temperatures to create a cloud of ions or plasma. Huge magnets
produce the magnetic fields to hold the plasma together for a
time sufficient for some of the nuclei to crash into each other
and fuse. This thermonuclear fusion reaction produces tritium
and helium nuclei as well as a shower of neutrons and gamma
radiation.

[0011] In a super-giant laser fusion generator, laser beams
bombard a deuterium-tritium fuel pellet, causing its outer layer
to vaporize and dissipate outwardly from the pellet. The
resultant reaction force implodes the fuel to effect fusion. Yet
despite the multi-billion dollar investments made in developing
thermonuclear fusion reactors to produce energy, no such
generator is at present a practical reality, and whether it ever
will be, cannot be forecast. Other technologically simpler and
less expensive techniques for fusing nuclei are desirable.

[0012] In the past decade or so, electrochemical techniques
have been investigated as a possible technique for fusing nuclei
for power generation. The investigations typically utilize an
electrolytic cell whose electrolyte is heavy water that is water
in which deuterium takes the place of ordinary hydrogen. The
heavy water is rendered electrically conductive by a salt
dissolved therein; i.e., lithium deuterhydroxide. Immersed in
this electrolyte is an anode-cathode electrode pair composed of
a strip of metal (such as palladium) surrounded by a coil of
similar or another metal (such as platinum wire).

[0013] When a d-c voltage is impressed across these electrodes,
the resultant current flow in the heavy water causes it to
decompose into its constituent elements. As a consequence,
oxygen is released as a gas at the platinum electrode, while
deuterium ions migrate toward the palladium electrode. The
buildup of a large concentration of these ions in the palladium
metal is thought to initiate a low energy nuclear reaction. The
energy released by such an low energy reaction could be captured
by the atomic lattice of the electrode and show up as heat.

[0014] In 1989, Martin Fleischmann and Stanley Pons, on
observing excess heat generation in an electrochemical cell,
claimed they had observed evidence of room temperature fusion of
deuterium ions. It is now generally understood that their
observations were not that of deuterium-deuterium fusion but of
some other phenomena. Further electrochemistry studies by E.
Storms, G. H. Miley and others, suggest that the phenomena
involved is an anomalous nuclear process in the solid electrode.
The excess heat generation may be attributed to the fusion of
hydrogen or isotopic hydrogen nuclei with the nuclei of the
solid electrode material rather than of the fusion of hydrogenic
nuclei themselves. The amount of excess heat generated appears
to depend on the nature of the voltage applied to the electrodes
and on whether the resultant current flowing through the
electrolyte is steady or pulsed.

[0015] In any case, present day electrochemical cells do not
generate enough excess heat to be commercially viable power
sources. Further improvements in electrochemical cell design and
methods of operation are desirable.

**SUMMARY OF INVENTION**

[0016] The main object of this invention is to provide a low
energy nuclear reaction power generator that includes a cell
having a pair of electrodes immersed in an
electrically-conductive heavy or light water electrolyte, to
which electrodes electrical pulses are applied which are in a
predetermined pattern.

[0017] The significant feature of the present invention which
distinguishes it from a prior cell in which the current through
the electrolyte is pulsed, is that in a cell in accordance with
the invention, pulsing takes place in a pulse pattern that is
highly conducive to fusion.

[0018] More specifically, an object of this invention is to
provide a low energy nuclear reaction power generator that
yields far more energy in the form of heat than is applied to
the cell in the form of electricity.

[0019] Briefly stated, these objects are attained in a low
energy nuclear reaction power generator provided with an
electrolytic cell containing an electrically-conductive
electrolyte in which is immersed a metallic electrode pair whose
anode and cathode are formed of platinum, palladium, titanium,
nickel or any other suitable metal. The electrolyte may be any
suitable fluid such as light water, heavy water, and liquid
metals, etc. or may also be a suitable solid material--e.g., a
semiconductor. Applied across these electrodes is a train of
voltage pulse packets, each comprised of a cluster of pulses.

[0020] The amplitude and duration of each pulse in the packet,
the duration of the intervals between pulses, and the duration
of the intervals between successive packets in the train are in
a predetermined pattern in accordance with superlooping waves in
which each wave is modulated by waves of different frequency.
Each packet of voltage pulses gives rise to a surge of current
in the electrolyte which flows between the electrodes and causes
the electrolyte (e.g., heavy or light water) to decompose,
oxygen being released, for example, at the platinum electrode
while hydrogen (or isotopic hydrogen, e.g., deuterium) ions
migrate toward, for example, the palladium electrode. The
successive surges of ions produced by the train of pulse packets
bombard the metallic electrode to bring about dense ion packing.
The dense ion packing preferably causes fusion which results in
the generation of energy in the form of heat. The energy
generated in the heat is greater than the energy of the voltage
pulses applied to the electrodes.

[0021] It should be noted that the dense ion packing may
substantially increase the resistivity--i.e., the measure of a
material's ability to oppose the flow of an electric current--of
the metallic electrode by introducing hydrogen, or other, ions
to the structure of the metal. This resistivity preferably can
be measured in real-time by passing a current through the
metallic electrode and measuring the change in current over
time. The measured current over time is an indication of the
change in resistivity, and, hence, the level of ion packing of
the metallic electrode over time. Thus, a real time indicator of
the ion packing may then be realized by continually passing a
current through the metallic electrode and measuring the
current.

**BRIEF DESCRIPTION OF DRAWING**

[0022] For a better understanding of the invention as well as
other objects and features thereof, reference is made to the
following detailed description to be read in conjunction with
the annexed drawings wherein:

[0023] **FIG. 1** schematically illustrates superlooping
wave phenomena;

[0024] **FIG. 2** schematically illustrates a low energy
nuclear reaction electrolytic cell in accordance with the
invention;

[0025] **FIG. 3** illustrates the pattern of electrical
pulses applied to the electrodes of the cell; and

[0026] **FIG. 4** illustrates the pattern of electrical
pulses applied to the electrodes of the cell with pulse packets
switched off during relaxation periods.

**DETAILED DESCRIPTION OF INVENTION**

**[0027] Superlooping:**

[0028] The present invention represents a significant advance
beyond the discovery at the Los Alamos National Laboratory that
a greater production of excess heat is obtained in an
electrochemical cell by pulsing the current flowing through the
cell. In the present invention, applied to the electrodes of the
cell are voltage pulses to produce a pulsed current flow in the
cell. However, these pulses are not of constant amplitude and
duration but are in a pattern in which the amplitude and
duration of the pulses and the intervals therebetween are
modulated to give rise to a dense packing, for example, of
deuterium ions in the palladium electrode that promotes a fusion
reaction.

[0029] This pulse pattern is in accordance with superlooping
activity as set forth in the theory advanced in the Irving I.
Dardik article "The Great Law of the Universe" that appeared in
the March/April 1994 issue of the "Cycles" Journal. This article
is incorporated herein by reference.

[0030] As pointed out in the Dardik article, it is generally
accepted in science that all things in nature are composed of
atoms that move around in perpetual motion, the atoms attracting
each other when they are a little distance apart and repelling
upon being squeezed into one another. In contradistinction, the
Dardik hypothesis is that all things in the universe are
composed of waves that wave, this activity being referred to as
"superlooping." Superlooping gives rise to and is matter in
motion; i.e., both change simultaneously to define
matter-space-time.

[0031] Thus in nature, changes in the frequency and amplitude
of a wave are not independent and different from one another,
but are concurrently one and the same, representing two
different hierarchical levels simultaneously. Any increase in
wave frequency at the same time creates a new wave pattern, for
all waves incorporate therein smaller waves and varying
frequencies, and one cannot exist without the other.

[0032] Every wave necessarily incorporates smaller waves, and
is contained by larger waves. Thus each high-amplitude
low-frequency major wave is modulated by many higher frequency
low-amplitude minor waves. Superlooping is an ongoing process of
waves waving within one another.

[0033] FIG. 1 (adapted from the illustrations in the Dardik
article) schematically illustrates superlooping wave phenomena.
FIG. 1 depicts low-frequency major wave 110 modulated, for
example, by minor waves 120 and 130. Minor waves 120 and 130
have progressively higher frequencies (compared to major wave
110). Other minor waves of even higher frequency may modulate
major wave 110, but are not shown for clarity.

[0034] This new principle of waves waving demonstrates that
wave frequency and wave intensity (amplitude squared) are
simultaneous and continuous. The two different kinds of energy,
i.e., energy carried by the waves that is proportional to their
frequency, and energy proportional to their intensity are also
simultaneous and continuous. Energy therefore is waves waving,
or "wave/energy." In a low energy nuclear reaction power
generator in accordance with the invention, the pattern of
pulses applied to the electrodes of the cell is derived from
super-looping wave activity.

**[0035] The Low Energy Nuclear Reaction Power Generator:**

[0036] Referring now to FIG. 2, there is shown one preferable
embodiment of a low energy nuclear reaction power generator in
accordance with the invention provided with an electrolyte cell
having a vessel 10. Vessel 10 contains electrolyte 11.
Electrolyte 11 may be any suitable liquid electrolyte, such as
heavy water, light water, molten metals, etc. For purposes of
illustration, electrolyte 11 may, for example, be heavy water
which is rendered electrically conductive by a suitable salt
dissolved therein.

[0037] Immersed in the electrolyte is an anode-cathode
electrode pair formed by a cathode 12 and an anode 13. Cathode
12 and anode 13 may be made of any suitable metal such as
palladium, platinum, titanium, nickel, etc. For purposes of
illustration, cathode 12 may, for example, be a strip of
palladium and anode 13 may, for example, be a coil of platinum.
Anode coil 13 surrounds the strip of palladium metal so that the
electrodes are bridged by the conductive electrolyte 11 and a
voltage impressed across the electrodes causes a current to flow
therebetween.

[0038] Connected across the electrodes of the electrochemical
cell is a low-voltage battery, resulting in a steady current
flowing through the heavy or light water electrolyte, causing it
to decompose, so that oxygen gas is liberated at the platinum
anode electrode while hydrogenic ions migrate toward the
palladium cathode electrode and accumulate thereon.

[0039] In a generator in accordance with the invention, a d-c
voltage source 14 is provided whose output is applied across the
electrodes 12 and 13 of the cell through an electronic modulator
14 whose operation is controlled by a programmed computer 16,
whereby the modulator yields voltage pulses whose amplitude and
duration as well as the duration of the intervals between pulses
are determined by the program. The maximum amplitude of the
pulses corresponds to the full output of the d-c source 14. Thus
if the source provides a 45 VDC output, the maximum amplitude of
the pulses will be 45 VDC, and the amplitudes of pulses having a
lesser amplitude will be more or less below 45 VDC, depending on
the program.

[0040] Computer 16 is programmed to activate electronic
modulator 15 so as to yield a train of pulse packets, each
packet being formed by a cluster of pulses that assume the
pattern shown in FIG. 3. Thus the first packet in the train,
Packet I, is composed of five pulses P.sub.1 to P.sub.5 which
progressively vary in amplitude, pulse P.sub.1 being of the
lowest amplitude and pulse P.sub.5 being of the highest
amplitude. The respective durations of pulses P.sub.1 to
P.sub.5, vary progressively, so that pulse P.sub.1 is of the
shortest duration and pulse P.sub.5 is of the longest duration.
And the intervals A between successive pulses in the cluster
forming the packet vary progressively in duration. Thus the
first interval between pulses P.sub.4 and P.sub.5 is shortest in
duration, and the last interval between pulses P.sub.4 and
P.sub.5 is longest in duration. While the packets are shown as
being composed of five pulses, in practice they may have a fewer
or a greater number of pulses. The duration of a packet may in
practice be about thirty seconds, and the intervals between
successive packets may be in a range of two to five seconds.

[0041] The second packet in the train, Packet II, is also
composed of five pulses P.sub.6 to P.sub.10, but their
amplitudes and durations, and the intervals between pulses are
the reverse of those in the pulse cluster of Packet I. Hence
pulse P6 is of the greatest amplitude and that of P.sub.10 of
the lowest amplitude.

[0042] The third packet in the train, Packet III, is formed of
a cluster of five pulses P.sub.11 to P.sub.15 whose amplitudes
and durations, and the intervals between pulses correspond to
those in Packet I. The intervals between successive packets in
the train have a duration B that changes from packet to packet.

[0043] The varying amplitudes of the pulses in the successive
packets conform to the amplitude envelope of a major wave
W.sub.1. The varying durations of the pulses in the packets
conform to the amplitude envelope of a minor wave W.sub.2 whose
frequency differs from that of major wave W.sub.1. The varying
durations of the intervals between the pulses in a packet
conforms to the amplitude envelope of still another minor wave
W.sub.3 of different frequency. And the varying durations of the
intervals between successive packets in the train are in
accordance with the amplitude envelope of yet another minor wave
W.sub.4 of different frequency.

[0044] A second modulator 20 may be implemented in order to
measure the resistivity of cathode 12. Preferably, second
modulator 20 may generate an AC current and pass the AC current
through cathode 12. This AC current is preferably at a different
frequency than the pulses produced by electronic modulator 15.
In this way, no substantial interference exists between the
pulses produced by modulator 15 and the current produced by
second modulator 20.

[0045] In the proposed configuration shown in FIG. 3, the
current provided by modulator 20 may be used to measure the
resistivity of cathode 12. This measurement may be obtained by
passing an AC current, which may be substantially
constant--i.e., the amplitude of the peaks and valleys of the
current and the frequency of the current are substantially
constant--, through cathode 12 while measuring the voltage
potential across the cathode. The change in voltage potential
reflects the change in resistivity based on the relationship
V(voltage)=I(current)\*R(resistan- ce). The known resistivity
change may then be used to indicate the level of ion packing of
the cathode. As described above, ion packing may be a necessary
precursor for the success of low energy nuclear reactions in a
cell according to the invention.

[0046] It will be understood that in FIG. 3 for purposes of
clarity only small portions of minor waves W2, W3 and W4
superimposed on wave W1 are shown. Further for clarity, the
amplitudes and frequencies of superlooping minor waves W2, W3,
and W4, relative to each other and relative to major wave W1,
are not drawn to scale. In fact the maximum amplitude of the
minor waves may be proportional to the instantaneous amplitude
of the major wave. Thus, minor waves W2 and W3 (which are
located at about the peak amplitude of major wave W1) are likely
to have much larger maximum amplitudes than the maximum
amplitude of minor wave W4 (which is located at about the bottom
of a valley in wave W1). The maximum amplitude of minor waves W2
and W3 at the peak of the major wave may even be comparable to
the peak amplitude of major wave W1, i.e., the minor waves may
have the same intensity as the major waves as shown in FIG. 1.
Other illustrative examples of superlooping minor waves within
major waves and their frequency and amplitude distribution are
provided by the FIGS. shown in the Dardik article "The Great Law
of the Universe" incorporated herein by reference.

[0047] With continued reference to FIG. 3, the pattern of the
voltage pulses which constitute the train is governed by
superlooping waves W.sub.1 to W.sub.4 and the current which
flows between the electrodes immersed in the electrolyte is
pulsed accordingly.

[0048] Thus instead of a steady stream of deuterium ions
migrating toward the palladium electrode, the deuterium ions
travel in clusters, each created by a packet of pulses, to
produce a high intensity surge of deuterium ions that bombards
the palladium electrode. The surges of deuterium ions which
repeatedly bombard the palladium electrode give rise to a dense
packing of these ions on the palladium and fuse thereon to
produce heat.

[0049] Highly effective computer pulse pattern programs afford
optimum results, resulting in the greatest amount of fusion heat
at the palladium electrode. These can be determined empirically
by modifying the program to find the most effective pattern.

[0050] One example of the most effective pulse pattern is to
incorporate a relaxation period corresponding to the downward
phases of the major wave W1. Pulse packets in the pulse train
may be completely turned off during the relaxation periods
corresponding to the downward phases. FIG. 4 illustrates a pulse
pattern with pulses (e.g., packet P2, FIG. 3) completely
switched off during the relaxation period.

[0051] The program is developed from a formation of
superlooping waves which are digitized so as to derive a pulse
at the peak of each wave cycle. The aforementioned Dardik
article illustrates various forms of superlooping waves.

[0052] While there has been shown a preferred embodiment of a
low energy nuclear reaction power generator, it is to be
understood that many changes may be made therein without
departing from the spirit of the invention. Thus one may use a
silicon instead of platinum wire. And the electrode pair may be
formed by concentric tubes, rather than by a strip surrounded by
a coil as illustrated in FIG. 2.

---



**US2009021336**   
**INDUCTOR FOR THE EXCITATION OF POLYHARMONIC
ROTATING MAGNETIC FIELDS**

Inventor:  DARDIK IRVING I [US] ; LESIN SHAUL   
2009-01-22

**Abstract** -- An inductor for the excitation of
polyharmonic rotating magnetic fields (RMF) for controlling the
crystalline structure of continuous ingots and castings in
metallurgy and other foundry applications. The inductor design
makes it possible to use standard sources of sinusoidal currents
for generating polyharmonic RMF, and significantly increase cos
phi of the inductor.

![](us2009021336.jpg)

---



**WO2008156979**   
**SYSTEM AND METHOD FOR PRODUCING ANHARMONIC
MULTI-PHASE CURRENTS**

Also published as: WO2008156979 // US2008316782   
Inventor:  DARDIK IRVING [US] ; BRANOVER HERMAN   
2008-12-24

**Abstract** -- A system and method for producing anharmonic
multi-phase currents wherein the harmonic component of an
inverter is filtered and superimposed with a series of control
pulses to create a control signal. The control signal is fed
back to the inverter, causing the inverter to produce anharmonic
multi-phase current.

---



**CA2640362**   
**BATTERY CHARGING WITH SUPERWAVES**

Also published as: WO2007087380 // WO2007087380 // EP1977494   
Inventor:  KRAKOV VITALY [IL] ; BRANOVER HERMAN   
2007-08-02

**Abstract** -- Apparatus and methods are provided for
charging rechargeable batteries using amplitude and frequency
modulated current .

---



**CA2637213**   
**METHOD OF CONTINUOUS CASTING IN WHICH AXIAL
POROSITY IS ELIMINATED AND THE CRYSTALLINE STRUCTURE IS
REFINED**

Also published as:  WO2007087378 //  WO2007087378 //
EP1989012 // CN101378864   
Inventor:  LESIN SHAUL L [IL] ; MIKHAILOVICH BORIS   
2007-08-02

**Abstract** -- Apparatus and methods are provided for
eliminating axial porosity accompanie d by impurity segregation
arising at bulk crystallization of the axial zone of the liquid
core of a continuous ingot.

---



**BRPI0515178**   
**METHODS AND FACILITIES FOR SUPPRESSING
VORTICES ARISING IN TUNDISHES OR LADLES DURING THEIR
RESPECTIVE DISCHARGE**

Also published as:  WO2006031964 //
KR20070052343   // JP2008513214 // EP1791665 // 
CN101039768   
Inventor:  DARDIK IRVING I ; KAPUSTA ARKADY   
2008-07-08

**Abstract** -- A presente invencao refere-se a um metodo
que e fornecido para suprimir um vertice que surge em um panela
intermediaria ou caco durante o abaixamento da superficie livre
da fusao abaixo de um nivel critico utilizando um campo
magnetica rotativo excitado na fusao acima de um tubo de fluxo
de saida por um indutor RMF de um desenho especial

---



**US7316800**   
**Electromagnetic helical pump for
high-temperature transportation of molten metal**

Inventor:  DARDIK IRVING I [US] ; KAPUSTA ARKADY   
2008-01-08

**Abstract** -- Electromagnetic helical pump for
high-temperature transportation of molten metal, comprising an
explicit-pole or implicit-pole inductor exciting a rotating
magnetic field (RMF), and a helical channel consisting of a
thick-wall ceramic pipe with a quick-change helical core made of
graphite or graphitized carbon. The pump can be used for
transportation and batching of molten aluminum, magnesium,
copper, etc. and their alloys.

---



**WO2007144925**   
**METAL LAMINATE MATERIALS WITH INCLUSIONS OF
DIELECTRIC MATERIAL FOR THE ENHANCEMENT AND CONTROL OF THE
INTERFACE ELECTRIC FIELD AND PROCESS FOR THEIR PRODUCTION**

Inventor:  BETTINALI LIVIO [IT] ; VIOLANTE VITTORIO, et
al.   
2007-12-21

**Abstract** -- The invention concerns the development of a
material suitable to enhance the interface electric field during
polarization processes of the same material, such as, for
instance, during a "glow discharge" or an electrolysis. The
material comprises a metal matrix capable to absorb hydrogen and
its isotopes, preferably palladium, on the surface of which
there are provided, by any suitable method, some inclusions of
dielectric material or in any case some surface defects, having
a fixed size and space distribution, and of such a nature ad
they result in a suitable dispersion of the dielectric constant
and, in addition, shows a surface rugosity. Such conditions are
required for the material to result in a particularly high
localization of the interface electric field during polarization
processes.

---



**US2007157996**   
**System and method of electromagnetic
influence on electroconducting continuum**

Also published as:  US7381238 // US2004187964 // US7350559
//  US2007145652 // US2007151414   
Inventor:  DARDIK IRVING I [US] ; KAPUSTA ARKADY   
2007-07-12

**Abstract** -- Thus, as shown by an exact electrodynamic
computation of EMBF and the estimations described above of the
velocity of turbulent flows arising due to their effect,
application of amplitude- and frequency-modulated helically
traveling (rotating and axially traveling) electromagnetic
fields in metallurgical and chemical technologies and foundry
can considerably increase the hydraulic efficiency of MHD
facilities, intensify the processes of heat and mass transfer in
technological plants, significantly increase their productivity,
considerably decrease energy consumption for the production of
metals, alloys, cast articles, and chemical products, and
improve their quality.

---



**CA2637213**   
**METHOD OF CONTINUOUS CASTING IN WHICH AXIAL
POROSITY IS ELIMINATED AND THE CRYSTALLINE STRUCTURE IS
REFINED**

Also published as:  WO2007087378 //  WO2007087378 //
EP1989012 // CN101378864   
Inventor:  LESIN SHAUL L [IL] ; MIKHAILOVICH BORIS   
2007-08-02

**Abstract** -- Apparatus and methods are provided for
eliminating axial porosity accompanie d by impurity segregation
arising at bulk crystallization of the axial zone of the liquid
core of a continuous ingot.

---



**BRPI0515178**   
**METHODS AND FACILITIES FOR SUPPRESSING
VORTICES ARISING IN TUNDISHES OR LADLES DURING THEIR
RESPECTIVE DISCHARGE**

Also published as:  WO2006031964 //
KR20070052343   // JP2008513214 // EP1791665 // 
CN101039768   
Inventor:  DARDIK IRVING I ; KAPUSTA ARKADY   
2008-07-08

**Abstract** -- A presente invencao refere-se a um metodo
que e fornecido para suprimir um vertice que surge em um panela
intermediaria ou caco durante o abaixamento da superficie livre
da fusao abaixo de um nivel critico utilizando um campo
magnetica rotativo excitado na fusao acima de um tubo de fluxo
de saida por um indutor RMF de um desenho especial

---

  

**US20090021336**   
**INDUCTOR FOR THE EXCITATION OF POLYHARMONIC ROTATING MAGNETIC
FIELDS**

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**SYSTEM AND METHOD FOR PRODUCTING ANHARMONIC MULTI-PHASE
CURRENTS**

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**Modified electrodes for low energy nuclear reaction power
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electroconducting continuum**

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electroconducting continuum**

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---

---