Anatoly Kinderevich: Transmutation of Nuclear Waste -- Book
excerpt, US Patent Application, etc.

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**Anatoly KINDEREVICH**

**Transmutation of Nuclear Waste**

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***Field Essence of Nuclear Physics***

**by** **Anatoly Kinderevich**

**[ [EXCERPTS: MS WORD DOC](excerpts.doc), 391
KB ]**

*A Real Cure for Chernobyl?*

Ukrainian mathematician and scientist Anatoly Kinderevich has
developed a practical way to render nuclear wastes less harmful.
In a specially constructed chamber, hazardous radionuclides are
transmuted into less harmful elements. The method could not only
make Chernobyl safer, but also lead to many other new
technologies. The scientists and engineers under Kinderevichs
leadership have demonstrated successfully controlled accelerated
decay of strontium, cesium, and Chernobyl samples.

To date, in various laboratories throughout the world, there
have been at least ten successful experiments demonstrating
controlled accelerated decay of radioactive isotopes. All have
involved high-energy bombardment of nuclei and are prohibitively
expensive. Kinderevichs approach could be the first
economically feasible one.

*Field Essence of Nuclear Physics* (2005, 340 pp.) is
rigorously mathematic and completely integrates Kozyrevs
time-space flows of structurization and destructurization with
models of the Coulomb barrier, thereby providing a new
understanding of relativity and resolving the particle/quantum
question elegantly. The Kinderevich Field Theory also explains
gravity clearly and succinctly in relation to electromagnetics.
The book has recently been translated into English by Randall
Roffe and Vyacheslav Varetsky, a physicist at the Center of
Radiation Medicine of the Ukraine Academy of Medical Sciences. *Fundamentals
of Field Physics* (2000) and *Experimental Gravitonics
in the Field Physics Paradigm* (2004) are currently in
translation.

**For more information:**

**Randall Roffe**

**de roffe@yahoo.com**

President, Ukraine Chiropractic Association   
Nation Member World Federation of Chiropractic   
In Formal Relations with United Nations World Health
Organization   
Member International Sports Chiropractic Federation   
In Formal Relations with UNESCO

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**United States Patent Application 
20040238366**   
**[ [PDF](us04238366.pdf)
]**

**Vladimirovich, Kinderevich Anatoly, et al.**

**( December 2, 2004 )**

**Method and System with Apparatus for
Acceleration of Activity Decrease and Radioactive Material
Deactivation**

**Abstract --** Radioactive material can be processed by an
apparatus that includes at least a cylindrical outer shell
electrode, an inner electrode, and a plurality of prism-shaped
ferromagnetic elements positioned between the outer and inner
electrodes. The prism-shaped ferromagnetic elements are
positioned around the inner circumference of the metal cylinder.
The inner electrode component is located within the metal
cylinder and is configured to cover the inwardly-pointing
portions of the prism-shaped ferromagnetic elements. Radioactive
material in a container is placed into the apparatus, and an AC
voltage excitation signal is applied to the electrodes of the
apparatus during treatment of the material. The frequency of the
excitation signal is selected according to the frequency of
structurization or the frequency of destructurization of the
ferromagnetic material. The process can be monitored and
controlled with the use of alpha, beta, and gamma radiation
intensity measuring instruments.

**Inventors:**  Vladimirovich, Kinderevich Anatoly;
(Kiev, UA) ; Ivanovich, Kicha Leonid; (Kiev, UA)   
Correspondence Name and Address:

**Correspondence:**

MARK M. TAKAHASHI   
GRAY CARY WARE & FREIDENRICH, LLP   
4365 EXECUTIVE DRIVE, SUITE 1100   
SAN DIEGO, CA 92121-2133 USA

U.S. Current Class:  205/43; 204/230.2; 204/242; 588/1   
U.S. Class at Publication:  205/043; 588/001; 204/230.2;
204/242   
Intern'l Class:  G21F 009/00; C25B 001/00; C25C 001/22;
C25C 003/34

**Description**

**FIELD OF THE INVENTION**

[0001] The present invention relates generally to the field of
applied physics, and deals with the acceleration of processes of
activity decrease and deactivation of radioactive materials of
high and low activity levels. More particularly, the present
invention relates to the treatment of radioactive material such
as waste from nuclear power plants.

**BACKGROUND OF THE INVENTION**

[0002] Worldwide development of nuclear power engineering has
created a problem that is progressively turning into a global
ecological issue. Namely, this problem relates to the
accumulation, processing, and storing of radioactive waste
materials. The United States, France, and Russia process the
nuclear waste that has accumulated over time. Such processing is
partial in that only five or six isotopes are returned into the
new fuel cycle, while other isotopes are no longer suitable for
utilization.

[0003] There are approximately 50 actinides accumulated in
every nuclear reactor at the end of each operating period, and
20 of the actinides are long-living isotopes that remain highly
radiotoxic despite long periods of aging. Such nuclear waste is
typically stored in special containers buried deep below the
surface of the earth; nevertheless, this storage method can be
the source of ecological problems and the subject of controversy
and concern. Existing processing technologies for radioactive
waste are very expensive, laborious, not environmentally safe,
and are time consuming.

[0004] Consequently, there exists a need for new techniques of
acceleration of the processes of activity decrease and
deactivation of radioactive material (hereinafter referred to as
"treatment" of radioactive material).

**BRIEF SUMMARY OF THE INVENTION**

[0005] The method of activity decrease and deactivation of
radioactive materials uses a system that includes an apparatus
for treatment of radioactive material configured to function as
a large hollow capacitor having a ferromagnetic material in lieu
of a dielectric material. The system includes a power source,
such as a signal generator that supplies a suitable AC voltage
of adjustable frequency to the apparatus. A container with
radioactive material is placed into the cavity of the apparatus,
an appropriate frequency is selected for the signal generator,
and the AC voltage at the selected frequency is applied to the
apparatus until activity of the radioactive material is
decreased to the permissible level or until complete
deactivation has occurred. These processes are monitored with
alpha, beta, and gamma meters.

**BRIEF DESCRIPTION OF THE DRAWINGS**

[0006] A more complete understanding of the present invention
may be derived by referring to the detailed description and
claims when considered in conjunction with the following
Figures, wherein like reference numbers refer to similar
elements throughout the Figures.

[0007] **FIG. 1** is a schematic block diagram of a system
for treating radioactive material;

![](fig1.jpg)

[0008] **FIG. 2** is a longitudinal sectional view of an
apparatus for treating radioactive material;

![](fig2.jpg)

[0009] **FIG. 3** is a cross sectional view of the
apparatus shown in FIG. 2, as viewed from line 3-3; and

![](fig3.jpg)

[0010] **FIG. 4** is a sectional view of a portion of the
apparatus, showing the direction of the emitted flows focusing.

![](fig4.jpg)

**DETAILED DESCRIPTION OF A PREFERRED EMBODIMENT**

[0011] It should be appreciated that the particular
implementations shown and described herein are illustrative of
the invention and its best mode and are not intended to
otherwise limit the scope of the invention in any way. Indeed,
for the sake of brevity, conventional aspects of the systems
(and the individual operating components of the systems) may not
be described in detail herein. Also, dimensions of components of
the apparatus of radioactive material treatment, which differ in
each specific case of application, are not provided.

[0012] The term "radioactive material" as used herein comprises
all wastes contaminated with radioactive substances in the
quantities exceeding the established standards and rules. Solid
wastes are considered radioactive if specific medical
exploitation dose at the distance of 1 centimeter from the given
waste exceeds 0.84 milliroentgen hour per kilogram or specific
activity exceeds 2.times.10.sup.-6 and 1.times.10.sup.-8 Ci/kg
(7.times.10.sup.4 and 3.7.times.10.sup.2 Bq/kg), respectively,
for beta- and alpha-active and transuranium elements. All
radioactive isotopes, nuclear wastes can be conventionally
subdivided into highly active, when specific activity amounts to
10.sup.15-10.sup.14 Bq/kg, medium active, 10.sup.13-10.sup.9
Bq/kg, low active, 10.sup.8 Bq/kg.

[0013] FIG. 1 is a schematic block diagram of a system 100 for
the treatment of radioactive material. System 100 includes at
least the following components: a treatment apparatus 102
configured as a hollow capacitor of complicated shape which
holds a container (capsule) 103 for holding radioactive
material; an excitation signal generator 104 connected to the
treatment apparatus 102 with a high frequency cable 105; one or
more alpha-, beta-, and gamma-activity sensors 106 located in
the container; and a grounded shielding device 107. The dashed
line in FIG. 1 indicates that the activity sensor 106 may, but
need not, be connected to the generator 104 for purposes of
feedback control.

[0014] The treatment apparatus 102 is generally configured as a
special capacitor having an external shell electrode and an
inner electrode. In lieu of a conventional dielectric material,
the treatment apparatus 102 utilizes a ferromagnetic material
located between the two electrodes. The treatment apparatus 102
includes a cavity formed therein; the cavity receives the
container (capsule) with radioactive material. The container is
positioned inside of the cavity during treatment of the
material.

[0015] The adjustable generator 104 is connected to the
electrodes of the capacitor 102, and is used for supplying AC
voltage of suitable frequency, at which the so-called flows of
structurization or destructurization are excited in the
ferromagnetic and focused inside of the apparatus. These flows
cause deceleration or acceleration of radioactive decay and
spontaneous radioactive decay in the container.

[0016] Meters 106, which can be off-the-shelf commercially
available instruments, are used to measure the intensity of
alpha-, beta-, and gamma-radiation of the radioactive materials
in the container. The readings of these detectors are used for
monitoring of the technological process.

[0017] FIGS. 2 and 3 are views of sections of an apparatus 200
for treating radioactive material. FIG. 2 is a longitudinal
sectional view of apparatus 200, as viewed from line 2-2 in FIG.
3 (line 2-2 represents a line that intersects the longitudinal
axis of apparatus 200), and FIG. 3 is a cross sectional view of
apparatus 200, as viewed from line 3-3 in FIG. 2. FIG. 4 is a
cross sectional view of a portion of the apparatus, which shows
the direction of the excited flows (of structurization or
destructurization) focusing.

[0018] Apparatus 200 generally includes an outer shell
electrode 202, an inner electrode 204, a plurality of
ferromagnetic prisms 206, a first inner end electrode 208, a
first outer end electrode 210, a second inner end electrode 212,
a second outer end electrode 214, a first ferromagnetic end
element 216, and a second ferromagnetic end element 218.

[0019] Outer shell electrode 202 may be cylindrical in shape.
Other shell shapes may be utilized in alternate embodiments,
e.g., polyhedron, spherical, or the like, as long as the shape
facilitates proper focusing of the space-time flows. Outer shell
electrode 202 is formed from an electrically conductive material
such as metal. Although the preferred practical embodiment
employs an outer electrode formed from stainless steel, other
materials such as copper, zinc, or a suitable alloy can be
utilized. The inner surface of electrode 202 defines the
interior of electrode 202. The size of outer shell electrode 202
may vary to accommodate the particular application.

[0020] The ferromagnetic prisms 206 are positioned within the
interior of outer shell electrode 202 and around the inner
surface of outer shell electrode 202, as shown in FIG. 3. The
prisms 206 are held in place in any suitable manner. For
example, they can be glued to the inner electrode 204 such that
electrical contact is maintained between the prisms 206 and the
electrodes. In accordance with one practical embodiment, each
ferromagnetic prism 206 has a triangular cross section (see FIG.
3). The triangular cross section includes an acute angle that
forms an apex that points toward the interior of the apparatus.
In this embodiment, each prism-shaped element 206 is identical
in size, shape, and composition. The shape of the ferromagnetic
prisms 206 facilitates the combination of the vectors of
space-time flows generated by the prisms 206. The shape ensures
that the resulting flows are directed toward the center of the
cavity within the treatment apparatus.

[0021] In the example embodiment, the cylindrical shell
electrode 202 and each of the ferromagnetic prisms 206 are of
the same length. As shown in FIG. 3, each of the ferromagnetic
prisms 206 is positioned within the interior of the outer
electrode 202 such that its apex points toward the longitudinal
center of treatment apparatus 200. In other words, all of the
triangles defined by the cross sections of the prisms point
radially inward. The number of ferromagnetic prisms 206, and
their shape, size, and composition, may vary depending upon the
particular application. Practical embodiments include at least
three prism elements. In the illustrated example, apparatus 200
includes twelve prism-shaped elements 206 positioned around the
inner surface of outer shell electrode 202 such that adjacent
prisms contact each other at their respective bases.

[0022] The prism-shaped elements 206 should be formed from a
ferromagnetic material. One suitable material is identified as
material catalog number 250 VNRP according to the Ukraine
National Nomenclature. 250 BHP.PI. is nickel-zinc ferromagnetic.
It has the following technological characteristics: (1) specific
magnetization saturation: .sigma..sub.i=50-80 A\*m.sup.2/kg; (2)
coefficient of shrinkage: in the limits of 1.14-1.18; (3)
initial magnetic permeability: .mu..sub.H=180-400; maximal
allowable operation temperature: not less than 120.degree. C.
The material is generally characterized as a high frequency
(10-100 MHz) ferromagnetic material. In this regard,
ferromagnetic materials of low and super-high frequency are not
desirable in this application.

[0023] The inner electrode 204 is formed from an electrically
conductive material, such as metal. Although the preferred
practical embodiment employs an inner electrode formed from
stainless steel, other materials such as copper, zinc, an alloy,
or any current-conducting material can be utilized. The inner
electrode 204 is located within the interior of the shell
electrode 202, and is coupled to the ferromagnetic prisms 206
such that the prism-shaped elements 206 are not exposed to the
interior. In this regard, the ferromagnetic material is located
between the inner surface of the shell electrode 202 and the
inner electrode 204. The inner electrode 204 is configured such
that it does not contact the outer shell electrode 202. In the
practical embodiment, the inner electrode 204 may be realized as
a plurality of flat plates that are joined together at points
between the prisms 206 and at the apexes of the prisms 206.
Alternatively, the inner electrode 204 may be formed as a
unitary component.

[0024] The inner electrode 204 is held in place in any suitable
manner, for example, by gluing or welding it to the prism shaped
elements 206. As shown in FIGS. 2 and 3, the inner electrode 204
defines a cavity 220 within the interior of the treatment
apparatus 200. The cavity 220 is shaped to accommodate the
container 222 in which the radioactive material is placed. The
container 222 is formed as a cylindrical vessel in which
radioactive material is sealed. In a practical embodiment, the
container 222 is preferably formed of lead because lead screens
alpha, beta, and gamma radiation while allowing the space-time
flows to pass. Although not shown, the container 222 rests on
dielectric or insulating plates or mounts to ensure that the
container 222 is electrically isolated from the inner electrode
204 during processing of the radioactive material.

[0025] The first inner end electrode 208 is formed from an
electrically conductive material. The first inner end electrode
208 is connected to one end of the inner electrode 204 to
establish electrical continuity. In the example embodiment, the
first inner end electrode 208 is a conical shell electrode that
contacts the inner electrode 204 at the inwardly facing points.
In this regard, the first inner end electrode 208 is physically
attached to the inner electrode at these points. In practice,
these two electrodes can be connected together (by welding,
soldering, etc.).

[0026] The exact dimensions and configuration of first inner
end electrode 208 may vary from one system to another.
Generally, the dimensions of the first inner end electrode 208
are proportional to the dimensions of the Egyptian pyramids.

[0027] First ferromagnetic end element 216 is mounted in the
first inner end electrode 208 as shown in FIG. 2. The end
element 216 may be welded, bonded, or otherwise secured to the
first inner end electrode 208. The end element 216 is preferably
formed from the same ferromagnetic material used for the
prism-shaped elements 206. In this example, the end element 216
is cone-shaped, which allows it to mate with conical shell
electrode 208. Generally, the dimensions of the first
ferromagnetic end element 216 are proportional to the dimensions
of the Egyptian pyramids. The height of the first ferromagnetic
end element 216 may be greater than the height of the first
inner end electrode 208, as depicted in FIG. 2 and FIG. 5. This
feature facilitates the focusing properties of the apparatus.

[0028] The first outer end electrode 210 is mounted to the
outer surface of the first ferromagnetic end element 216 such
that electrode 210 does not contact the first inner end
electrode 208. The first outer end electrode 210 may be glued or
otherwise secured to the outer surface of the end element 216.
The first outer end electrode 210 is formed from an electrically
conductive material. As schematically shown in FIG. 2, the first
outer end electrode 210 is electrically connected to the outer
shell electrode 202 and to the second outer end electrode 214.
This electrical connection may be established using wire,
cabling, or any suitable electrical conductor.

[0029] The exact dimensions and configuration of first outer
end electrode 210 may vary from one system to another. In
accordance with one practical embodiment, the first outer end
electrode is a circular plate. The diameter of the first outer
end electrode 210 may be less than the base diameter of the
first ferromagnetic end element 216, as depicted in FIG. 2.

[0030] The second inner end electrode 212 is also formed from
an electrically conductive material. The second inner end
electrode 212 is connected to the end of the inner electrode 204
(opposite the first inner end electrode) to establish electrical
continuity. Thus, the first inner end electrode 208, the second
inner end electrode 212, and the inner electrode 204 cooperate
to form one electrode component. In the example embodiment, the
second inner end electrode 212 is a truncated conical shell
electrode that contacts the inner electrode 204 at its inwardly
facing points. In this regard, the second inner end electrode
212 can be physically attached to the inner electrode 204 at
these points, in the same manner as described above for the
first inner end electrode 208. In this example, the truncated
tip forms an opening in the second inner end electrode 212. As
shown in FIG. 2, this opening is positioned within the interior
of the outer shell electrode 202. The exact dimensions and
configuration of second inner end electrode 212 may vary from
one system to another.

[0031] Second ferromagnetic end element 218 is mounted in the
second inner end electrode 212 as shown in FIG. 2. The end
element 218 can be glued or otherwise secured to the second
inner end electrode 212. The ferromagnetic end element 218
should be formed from the same ferromagnetic material used for
the prism-shaped elements 206. In this example, the end element
218 is shaped like a truncated cone, which allows it to mate
with second inner end electrode 212. The height of the second
ferromagnetic end element 218 may be greater than the height of
the second inner end electrode 212, as depicted in FIG. 2.

[0032] As shown in FIG. 2, the second ferromagnetic end element
218 has a conduit or passageway formed therein along its central
axis. In the example embodiment, this conduit is a cylindrical
hole having a diameter that is large enough to allow for passage
of the container 222.

[0033] The second outer end electrode 214 is mounted to the
outer surface of the second ferromagnetic end element 218 such
that electrode 214 does not contact the second inner end
electrode 212. The second outer end electrode 214 is formed from
an electrically conductive material. As schematically shown in
FIG. 2, the second outer end electrode 214 is electrically
connected to the outer shell electrode 202 and to the first
outer end electrode 210. This electrical connection may be
established using wire, cabling, or any suitable electrical
conductor. Thus, the first outer end electrode 210, the second
outer end electrode 214, and the outer shell electrode 202
cooperate to form one outer electrode component.

[0034] As shown in FIG. 2, the second outer end electrode 214
has a hole formed therein. This hole is sized to accommodate
canister 222. The hole is positioned for alignment with the
conduit formed in the second ferromagnetic end element 218.
Thus, the opening formed by the truncated tip of the second
inner end electrode 212, the conduit in the second end element
218, and the hole in the second outer end electrode 214 form a
passageway for the radioactive material, which may be enclosed
within the container 222.

[0035] The exact dimensions and configuration of the second
outer end electrode 214 may vary from one system to another. In
accordance with one practical embodiment, the second outer end
electrode 214 is a ring-shaped plate. The outer diameter of the
second outer end electrode 214 may be less than the base
diameter of the second ferromagnetic end element 218, as
depicted in FIG. 2.

[0036] The generator of the excitation signal 104 is shown in
FIG. 1; it is connected to the second outer end electrode 214,
to the second inner end electrode 212, as shown in FIG. 2.

**Theory of Operation**

[0037] The basis of the proposed method is constituted by the
phenomenon of excitation of flows of structurization,
.DELTA..tau..sub.l, and destructurization, .DELTA..tau..sub.2,
in substance. Its physical substantiation is based upon the
frequencies of proton nuclear magnetic resonance (NMR) in the
phases of dispersion (J. W. Emsley, J. Feeney, and L. H.
Sutcliffe, HIGH RESOLUTION NUCLEAR MAGNETIC SPECTROSCOPY, in two
volumes, New York (1966)). Dispersion phase at NMR is a state of
transition from the frequency of structurization to the
frequency of destructurization or vice versa. In the chart
showing energy absorption in NMR, crossing of the abscissa will
be present without failure. This phenomenon characterizes
dispersion.

[0038] It is established that when exposed to electromagnetic
oscillations of specific frequency f.sub.i, the substance,
absorbing the energy of these oscillations, emits the flows of
structurization, .DELTA..tau..sub.1. At this, chemical shift
takes place; and the substance somewhat decreases its sizes
(isomerism). At the frequency of oscillations f.sub.2, the
substance emits the flows of destructurization,
.DELTA..tau..sub.2. At this, chemical shift takes place; and the
substance somewhat increases its sizes (isomerism).

[0039] The frequency of structurization f.sub.1, is defined as
such a frequency of electromagnetic oscillations that
ferromagnetic material, when exposed to it, as a result of
nuclear magnetic resonance, emits the flows of space-time
.DELTA..tau..sub.1 that cause the phenomenon of structurization
and dilation of any physical process. The frequency of
destructurization f.sub.2 is defined as such a frequency of
electromagnetic oscillations that ferromagnetic material, when
exposed to it, as a result of nuclear magnetic resonance, emits
the flows of space-time .DELTA..tau..sub.2 that cause the
phenomenon of destructurization and acceleration of any physical
process (A. B. , . , . , ., 2000r. (A. V. Kinderevich, L. I.
Kicha, FIELD THEORY. ELEMENTS OF NUMBERS THEORY, Kyiv 2000)--pp.
405-408). The reaction of the space-time flows effect is
measured by N. A. Kozyrev detector, which is considered in the
works: H. A.// . AH. APM. CCCP, 1997r. (Kozyrev N. A.,
ASTRONOMICAL OBSERVATIONS BY THE WAY OF PHYSICAL PROPERTIES OF
TIME, Academy of Sciences of Armenian SSR (1977)); H. A., B.
B.// , 1980r. (Kozyrev N. A., Nasonov V. V., PROBLEMS OF
UNIVERSE STUDIES (1980)); M. M., . A., M. .//CCCP, 1990r., c.314
(Lavrentyev M. M., Yeganova I. A., Lutset M. K., Doklady
Akademyy Nauk USSR, (1990), p. 314).

[0040] In the monograph A. B. , . , . , ., 2000r. (A. V.
Kinderevich, L. I. Kicha, FIELD THEORY. ELEMENTS OF NUMBERS
THEORY, Kyiv (2000)), it is shown that any substance affects the
flows .DELTA..tau..sub.2 emitted by some mass very
insignificantly; and it is essentially transparent for them.
However, insignificant fraction of these flows deflects at
specified angle when passing from a less dense substance to a
denser one. This could result in appearance of some resemblance
of static lenses of .DELTA..tau..sub.2 focusing, which have real
and imaginary focuses, and, consequently, in local thickening of
the space-time flows and their rarefication, which is related to
the Hubble number, H, changes in this local region, acquiring
the magnitude H.sub.1. The normal intensity of the physical
processes is determined by the Hubble constant: 1 H = 2.8
.times. 10 - 18 1 c .

[0041] If the flows density increase takes place, then in this
local region H.sub.1>H, if the flows rarefication takes
place, then H.sub.1<H. Relation 2 H 1 H

[0042] is an attribute of the local region: at 3 H 1 H > 1

[0043] destructurization takes place, at 4 H 1 H < 1

[0044] structurization takes place. It is substantiated
theoretically that the larger the flow .DELTA..tau..sub.2, the
smaller will be structurization at the given point of the Earth
surface.

[0045] This is explained by the fact that the values
.DELTA..tau..sub.2 and 5 H 1 H

[0046] are linked by the relation 6 t 2 = 0.5 H 1 H M 4 R E 2 ,

[0047] where M=const, R.sub.E is the radius of Earth. From
here, it is seen that when the value 7 H 1 H > 1

[0048] increases at given point of "Earth-Universe"
destructurization will increase and vice versa at 8 H 1 H <
1.

[0049] It is shown that the change of the magnitude of the
activity, A, of radioactive materials at the initial specific
activity A.sub.0=(10.sup.8.div.10.sup.15) Bq/kg equals to: 9 A =
A 0 - H H 1 t , ( 1 )

[0050] where .lambda. is the decay constant, t is time.

[0051] It could be easily noted that at the specific magnitudes
of the value 10 H 1 H ,

[0052] the given exponential function decreases faster as
compared to the known function for the activity assessment:
A=A.sub.0e.sup.-.lambda.t.

[0053] As an example, the following calculations are for the
radioactive isotope Cs-137, where the radioactivity of the
freshly unloaded fuel, A.sub.0, is equal to 10.sup.15 Bq/kg.

[0054] The half-life for Cs-137 (T.sub.1/2) is 30.2
years=9.5.times.10.sup.8 seconds. Respectively, 11 = 0.693 T 1 /
2 = 7.3 .times. 10 - 10 .

[0055] Let 12 H H 1 = 10 6 ,

[0056] that is, H.sub.1<<H, then according to expression
(1),
A=10.sup.12.times.e.sup.-7.3.times.10.sup..sup.-10.sup..times.10.sup..sup-
.6.sup.t.
For time t=10 days=8.6.times.10.sup.5 seconds, 13 A = 10 12 e
629 .

[0057] That is, a significant decrease of the radioisotope
activity magnitude will take place.

[0058] If we accept that e.sup.25=6.times.10.sup.10, then we
obtain 14 A 10 12 6 .times. 10 10 1.6 .times. 10 - 3 Bq / k g .

[0059] Such decrease of the activity will occur during 9.4
hours since 15 t = 25 7.3 .times. 10 - 4 = 3.4 .times. 10 4

[0060] seconds. Consequently, the decrease of the Hubble number
H.sub.1 in some local region will cause the decrease of activity
and, respectively, deactivation of radioactive material.

[0061] Consequently, to decrease the activity of radioactive
material, it should be placed into the local region where
structurization takes place at given flow density
.DELTA..tau..sub.1, excited in ferromagnetic material at the
frequency of electromagnetic oscillations f.sub.1.

[0062] It is substantiated theoretically that in order to
accelerate deactivation of radioactive material with unexcited
nuclei with A.sub.0=10.sup.2 Bq/kg and lower, the intensity of
the fission reaction should be increased. It means that the
radioactive material should be placed in the local region with
16 H 1 H > 1.

[0063] It is shown that at neutron multiplication under the
conditions of 17 H 1 H

[0064] and flow .DELTA..tau..sub.2 growth, when the specific
density of neutrons flux reaches 10.sup.20 cm/s, under
fulfillment of the criterion 18 p .times. Nv k ( H 1 H ) 2 4 , 8
.times. 10 13 Ci ,

[0065] where .rho. is probability, N is the number of atoms, v
is the average number of neutrons at decay of one atom v=2.5, K
is the stage of decay, .DELTA..tau..sub..rho.2 is the flow from
nuclear structurization, spontaneous chain reaction could occur.
This should be taken into consideration when determining the
amount of radioactive material to be subjected to deactivation
lest the critical mass be formed.

[0066] It is shown that the activity change in this case equals
to 19 A = A 0 ' H 1 H t .

[0067] Here 20 A 0 ' = A 0 H 1 H

[0068] is increase of the activity in the intensification
apparatus due to the spontaneous fission of nuclei. Let 21 H 1 H
= 10 7 ,

[0069] then
A=A'.sub.0e.sup.-.lambda..times.10.sup..sup.7.sup..times.t. As
an example, the following calculations are for the unexcited
nuclei activity decrease for Cs-137 isotope.

A.sub.0=10 Bq/kg;

[0070] 22 A 0 ' = A 0 H 1 H = 10 6 Bq / kg ;
A=A'.sub.0e.sup.-7.2.times.10.sup..sup.-10.sup..times.10.sup..sup.7.sup.t-
=10.sup.9e.sup.-7.2.times.10.sup..sup.-3.sup.t.

[0071] For the time t=10
days=24.times.3600.times.10=86.times.10.sup.5 seconds, 23 A = 10
9 7.3 .times. 10 - 3 .times. 8.6 .times. 10 5 = 10 9 6290 .

[0072] Meanwhile, even at e.sup.20, the activity will already
be A=0.9 Bq/kg.

[0073] Consequently, in this case, in order to decrease
activity, accelerate deactivation of radioactive material, it
should be placed into the local region where destructurization
takes place at given flow density .DELTA..tau..sub.2 excited in
ferromagnetic material at the frequency of electromagnetic
oscillations of f.sub.2.

[0074] The lenses of the space-time flows focusing are known
shaped as pyramid, cone, prism described in the monograph A. B.
, . , . , ., 2000r. (A. V. Kinderevich, L. I. Kicha, FIELD
THEORY. ELEMENTS OF NUMBERS THEORY, Kyiv (2000)). We could not
find the most close as to their technical essence apparatuses.

[0075] The proposed apparatus for radioactive material
treatment 102 (see FIGS. 1, 2, 3, and 4) serves for changing of
intensity of physical processes in the local region 220. The
elements of the apparatus shaped as prisms 206 as well as cones
216 and 218 formed of ferromagnetic are surrounded by the
electrodes 202, 204, 208, 210, 212, and 214. These elements
create and focus the flows of space-time, which facilitate
acceleration or deceleration of physical processes in the local
region. The energy of the external electromagnetic field is
absorbed in the elements of the apparatus 102; in this process,
spins of ferromagnetic are oriented so that it emits powerful
flows of structurization, .DELTA..tau..sub.1, or
destructurization, .DELTA..tau..sub.2. Diagram of the flows
.DELTA..tau..sub.1 summation is presented in FIG. 4. The
specified flows in the local region of the apparatus 102 change
the magnitude of the Hubble number and in this way facilitate
intensification of the process of radioactive decay of the
radioactive material enclosed in the container 222.

**Processing Time Sequence at Embodiment of the Method
Together with the Apparatus for its Realization**

[0076] The container 222 with highly active radioactive waste
is loaded into the inner cavity of the apparatus 102 through the
cylindrical hole in the second end element 218; and then the
adjustable generator of electromagnetic oscillations 104 is
turned on. The frequency is set to the frequency of
structurization, f.sub.1, at which decrease of intensity of
alpha, beta, and gamma radiation begins as monitored by the
instruments 106 located directly in the container 222. When the
threshold magnitude of the activity is reached, the generator
104 is turned off, and the container 222 with radioactive waste
is removed from the inner cavity of the apparatus 102.

[0077] In the case of treatment of nuclear power plants fuel
elements, which have passed the stage of activity decrease, they
are removed from the container 222 and fragmented or ground into
smaller pieces. This provides for the possibility of selecting
of the amount of radioactive material, which excludes occurrence
of chain reaction when treated at the frequency f.sub.2.

[0078] After the specified procedure, the container 222 with
low active wastes enclosed in it is loaded into the inner cavity
of the apparatus 102 for the second time. The adjustable
generator of electromagnetic oscillations 104 is turned on; the
frequency of destructurization, f.sub.2, is selected, at which
activity of the radioactive material somewhat increases, but
then irreversible decrease of intensity of alpha, beta, and
gamma radiation begins, which is monitored by the instruments
106 located directly in the container 222. When the activity
value reaches the magnitude of the environment background, the
generator 104 is turned off, and the container 222 with
deactivated radioactive wastes is removed from the inner cavity
of the apparatus 102 for usage in other ecologically safe
technological processes.

[0079] The present invention has been described above with
reference to a preferred embodiment. However, those skilled in
the art having read this disclosure will recognize that changes
and modifications may be made to the preferred embodiment
without departing from the scope of the present invention. These
and other changes or modifications are intended to be included
within the scope of the present invention, as expressed in the
following claims.

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