RU2180141C1 - Method and device for magneto-nucleonic catalysis - Google Patents

Abstract

FIELD: various fields of nuclear physics and technology. SUBSTANCE: invention is related to magneto-nucleonic catalysis using magnetically charged elementary particles for converting chemical elements and their compounds with aid of electromagnetic and corpuscular radiation by interaction with magnetically charged particles and integration with them followed by disintegration of nuclear-bonded nuclear structures; it may be also used for nuclear (nucleonic) power plants and methods for generating electrical, magnetic, and thermal energy using reactions of magneto-nucleonic catalysis. To this end chemical elements are acted upon by catalyzing agent in the form of magnetically charged elementary particles. In the process nuclear structure of chemical elements undergoes nucleonic transformation and steady state of magnetically charged elementary particles is attained with nuclei of source chemical elements. Chemical elements and their compounds are transformed into other chemical elements and their compounds this transformation being accompanied by nuclear fusion and disintegration. Monopoles and dions are used as magnetically charged elementary particles. Device implementing this method has at least one of its modules used as means for acting upon chemical elements and their compounds with magnetically charged elementary particles. Such module may be made in the form of facility functioning to interrupt current through at least one circuit conductor in response to variations in current flowing through conductor. Conductor is placed in insulating medium wherein breakdown voltage is higher than highest voltage across any of circuit conductors. EFFECT: provision for transforming chemical elements and their compounds and for developing new technologies for producing chemical elements and generating energy. 31 cl, 43 dwg

Description

 The method and device for the implementation of magnetic nucleon catalysis (MNC) using elementary particles with a magnetic charge simultaneously relate to several areas of nuclear physics and technology, namely: the conversion of chemical elements - methods and devices for converting chemical elements and their compounds using electromagnetic and particle radiation by interacting with particles with a magnetic charge, combining with them and subsequent decay of nucleon-bound nuclear structures and to nuclear (and nucleon) energies eskim settings - methods and devices for producing electrical, magnetic and thermal energy by energy release in MNC reactions.

 The method and device of MNCs can be used, in particular, for transforming chemical elements and their compounds and creating new technologies for producing chemical elements, for generating energy and creating new technologies for generating energy, and for changing the physical and chemical properties of chemical elements.

 Using the capabilities of nucleon catalysis using elementary particles with a magnetic charge, implemented by the claimed method, due to the remarkable properties of elementary particles with a magnetic charge and its industrial suitability, it seems today unlimited.

 The described method and device have no analogue. Currently unknown methods for implementing magnetic nucleon catalysis using elementary particles with a magnetic charge, as well as devices for implementing this method. Nucleic catalysis with the help of other elementary particles is realized exclusively in laboratory conditions, in single processes and is not industrially suitable.

 The existence of similar technical devices does not mean compliance with this purpose - the implementation of the proposed method.

 The question of the existence of a magnetic charge (a single magnetic pole - S or N), the carrier of which is a stable elementary particle with a magnetic charge - a magnetic monopole - has long been posed to modern physics and is of interest to scientists and researchers.

 On the problem of the magnetic monopole, numerous authors have written more than two hundred works, mainly theoretical. Such significant interest is explained by the fact that the confirmation of the physical existence of the magnetic monopole, predicted at one time by the theoretician of quantum physics Paul Dirac, will lead to a change in the current understanding of the electromagnetic field, to the requirement that new sources - magnetic charges and currents - be introduced into the Maxwell equation and will be reflected over the entire monumental building called field theory.

 In 1931, Paul Dirac, based on the requirement of symmetry between electricity and magnetism, hypothesized the existence of an elementary magnetic charge - a magnetic monopole [1]. According to this hypothesis, a magnetic monopole is an elementary particle that is a carrier of a single magnetic charge - pole S or N.

 Particularly known particles having magnetic properties have north and south magnetic poles and, accordingly, are dipoles. Attempts to experimentally confirm the existence of a magnetic monopole have not stopped for almost seventy years. The detectors used to detect magnetic monopoles (direct detection) can be divided into two classes [10]: induction detectors using the principle of detection based on the phenomenon of electromagnetic induction, and detectors recording the interaction of a magnetic monopole with matter.

 Separate evidence of successful registration of the magnetic monopole appeared, but the only candidate for the role of the monopole was obtained in February 1982 under the leadership of Cabrera [7]. At the same time, it is known that his experiments could not be reproduced, which casts doubt on these results. All other attempts to experimentally confirm the existence of magnetic monopoles, and even more so to obtain these particles, failed [6, 7, 8, 9].

 The development of a theoretical justification for the existence and description of a magnetic monopole as an elementary particle with a magnetic charge — S or N poles — is based on the following mathematical conclusions and modern theories.

The study of the quantum-mechanical motion of an electric charge in the field of the magnetic pole led to the quantization condition: g = e • (137/2) • k, where e is the electric charge, k is an integer, and k = ± 1, ± 2, ± 3 ,. .. In the Schwinger model [2], the Dirac concept was extended to the relativistic region and it was shown that under quantization conditions only even values of k are allowed. Thus, it was established that the charge of the magnetic monopole is quantized and determined. The mass value from this model does not follow. In 1969, Schwinger [12], on the basis of ideas about fractional electric charges and qualitative symmetry between electric and magnetic charges, suggested that “hadron matter” should be considered as magnetically neutral formations of doubly charged particles - dyons. Nucleons, therefore, must consist of combinations of such particles that take into account various types of hadrons - mesons and baryons, as well as their antiparticles. In this regard, the electric and magnetic charges are multiples of: e ₀ = 1 / 3e, g ₀ = 1 / 3g, where e is the electric charge, g is the magnetic charge, e ₀ is the elementary electric charge, g ₀ is the elementary magnetic charge.

A new impulse in the development of theories of magnetic monopoles was given by the works of 't Hooft [3] and Polyakov [4]. They showed that magnetic monopoles necessarily arise in some theories of gauge fields. In non-Abelian gauge theories with spontaneously broken symmetry, there are stable classical solutions with finite size, energy, and nonzero magnetic charge. The mass of the magnetic monopole in these models is much larger than previously assumed and is expressed through the mass of the intermediate boson: m (M) = m (w) / 2≈5 TeV, where m (M) is the mass of the magnetic monopole and m (w) is mass of the intermediate boson. Magnetic monopoles in these theories are also very massive, and their mass significantly exceeds the energy at which the Great Unification sets in. In this regard, it is believed that magnetic monopoles cannot be created in modern accelerators. According to modern theories in models of the Great Union, magnetic monopoles should arise as topological space-time defects, when the gauge group spontaneously breaks and the abelian group U (1) first appears - subgroup: SU (5) _ → SU (3) ⊗SU (2 ) ⊗U (1).
In 1988, Matveev and Rubakov [11] determined that the simplest (fundamental) monopole should have a color hypercharge: both an ordinary magnetic charge and a color magnetic charge. The mass and size of the core of such a magnetic monopole are determined by the scale of the Great Unification: m (M) ~ (1/137) • (M _x ^-1 ~ 10 ¹⁶ GeV, r (M) ~ M _x ^-1 ~ 10 ^-28 cm, where M _x is the massive vector boson X of the SU (2) group and is equal to ~ 10 ¹⁴ GeV, m (M) is the mass of the magnetic monopole, r (M) is the radius of the core of the magnetic monopole. Back in 1981, Rubakov in his work [5] noted that catalyzes the breakdown of a magnetic monopole nucleons:. M + p_ → M + μ + + hadrons This decay predict Grand Unified theory.

 The nuclear reaction in its entirety is a process that begins with the collision of at least two elementary particles and proceeds, as a rule, with the participation of strong or weak interactions. In this case, particles are born and absorbed - synthesis and decay of chemical elements and their compounds occur. Accordingly, there is a combination of these two processes, which we can call the transformation of one particle into another.

In December 1942, Fermi succeeded in triggering the first nuclear chain reaction - fission of uranium nuclei: n + ²³⁵ U -> ¹⁴⁰ Cs + ⁹³ Rb + 3n + 200 MeV (0.85 MeV / nucleon). The nuclear fission process has received technical application in the form of an energy source and radioactive isotopes. A major drawback of nuclear fission and decay processes is the high radioactivity of fission products and the limited number of possible reactions.

Nuclear fusion was first carried out under laboratory conditions as early as the thirties. But it has a big drawback in technical implementation. Nuclear fusion is carried out only at very high temperatures in thermonuclear reactions, for example: ² H + ² H -> ³ He + n + 3.2 MeV and ² H + ³ H -> ⁴ He + n + 17.6 MeV (3, 52 MeV / nucleon). At modern JET nuclear fusion research facilities in 1991 in England and TOKAMAK in December 1993, 1.7 and 5.6 MW were obtained in the United States, which was much less than the energy expended. At the moment, nuclear fusion does not yet have technical applications due to the high energy costs of obtaining very high temperatures - more than 100,000 ^o C and the supply of currents with a value of millions of amperes to create magnetic fields to hold hot plasma in the reactor. The advantage of thermonuclear fusion lies in the unlimited reserves of fuel - deuterium in the marine oceans.

In a 1957 experiment in Berkeley led by Alvarez, the phenomenon of catalysis of nuclear reactions in hydrogen by μ mesons was discovered. This nuclear fusion occurs under cold hydrogen conditions and was theoretically predicted by Frank [19], Sakharov [20] and Zel'dovich [21]: p + d + μ (_ → pdμ) _ → ³ He + μ.
But this catalysis cannot get technical application, since the probability of nuclear fusion in cold hydrogen is low and the energy yield of the reaction will not cover the energy costs for creating mesons at accelerators. Cosmic ray mesons are practically ineffective due to their low intensity. In this regard, muon catalysis is used only for the study of nuclear transitions, etc.

In 1988, Matveev and Rubakov [11], within the framework of the Great Unification Theory, showed that in fermion – nucleon interactions, monopoles act as a catalyst. In the process of scattering of s-wave fermions in monopoles with non-conservation of the fermion number, the quantum numbers of condensates from SU (2) _M correspond to the processes of monopole catalysis of nucleon decay: p + M -> e ⁺ + M (+ pions) and n + M_ → e ⁺ + π ^- + M (+ pions). There are also processes with violation of the baryon number. The quantum numbers of this process> correspond to the reaction: p + M -> ^1/2 e ⁺ + ^1/2 p + M. The wave function of the final state is interpreted as a linear superposition of the proton and positron, i.e. the process effectively describes two reactions: p + M -> e ⁺ + M and p + M -> p + M.

The inclusion of fermions of the following generations leads to the appearance of other, additional channels of monopoly catalysis of proton decay [22]: p + M_ → e ⁺ + μ ⁺ μ ^- + M, p + M_ → μ ⁺ + K ^° + M and p + M_ → μ ⁺ + K ⁺ + π ^- + M.
Assessing the monopoly catalysis cross section is a very difficult task. The problem is the combination of large, intermediate and small distances (r >> 10 ^-13 cm, r ~ 10 ^-13 cm and r << 10 ^-13 cm) between the monopole and the nucleon. And the non-conservation of the baryon number depends on this.

 In [13], Korshunov in 1991 showed that the slow drift of a monopole in air coincides with the average physical parameters of ball lightning, and it is essentially a phenomenon of nucleon decay involving a catalyst — a monopole.

 The subject of the present invention is the creation of a method and device for the targeted implementation of OLS using elementary particles with a magnetic charge for versatile practical use in industry and everyday life, as well as for further scientific research. Perhaps this will make it possible to understand the structure of the construction of chemical elements, the nature of strong and weak interactions, and require its own, new description in the theory of interactions, modification of CPT theorems for the introduction of magnetic conjugation.

 The method of OLS in accordance with the present invention consists in the fact that chemical elements and their compounds are exposed to a catalyst - elementary particles with a magnetic charge.

 The MNC method in accordance with the present invention is characterized in that the number of nucleons in the nuclei of the chemical elements and their compounds is changed.

 The MNC method in accordance with the present invention is characterized in that they transform the starting chemical elements and their compounds into other chemical elements and their compounds.

 The OLS method in accordance with the present invention is characterized in that energy is obtained in the form of kinetic energy of elementary particles with magnetic charge and heat.

 The MNC method in accordance with the present invention is characterized in that the physical properties of chemical elements and their compounds are changed.

 The MNC method in accordance with the present invention is characterized in that in order to obtain the necessary and sufficient amount of elementary particles with a magnetic charge and to create conditions for the implementation of the MNCs according to the present invention, a method for producing elementary particles with a magnetic charge is used, characterized in that in an electric circuit, consisting of at least two conductors placed in a dielectric medium, the breakdown voltage of which is higher than the maximum voltage on any of these conductors to interrupt an alternating current in one of these conductors.

 It is advisable in some cases, the method of OLS according to the claimed invention is carried out simultaneously with the method of producing elementary particles with a magnetic charge.

 The method of OLS according to the present invention is characterized in that the starting material for the transformation of chemical elements and their compounds are conductors placed in a dielectric medium. It is advisable to use electrical circuit conductors intended for electrical explosion as starting material.

 The inventive MNC method according to the present invention is characterized in that additional solids, liquids and gases can also be used as starting material. In some cases, it is advisable to add the source material to the dielectric medium.

 The OLS method according to the present invention is characterized in that the source material for transforming the chemical elements and their compounds is a dielectric medium.

 The inventive method is also characterized by the fact that through the conductors that make up the electrical circuit, it is advisable to pass an alternating or pulsed current and interrupt it by electric explosion of one of the conductors at the time the current value changes in time.

 In order to increase the efficiency of the process and obtain the desired results according to the claimed method, it is advisable to arrange the conductors in parallel and pass at least two current conductors of the electric circuit in opposite directions or arrange them at an angle to each other, and changing this angle in the range from -180 to + 180 degrees allows you to adjust the qualitative and quantitative indicators of the process of transformation of chemical elements and their compounds and energy. In some cases, it is advisable to use more than two conductors and arrange them in such a way as to ensure the location of the conductors specified above, and electrical explosion of all conductors intended for this.

 In order to increase the efficiency of the process and obtain the desired results according to the claimed method, it is advisable to interrupt the current in the conductor at the time of maximum current rise rate.

 In order to control the OLS process, it is advisable to carry out both conductors and source material from the same and different chemical elements or their compounds.

 In order to increase the efficiency of the process and obtain the desired results according to the claimed method, it is also advisable to use conductors of such sizes and with such sections that the current interruption is performed at optimal energy consumption, and the amount of energy expended, as well as the current rise rate, amount and composition of the starting material, composition and the physical properties of the dielectric medium make it possible to control the qualitative indicators and the quantitative yield of the MNC process.

 In accordance with the claimed method, solids, liquids and gases can be used as a dielectric medium. In some cases, it is advisable to use ordinary or distilled water.

 The inventive method is also characterized in that the dielectric medium is placed in a closed volume.

 In accordance with the claimed method, an additional effect on the qualitative and quantitative characteristics of the MNC process can be obtained by sealing a closed volume. In some cases, it is advisable to interrupt the current in the electric circuit at an increased pressure in a closed volume, as well as at an elevated temperature of the dielectric medium.

 A device for implementing the inventive method of OLS using elementary particles with a magnetic charge in accordance with the present invention contains a power source, a switching device with an external trigger and a reactor.

 The inventive device is characterized in that the reactor consists of a unit for the formation of elementary particles with a magnetic charge, which contains a dielectric medium, placed in it at least two electrically connected conductors of the electric circuit, which is the load for the power source.

 It is advisable in some cases in the inventive device as a reactor to use a unit for the formation of elementary particles with a magnetic charge.

 The inventive device is characterized in that a dielectric medium is formed in the unit for forming elementary particles with a magnetic charge so that its breakdown voltage is higher than the highest voltage at any point on the conductors of the electric circuit.

 It is advisable for the implementation of the inventive device MNC using elementary particles with a magnetic charge in accordance with the present invention to use additional source material and place it in the reactor.

 It is advisable to use a device for spatial limitation of the dielectric medium in the unit for forming elementary particles with a magnetic charge, if liquid or gas is used as it. In some cases, it is advisable to use a camera for the spatial limitation of the dielectric medium.

 The inventive device is characterized in that as a power source can be used a source of alternating or pulsed voltage.

 In order to increase the efficiency of the device in accordance with the present invention, the chamber filled with a dielectric medium is a sealed chamber equipped with pressure and temperature controllers of the dielectric medium.

 The inventive device is characterized in that it contains means for changing and fixing the spatial arrangement of the conductors of the electrical circuit relative to each other by rotating the conductors relative to each other along the x and y axes relative to z by angles in the range from -180 to +180 degrees.

 The device in accordance with the present invention is also characterized in that the conductors of the electric circuit can have various geometric shapes and cross-sections, and the conductor, which is intended for electric explosion, can be made in the form of foil, wire or liner. Conductors can be made of various chemical elements or their compounds.

 The inventive method and device illustrate the following materials.

 Figure 1 - block diagram of the algorithm for producing elementary particles with a magnetic charge.

 FIG. 2 is a functional block diagram of a device for implementing a method for producing elementary particles with a magnetic charge.

 Figure 3 and figure 4 - photographs of a spherical light discharge that occurs during the implementation of the proposed method after 1 ms and 7 ms after an electric explosion.

 FIG. 5 is a photograph of bremsstrahlung occurring in air after an electric explosion in the experiment of 11/18/98.

 6 is a photograph of the radiation of Vavilov-Cherenkov arising in the water leaving the chamber in the experiment of 11/18/98.

 FIG. 7 is a photograph of the optical spectrum of a spherical light discharge (plasma) in experiment 67 of 02/11/99.

 FIG. 8 is a photograph of a fragment of the ultraviolet spectrum of a spherical light discharge (plasma), consisting of a continuous and line spectra, with a standard (reference spectrum) of iron.

 Figa - photograph of the ultraviolet spectrum of bremsstrahlung in a dielectric medium behind filters 423 μm and 457 μm with a peak intensity during the existence of a plasma glow in experiment 82 from 02.27.99. The upper channel is inverted at a sweep time of T = 5 ms / division and a voltage of U = 5 V / division.

 Fig. 9b is a photograph of the ultraviolet spectrum of bremsstrahlung in a dielectric medium behind filters 423 μm and 457 μm until a spherical light discharge occurs in experiment 82 of 02.27.99. The upper channel is inverted at a sweep time of T = 0.1 ms / division and a voltage of U = 1 V / division.

Figure 10 - arrangement of photodetectors:
1 - place of an electric explosion of foils;
2 - lens;
3 - plate with a nuclear emulsion;
4 - film stacked in a stack;
5 - image intensifier tubes;
6 - film;
7 - PMT-35;
8 - interference filters;
9 - spectrograph ISM-51;
10 - spectrograph STE-1.

 FIG. 11a is a typical track obtained in a P-100 nuclear emulsion located at a distance of 100 cm from the axis of the device.

 FIG. 11b is a more detailed image of the track structure of FIG. 11a under a high magnification microscope.

 FIG. 12a, b and c are photographs of the track of the passage of the same particle on three fragments of the RF film located one after another.

 FIG. 13 is a photograph of a very long intermittent track resembling a tread track of a car tire.

 Fig. 14 is a photograph of a track resembling a track of a caterpillar.

Fig - experimental design for registration of secondary radiation of the sample:
1 - Petri dish;
2 - sample;
3 - film;
4 - fiberglass washer.

 Fig. 16 is a photograph of a fragment of a track obtained by secondary radiation of a sample.

 Fig - photograph of the diffuse glow of the entire space arising at the time of electric explosion (T = 0 ms).

 Fig. 18 is a photograph of an image intensifier tube obtained in the first 550 microseconds after a current pulse using an ultraviolet image intensifier tube.

FIG. 19, FIG. 20 and FIG. 21 are measurement results — plots produced using the Mossbauer effect for unirradiated ⁵⁷ Fe, southern (S) ⁵⁷ Fe, and northern (N) ⁵⁷ Fe, respectively.

 FIG. 22 is a mass analysis table for the elemental composition of an initial titanium foil. Weight is indicated as a percentage of the total weight.

 FIG. 23 is a table of mass analysis of the isotopic composition in the initial titanium foil. Weight is indicated as a percentage of the total weight.

 Fig.24-Fig.27 - photographs of the samples.

 FIG. 28 is a mass analysis table for the elemental composition of the sample 170. Weight is indicated as a percentage of the total weight.

 FIG. 29 is a mass analysis table for the elemental composition of the sample 170. Weight is indicated as a percentage of atomic weight.

 Fig. 30 is a mass analysis table of the titanium isotopic composition in sample 196. Weight is indicated as a percentage of the total weight.

 FIG. 31 is a table of mass analysis of the elemental composition of the sample 169. Weight is indicated as a percentage of the total weight.

 FIG. 32 is a mass analysis table for the elemental composition of the sample 169. Weight is indicated as a percentage of atomic weight.

 FIG. 33 is a mass analysis table of the titanium isotopic composition in sample 197A. Weight is indicated as a percentage of the total weight.

 Fig - table analysis of masses of the elemental composition of the sample 197A. Weight is indicated as a percentage of the total weight.

 Fig - table analysis of masses of the elemental composition of the sample 197A. Weight is indicated as a percentage of atomic weight.

 FIG. 36 is a table of the analysis of masses of the titanium isotopic composition in the sample 207р. Weight is indicated as a percentage of the total weight.

 FIG. 37 is a histogram of an averaged mass analysis of 169-240 for titanium. Weight is indicated as a percentage of the total weight.

 FIG. 38 is a mass analysis table for sample composition 226, 229, and 230. Weight is indicated as a percentage of the total weight.

 Fig.39 - analysis of the composition of the sample X25.

 Fig - analysis of the composition of the sample X27.

 Fig - analysis of the composition of the sample X22.

 Fig - analysis of the composition of the sample X23.

Fig - analysis of the ratios Z _out / Z _in .

 The algorithm of the proposed method MNC using elementary particles with a magnetic charge is presented in the block diagram of figure 1. According to the claimed invention it is necessary to act with elementary particles with a magnetic charge on the original chemical elements and their compounds. It is advisable to act under conditions created by the implementation of the method for producing such particles described below. In accordance with the inventive method, an electric circuit consisting of at least two conductors is placed in a dielectric medium, voltage is supplied to it from a power source by an external start of a switching device, and current is interrupted by electric explosion in one of these conductors. To carry out an electric explosion in an appropriate conductor, it is necessary to interconnect the electrical characteristics of the power source, the switching device, the dielectric medium, the electric circuit consisting of cables, the conductors themselves and their electrical connections. Moreover, the set of characteristics provides electrical explosion of the conductor in such a way that it occurs at the moment of maximum slew rate of the current value. As a dielectric medium, to ensure the necessary interactions, a material is used whose breakdown voltage is higher than the maximum voltage on any of the conductors that make up the electric circuit. Elementary particles with a magnetic charge in an amount recorded and sufficient for their further use were repeatedly and stably obtained using, in particular, various dielectric media, at different temperatures of the dielectric medium, two or more conductors of the electric circuit, using the same and different materials , as well as the geometric shapes of conductors, various rates of change of the current value at the time of electric explosion and various energy capacities of the power source. Simultaneously with the production of elementary particles with a magnetic charge, they controllably interact with the starting material, which can be conductors of an electric circuit, a dielectric medium and chemical elements placed in a dielectric medium and their compounds, depending on the totality of conditions created in the process of obtaining these elementary particles with a magnetic charge .

 To implement the method of OLS using elementary particles with a magnetic charge, it is advisable to use a device whose block diagram is shown in figure 2. The device comprises a power source 1 and a reactor 15. It is expedient to carry out the reactor 15 in the form of a unit for forming elementary particles with a magnetic charge 3 connected via cables 4 and a switching device 2 with a power source 1. The unit for forming elementary particles with a magnetic charge can be a chamber filled dielectric medium 5, and contains at least one current interruption module 6, including an electrical circuit 7, consisting of at least two conductors 8 and 9 (a conductor designed for For electric explosion). The position of the conductors of the electric circuit is changed and fixed using standard elements and mounting principles 10. Cables 4 are connected using standard connectors 11 to the electric circuit 7 of the current interruption module 6. The current interruption module 6 is attached with standard fasteners 12 to the unit for forming elementary particles with a magnetic charge 3 so that the electrical circuit 7 is inside the dielectric medium 5. The device may include means for adjusting the pressure 13 in the dielectric medium, which can be Filled as a reversible pump. The device may include means for adjusting the temperature 14 in the dielectric medium, which can be made in the form of a thermocouple or other heating device.

 As a power source 1 in the inventive device can be used a capacitor bank. The energy reserve at a voltage of U = 4.8 kV is W = 50 kJ. Battery switching can be carried out using a conventional thyratron spark gap with external start 2. Energy is transported via cables 4 of electric circuit 7, which can be coaxial cables. Conductors 8 and 9 are interconnected in series. The conductor intended for electric explosion 9 is performed, for example, in the form of a foil, the material whose shape and cross section is selected based on the combination of all other electrical properties of the elements and units of the device.

The inventive device operates as follows. After the supply voltage of the power source 1 using the switching device 2 to the electrical circuit 7 through the cables 4 and conductors 8 and 9, current flows. Upon reaching the necessary and sufficient current density in the conductor 9, an electric explosion occurs in it. With electrical explosions in conductors, current densities of the order of 10 ⁶ -10 ⁷ A / cm ^{2 are} achieved. At the time of electrical explosion of the conductor 9, the current in the electrical circuit is interrupted and there is a registered and sufficient for further use the number of elementary particles with a magnetic charge.

 The following physical diagnostics were used to identify and confirm the reliability of the existence of elementary particles with a magnetic charge.

 1.) Registration of tracks of elementary particles with a magnetic charge.

For this purpose, an RF-ZMP fluorographic film with a sensitivity of 1100 r ^-1 according to the criterion of 0.85 over the veil, a medical radiographic film of RM-1MD with a sensitivity of 850 r ^-1 according to the criterion of 0.85 over the veil, nuclear photographic plates of type P with the thickness of the emulsion layer is 100 μm, high resolution IAE photoemulsions with a sensitivity of ~ 0.1 units GOST and resolution up to 3000 lines / mm, photo paper.

After irradiation, all materials appeared in the corresponding developers: fluorographic films in the D-19 developer for 6 minutes. At a temperature of 20 ^o With the plate in the phenidone-hydroquinine developer isothermal method.

 In the study of processed photographic materials, macro- and microeffects were discovered. Macro effects were considered those that can be viewed with the naked eye, as well as under a magnifying glass with a magnification of ~ up to 5 times. Micro effects were considered those effects that are visible when magnified from 75 to 2025 times.

 Photo detectors were placed at various distances from the center of the device - from 20 cm to 4 m and were located in radial and normal planes with respect to the axis of the device (Fig. 10). Films and plates with a nuclear emulsion were wrapped in black paper. The paper was checked for integrity before packaging of films and plates and before development.

The sizes and lengths of the observed tracks in a nuclear photoemulsion are unusually large. A typical track, the photograph of which is shown in Fig. 11a, was obtained in a P-100 nuclear emulsion located at a distance of 100 cm from the axis of the device. From the photograph in FIG. 11 a, it can be seen that the radiation is substantially corpuscular in nature. An energy estimate made from the geometrical dimensions of the track under the assumption that the particle’s drag mechanism is Coulomb's gives E ~ 1 GeV. Obviously, given the location of the plate with the nuclear emulsion and the size of the track, it is impossible to attribute the track to either α, β, or γ (recall that the nuclear emulsion is located in the atmosphere). A more detailed study of the track structure under a microscope with strong magnification (Fig. 11b) made it possible to distinguish a round “head” with a blackening density γ> 3 and a long train with a decreasing density resembling a comet’s tail. On this plate with a nuclear emulsion on an area of 4 cm ^{2 there} are 6 "comets". Their sizes range from 300 to 1.300 microns. Another photodetector was used, consisting of three X-ray films of the Russian Federation folded and fixed relative to each other, wrapped in black paper. The films were located at about the same place as the nuclear emulsion. From the photographs presented in figa, b and c shows that the blackening coincide and this does not make it possible to attribute them to artifacts. Estimation of the absorbed energy in three films, taking into account the emulsion layer thickness of 10 μm, grain size of 1 μm, and photosensitivity, yields E ~ 700 MeV, which coincides with the estimate of the track from the photograph in Fig. 4a.

 During the manifestation of a nuclear emulsion, it was determined that its blackening began from the side of the glass plate. This means that the radiation released most of the energy at the interface between glass and nuclear photoemulsion. This is confirmed by the subsequent processing of photographic plates under a microscope with a strong increase (2025 times) by scanning through the thickness of the emulsion. The same effect was observed on the plates, which during operation of the device were stacked with glasses to each other and were located in a normal plane with respect to the axis of the device. This suggests that the observed radiation exhibits the property of transition radiation.

 Very long (~ 5 mm) discontinuous tracks were also recorded, resembling a track of a caterpillar or tire tread of a car wheel, shown in the photographs of Figs. 13 and 14. This type of tracks is characterized by the presence of a second parallel track, which differs in blackening intensity and length from the main one. Evaluation of the energy density of blackening gives approximately the same order of magnitude determined from the tracks in the photographs of Fig.11 and Fig.12. Very remarkable was the fact that the remnants of water and foil material after an electric explosion (sample) after they were removed from the device’s chamber were the source of the same radiation that was recorded at the time of the electric explosion. The sample was placed in a Petri dish, and the film was set at a distance of 10 cm, as shown in the photograph of Fig. 15. The film was pressed by an emulsion to a fiberglass washer, since we have already noted that radiation exhibits the properties of transition radiation. The exposure time was ~ 18 hours. The result is shown in the photograph of FIG. From comparing the photographs in FIG. 13 and 16, it can be concluded that the causes of the blackening of the films are identical. This means that the radiation mechanism does not have an accelerator, but a nuclear origin. The second conclusion that can be drawn is that the reason leading to the appearance of tracks does not disappear after an electric explosion, but can be “accumulated”.

 The recorded tracks completely coincide with tracks of the caterpillar type predicted in [17]. Photographs of such tracks are shown in FIG. 13, 14 and 16. The energy estimate made in FIGS. 11 and 12 also coincides with the results of [16, 17]. The transitional nature of the radiation coincides with the results of [15].

 2.) Registration of bremsstrahlung and Vavilov-Cherenkov radiation.

 Based on the results of [14, 16], when registering elementary particles with a magnetic charge, one should expect intense bremsstrahlung in air and Vavilov-Cherenkov radiation when elementary particles with a magnetic charge enter water.

и временем экспозиции ~ 50 мксек. Над устройством прикреплено зеркало под углом 45^o к оси Z, что позволяет одновременно регистрировать две проекции свечения.To record the radiation, we used high-speed photographing using six electron-optical converters (EOPs) operating in a single-frame mode with an exposure time of ~ 100 μs and a delay of ~ 1 ms relative to each other. Image intensifier tubes are located at a distance of ~ 2.5 m, as shown in FIG. 10. In a number of measurements, the 7th, “sun-blind” ultraviolet image intensifier with a maximum spectral sensitivity in the region was used

and exposure time ~ 50 μs. Above the device is attached a mirror at an angle of 45 ^o to the Z axis, which allows you to simultaneously register two projections of the glow.

 To register the image, an industrial high-speed movie camera of the brand "IMAGE300 ALAN GORDON ENTERPRISES, INC" was used. The camera allows you to register 300 frames per second with a frame exposure time of ~ 2 ms. To synchronize the camera, special quartz watches were developed.

 To register the radiation intensity over time, photodiodes and photoelectronic multipliers (PMTs) were used. Two PMT-35s with interference filters 423 nm and 457 nm with a spectral width of filters of 0.5 nm were located at a height of 1 m above the device. Photodiodes and other PMTs (ultraviolet PMT-142, PMT-97 with a λ = 43 nm filter) were located in a horizontal plane at various distances from the device.

 To determine the spectral composition of light radiation in both the optical and ultraviolet regions, spectral analysis was performed using two standard spectrographs. Optical spectra were recorded with an ISM-51 instrument, and ultraviolet spectra were recorded with STE-1.

After the electric explosion of the foil, a luminescence is fixed over the unit for the formation of elementary particles with a magnetic charge: at the time of the electric explosion, a diffuse glow appears, as it were, of the entire space (Fig. 5 and Fig. 17), and then a glow (Fig. 3 and Fig. 4) appears, very similar on the phenomenon of ball lightning. The installed mirror made it possible to simultaneously register two glow projections. The photographs in FIG. 3 and FIG. 4 were obtained using two of the six image intensifier tubes, and they show that the glow has a spherical shape. The spherical glow is plasma and exists for at least about 7 ms. The luminescence intensity was recorded over time using photoelectronic photodiode multipliers located at different distances from the setup. From the analysis of the oscillograms and photographs obtained by the image intensifier tubes in various time modes of operation, it follows that the duration of the spherical glow of the plasma is tens of milliseconds, while the duration of the operation of the capacitor bank is only ~ 100 μs. In order to verify the impossibility of electrical breakdown on the electrodes, a static control voltage U = 25 kV was applied. During the operation of the device, no traces of breakdown were detected by air or by dielectric. Thus, the existence of a spherical plasma glow for such a long time cannot be explained by any breakdown between the electrodes. The spherical glow is ~ 15 cm in diameter, there are tens of milliseconds and then "crumbles" into small luminous formations, as shown in the photograph of FIG. 4. The photograph of FIG. 18 shows an EOPogram obtained in the first 550 μs after the start of a current pulse using an ultraviolet EOPA. From the photograph of FIG. 18 it can be seen that in the ultraviolet region there is also no image, as in the photographs of FIG. 5 and FIG. Comparison with the signals obtained with a PMT-35 (λ ₁ = 423 nm, λ ₂ = 457 nm) allows us to interpret the pre-pulse on the waveform of FIG. 9b as the bremsstrahlung of flying elementary particles with a magnetic charge, and the main pulse on (figa) - as the radiation associated with a spherical glow. This interpretation is confirmed by spectral measurements. Figures 7 and 8 show sections of the optical and ultraviolet spectra. It can be seen from the figures that, in addition to the spectral lines, there is simultaneously a continuous part of the spectrum (continuum), which confirms the presence of bremsstrahlung.

 It should be noted that the very fact of the existence of "ball lightning", as follows from the work of Korshunov [13], is the result of the formation of elementary particles with a magnetic charge. The fact of the existence of Vavilov-Cherenkov radiation, arising due to the movement of elementary particles with a magnetic charge in a dielectric medium, follows from the photograph of Fig.6, obtained using a high-speed camera. The photograph shows the glow of water being sprayed from the unit for the formation of elementary particles with a magnetic charge of the device. To obtain this frame, the camera was made in the form of an open tank and plate. The plate was laid on the tank and not specially sealed.

 To confirm the hypothesis of obtaining elementary particles with a magnetic charge, the magnetization effect was measured, followed by analysis using the Mossbauer effect, since an attractive force must exist between the monopole and the ferromagnet. Based on the work of Khakimov and Martinyanov [18], in the case of particles with a magnetic charge, they should be absorbed by iron foils.

For this experiment, 3 foils of ⁵⁷ Fe were used. ⁵⁷ Fe has an ideal structure and a significant field at the core. Two foils were placed at different poles of a strong magnet with a magnetic field strength of about 1.2 KG and were located at a distance of about 70 cm from the place of electric explosion, and the third foil was used as a reference, without the influence of a magnet. After irradiation with elementary particles with a magnetic charge resulting from electric explosion, the flux of these particles should be equally distributed at the N- and S-poles, they would be compensated in the reference foil, and on the other two foils they should split into N- and S - poles of a magnet. This cleavage can be recorded and evaluated using the Mossbauer effect.

 The measurement results are shown for the reference Fe in Fig. 19, for the southern (S) Fe in Fig. 20, for the northern (N) Fe in Fig. 21.

 In foils placed at the N-pole, the absolute value of the hyperfine magnetic field increased by 0.24 kg. On the other foil (S), it decreased by about the same amount, 0.29 kg. Error = 0.012 kg.

Fe - reference: H _n = 330.42 kg
Fe - northern N Н _n = 330.66 kg, Δ _N = 0.24 kg
Fe - southern S Н _n = 330.13 kg, Δ _S = -0.29 kg
Given the fact that the magnetic field in ⁵⁷ Fe has the opposite sign with respect to the direction of its magnetization, it can be confidently stated that S particles (at the N-pole of the magnet) increase the negative hyperfine field, and particles of the opposite sign decrease it and this relative change the absolute value is ~ 8 • 10 ^-4 .

 Such a fact is known that when analyzing the Mössbauer spectra of ferromagnets, a broadening of the absorption lines is noted. This phenomenon is associated with the heterogeneity of the internal magnetic fields at the nuclei. An analysis of the spectra of irradiated foils revealed an additional broadening of the absorption lines, comparable in magnitude with ordinary magnetic broadening. This is probably due to the chaotic absorption of monopoles in the iron lattice.

 Error = 0.003 mm / s.

Fe - reference: r _i = 0.334 / 0.300 / 0.235 mm / s
Fe - northern - N: r _i = 0.363 / 0.328 / 0.250 mm / s
Fe - southern - S: r _i = 0.366 / 0.327 / 0.248 mm / s
The appearance of a quadrupole line shift, i.e. a change in the gradient of the electric field in the crystal is not observed.

Fe - reference: N ₀ = 126.465
Fe - Northern - N: N ₀ = 126.466
Fe - Southern - S: N ₀ = 126.470
This can be due to both the smallness (in comparison with the electron) of the electric charge of the monopole, and a high degree of symmetry of the iron lattice. The magnetic nature of the investigated radiation is unambiguous.

 Under the conditions created when obtaining elementary particles with a magnetic charge and determined by a combination of device adjustments, these elementary particles interact with the starting material and form bound states with the nuclei of the chemical elements and their compounds. Chemical elements and their compounds are transformed, forming new chemical elements and their compounds, changing the physical and chemical properties of chemical elements and their compounds, as well as releasing energy. Part of the source and obtained substance remains in the device chamber, and part leaves the device chamber in the form of a plasma, i.e. a spherical plasma glow occurs.

Due to the large magnitude of the magnetic charge, the constant of interaction of elementary particles with a magnetic charge becomes comparable with the constant of nuclear interaction: g ² / 2πhc = (137) ² [5, 16]. For this reason, magnetic-nucleon catalysis of nuclei is possible, with which elementary particles with a magnetic charge form bound states, which leads to the transformation of the nuclei of chemical elements and their compounds, to a change in the physical and chemical properties of chemical elements and their compounds, as well as the release of energy .

 To ensure the purity of experimental studies, the following measures were taken. All connectors for connecting high-voltage cables to the module for interrupting current, attaching conductors and additional source material, other fasteners and nodes inside and outside the chamber of the unit for the formation of elementary particles with magnetic charge were made of, for example, high-purity titanium. The result of mass spectrometric analysis of this titanium is shown in the table in Fig.22. The conductors of the electrical circuit were also made of this titanium. In experiments in which a foil of this titanium was used as a starting material, four times purified distilled water and its constituent elements H and O were used as a dielectric medium. A chamber consisting of a tank and a cover of polyethylene was used as a device for spatial limitation of the dielectric medium high pressure, its constituent elements C and N. Since the chamber was sealed with a polyethylene seal, and the lid was attached to the tank with titanium mounts, mass analysis of the cat These are shown in the table in FIG. 22, and during an electric explosion, the pressure in the chamber was obviously greater than the external atmospheric pressure (P> 1 atm), then no foreign substances could enter the chamber, i.e. into the reactor. Thus, all measures were taken to ensure the "purity" of experimental research.

 During the electric explosion, part of the water and the material of the starting material (the conductor blown up by the electric explosion) flew out from under the chamber lid, despite all the efforts made to seal the chamber. The water remaining in the chamber and the residues of the starting material, hereinafter referred to as the “sample”, were removed from the chamber with all the precautions taken when working with highly pure substances and were analyzed using various methods. Samples are obtained from the starting material in the form of crystals, wires, fibers, etc. Pictures of examples are shown in FIGS. 24-27.

 For example, when using titanium foil as the starting material in 33 experiments from a series of experiments 169 to 240, the following chemical elements were found in the samples: Na, Mg, Al, Si, Cl, K, Ca, V, Cr, Fe, Cu, Zn, Mo, Pb, C, F, P, S, Mn, Co, Ni, Zr, W. Their average quantitative distribution is shown in the histogram in Fig. 37. The identical composition of the elements is recorded using the spectral technique described above and also used in studies of the OLS process. The photographs of FIGS. 7 and 8 show optical and ultraviolet spectra, respectively. As a reference spectrum for the optical spectrum in Fig. 7, standard B-3 copper (Cu) and zinc (Zn) lamps were used, which were excited using a microwave field. An iron (Fe) high current arc was used as a reference spectrum for the ultraviolet spectrum. The results of deciphering the spectra in a comparison of two different methods allow us to make a completely natural conclusion: some of the initial and transformed substances leave the chamber and form a spherical plasma glow - "ball lightning".

It should be noted that the isotopic analysis of the starting material remaining in the sample - the chemical element titanium, carried out using mass spectroscopy, shows a change in the natural ratio between titanium isotopes. The natural isotopic composition and their weight ratio are shown in the table of FIG. 23. The titanium isotopic composition in samples 197A, 196, and 207p after MNC is shown in the tables of FIGS. 33, 30, 36, respectively. The decrease or increase in the specific mass content of the basic ⁴⁸ Ti leads mainly to an increase or decrease in the specific mass content of ⁴⁶ Ti, ⁴⁷ Ti, ⁴⁹ Ti and ⁵⁰ Ti in the sample, respectively. In samples 226, 229, 230, 231, 232, the specific gravity of individual isotopes obtained differs from the standard natural composition by 3.5 times. The starting elements were titanium, tantalum and tungsten. Similar results were obtained for other studied isotopes of chemical elements (for example, chromium, nickel, iron, molybdenum, lead). This circumstance allows the use of OLSs using elementary particles with a magnetic charge for the separation of isotopes.

 When analyzing samples, in order to avoid possible methodological errors, mass spectrometers of various manufacturers belonging to various organizations were used: the Institute of General and Inorganic Chemistry in Moscow, Moscow State University named after Lomonosov Military Academy of Chemical Protection in Moscow and the All-Russian Scientific Research Institute of Mineral Raw Materials in Moscow. For this purpose, the sample was divided into several parts and simultaneously analyzed in various organizations. No significant discrepancies were noted.

 In addition to mass spectroscopy, other methods of analysis were also used. The results of electronic sounding of sample fragments give a good agreement between the elemental composition and the mass spectra.

 For analysis of the samples, X-ray phase, X-ray structural and X-ray fluorescence analysis methods were also used. According to the elemental composition of the samples, all methods gave good agreement. In total, more than 100 samples were analyzed.

 It has been experimentally established that the transformation of elements occurs both with decreasing and increasing Z nuclei, which is equivalent to fission and synthesis relative to the initial chemical element. Thus, the transformation of nuclei, and, consequently, the fact of the occurrence of magnetic nucleon catalysis is proved.

 The degree of burnout of the initial chemical element, and therefore, the number of transformed nuclei, depends on the conditions created by the least-squares method. By appropriate selection of physical conditions, it is possible to achieve a different degree of burnout of the initial chemical element. The elemental composition of sample 170 is shown in the tables of FIGS. 33 and 34. In experiment 170, approximately 4% of the burn-out of the main element by specific gravity was realized. The elemental composition of sample 169 is shown in the tables of FIGS. 36 and 37. In experiment 169, approximately 8% of the burn-out of the main element by specific gravity was realized. The elemental composition of sample 197A is shown in the tables of Figs. 39 and 40. In experiment 197A, approximately 25% of the burn-out of the main element by specific gravity was realized. A comparison of the results of these samples shows that with an increase in the degree of burnout of titanium, the gamma of the obtained elements expands both in the direction of decreasing Z and in the direction of increasing Z. For other studied chemical elements, another gamma of the obtained elements is obtained with a similar dependence on the degree of burnout.

 On the example of experiments 226, 229 and 230 (Fig. 38) it is also shown that by changing the conditions of the least-squares method, a different degree of transformation of the starting material into certain elements is achieved. The degree of burnout of the starting element reaches more than 99%.

 The spectral composition of the nuclei formed as a result of the transformation is determined by the choice of the initial element and the dielectric medium. A comparison of the histograms shows that the set of elements resulting from the transformation according to the least-squares method, the spectrum and their percentage of the statistical weight are different for different starting materials.

During the transformation of the initial chemical element as a result of OLS, chemical elements and their compounds are formed both with a high specific percentage yield of more than ~ 1%, i.e. in macroscopic quantities, and with a low specific percentage yield, ~ 10 ^-2 %, i.e. microimpurities. The following data presents the results of the analysis of samples produced with an accuracy of γ = 10 ^-7 %. Analysis of 14 samples from 5 experiments 226, 229, 230, 231, 232 showed that, depending on the conditions of OLS, the following elements are obtained: Li, Be, B, Na, Mg, Al, Si, Ca, Sc, Ti, V, Cr , Mn, Fe, Co, Ni, Cu, Zn, Ga, As, Rb, Sr, Y, Zr, Nb, Ru, Pd, Ag, Cd, In, Sn, Sb, I, Cs, Ba, La, Ce , Pr, Nd, Sm, Gd, Tb, Dy, Tm, Hf, Ta, W, Re, Os, Ir, Pt, Au, Hg, Tl, Pb, Bi, Th, U. Other elements were also obtained in other experiments. , including: Cl, K, V, Mo, C, F, P and S. As a result of transformation, almost all chemical elements of the table of chemical elements are formed. Thus, the possibility of obtaining elements of the transition group, non-metals, earth metals, elements of the earth-alkali group, iridium-platinum group, including silver and gold, the group of lanthanides and rare-earth elements, as well as elements of the lactanoid group is proved.

 From the analysis (FIGS. 39, 40, 41 and 42) of samples, photographs of which are shown in FIG. 24, FIG. 25, FIG. 26 and FIG. 27, it can be seen that as a result of the transformation, compounds of chemical elements are also formed. These compounds of chemical elements form minerals. Thus, the possibility of obtaining minerals and aluminosilicates is proven.

Consider single-crystal samples of the obtained material. Depending on the technology for producing copper and the presence of impurities in it, the crystal lattice parameter changes. For the samples obtained, the copper parameter is slightly less than the usual value. This can be explained by the purity and absence of stresses in the crystal lattice. One can see the separation of the doublets α ₁ and α ₂ along the reflection plane (331) and (420). The presence of texture on one of the X-ray diffraction patterns characterizes a certain orientation of the grains in the crystal lattice. From literature data it is known that the crystal lattice parameter of silver is always constant and equal to 4.077 kX. For a sample of crystalline silver, the parameter exactly matches the ASTM pattern. The x-ray diffraction pattern shows good - clear interference lines without dispersion and stresses with a resolution of the doublets α ₁ and α ₂ along the (511) plane. Thus, the production of single-crystal chemical elements is proven.

As a result of the transformation of the original element, a spectrum of other elements is formed, as indicated above. For a qualitative analysis of the process, it is convenient to introduce the parameter of the average (taking into account the statistical weight) of the transformed core N _out . The dependence of N _out on the source core N _in for various source elements that were studied experimentally is shown in Fig. 43. The curve in Fig. 43 was obtained as a result of computer processing by the least squares method based on data from mass spectral analysis of more than 100 samples. From Fig. 43 it can be seen that, up to the inevitable errors, the ratio N _out / N _in is linear.

As a result of studies of the OLS process, it was found that a change in the properties of chemical elements is possible. So, for example, it is possible to change the magnetization of chemical elements. The proof of this is the registration of changes in the hyperfine magnetic field in ⁵⁷ Fe foils using the Mossbauer effect. In the process of OLS, due to the irradiation of the initial substance with elementary particles with a magnetic charge, it is possible to create magnetic fields on the nuclei, obviously not magnetic, of chemical elements. Proof of this are magnetized samples of titanium and lead.

From Fig. 43 it can easily be understood that, depending on the starting element, due to the least-squares method, a difference in the binding energy of the starting chemical element E _in and the resulting middle element E _{out⌀ arises} . This difference ΔE, which is different for different initial elements, can serve as a source of energy. The cross section of this process also depends on the degree of burnout of the initial element. Thus, the use of magnetic nucleon catalysis for energy production is proven.

 All obtained experimental data have natural and well-consistent explanations within the framework of the hypothesis of the appearance of elementary particles with a magnetic charge. From the analysis of the available theoretical justifications it follows that elementary particles with a magnetic charge should lead to the physical phenomena described above.

 Studies conducted on the basis of experimental data obtained in more than two hundred experiments over two years convincingly show that the implementation of the inventive method and device leads to the formation of stable elementary particles with a magnetic charge and these results cannot be attributed to artifacts. And despite the fact that the physical essence of many phenomena that accompany their production is not yet fully understood, the nature of the particles obtained, their physical properties leave no doubt that these elementary particles have a single magnetic charge - pole N or S.

Sources of information
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Claims (31)

 1. The method of magnetic-nucleon catalysis, characterized in that the chemical elements and their compounds are affected by a catalyst - elementary particles with a magnetic charge for nucleon conversion of the nuclear structure of chemical elements, while creating stable states of elementary particles with magnetic charge with the nuclei of the original chemical elements and their compounds and transform them into other chemical elements and their compounds, and the transformation is accompanied by processes of nuclear transformation - nuclear fusion and decay.  2. The method according to p. 1, characterized in that they receive energy, chemical elements, compounds of chemical elements, isotopes of chemical elements, minerals.  3. The method according to p. 1, characterized in that they receive highly pure chemical elements, their compounds and isotopes.  4. The method according to p. 1, or 2, or 3, characterized in that the properties of chemical elements, their compounds and isotopes are changed.  5. The method according to p. 1, or 2, or 3, or 4, characterized in that the receive elements with a single crystal structure.  6. The method according to p. 1, or 2, or 3, or 4, or 5, characterized in that magnetic monopoles are used as elementary particles with a magnetic charge.  7. The method according to p. 1, or 2, or 3, or 4, or 5, characterized in that in the role of elementary particles with a magnetic charge use dyons.  8. A device for implementing magnetic-nucleon catalysis using elementary particles with a magnetic charge, characterized in that at least one module in it is a means for exposure to elementary particles with a magnetic charge on chemical elements and their compounds.  9. The device according to p. 8 for the implementation of magnetic-nucleon catalysis using elementary particles with a magnetic charge, characterized in that the module of the action of elementary particles with a magnetic charge on chemical elements and their compounds is a device for producing elementary particles with a magnetic charge.  10. The device according to p. 8 or 9 for the implementation of magnetic-nucleon catalysis using elementary particles with a magnetic charge, characterized in that at least one module of this tool is a means for implementing current interruption in at least one of the electrical conductors circuit, at the moment of changing the value of the current flowing through this conductor, placed in a dielectric medium in which the breakdown voltage is higher than the highest voltage on any of the conductors of the electric circuit.  11. The device according to p. 10, characterized in that the conductors of the electrical circuit are made of various chemical elements.  12. The device according to p. 10, characterized in that the conductors of the electrical circuit are made of various compounds of chemical elements.  13. The device according to p. 10, or 11, or 12, characterized in that the conductors of the electrical circuit are made with different cross sections.  14. The device according to p. 10, or 11, or 12, or 13, characterized in that the conductors of the electrical circuit are performed in various geometric shapes. 15. The device according to p. 10, or 11, or 12, or 13, or 14, characterized in that it contains means for changing the direction in space of the conductors relative to each other in the range from -180 to +180 ^o C.  16. The device according to p. 10, or 11, or 12, or 13, or 14, or 15, characterized in that it contains means for setting a parallel direction in the space of the conductors relative to each other.  17. The device according to p. 10, or 11, or 12, or 13, or 14, or 15, or 16, characterized in that the electrically connected adjacent conductors of the electrical circuit are located in different planes.  18. The device according to p. 10, or 11, or 12, or 13, or 14, or 15, 16, or 17, characterized in that it contains means for changing the direction of flow of currents through the conductors of the electrical circuit.  19. The device according to p. 10, or 11, or 12, or 13, or 14, or 15, 16, or 17, or 18, characterized in that it contains means for forming an alternating current circuit in the conductors and interrupting the current in moment of the greatest change in its value.  20. The device according to p. 10, or 11, or 12, or 13, or 14, or 15, 16, or 17, or 18, or 19, characterized in that it contains means for forming a pulse current in the conductors of the electrical circuit and interruption of current at the time of the largest change in its value.  21. The device according to p. 10, or 11, or 12, or 13, or 14, or 15, 16, or 17, or 18, or 19, or 20, characterized in that it contains means for interrupting current by electric explosion .  22. The device according to p. 10, or 11, or 12, or 13, or 14, or 15, 16, or 17, or 18, or 19, 20, or 21, characterized in that it contains a power source and switching device with an external trigger for supplying energy to the load.  23. The device according to p. 10, or 11, or 12, or 13, or 14, or 15, or 16, or 17, or 18, or 19, or 20, or 21, or 22, characterized in that it contains device for spatial limitation of the dielectric medium.  24. The device according to p. 23, characterized in that the device for spatial restriction of the dielectric medium is made in the form of a camera.  25. The device according to p. 24, characterized in that the chamber is sealed.  26. The device according to p. 10, or 11, or 12, or 13, or 14, or 15, or 16, or 17, or 18, or 19, or 20, or 21, or 22, or 23, or 24, or 25, characterized in that water is used as the dielectric medium.  27. The device according to p. 26, characterized in that distilled water is used as the dielectric medium.  28. The device according to p. 10, or 11, or 12, or 13, or 14, or 15, or 16, or 17, or 18, or 19, or 20, or 21, or 22, or 23, or 24, or 25, or 26, or 27, characterized in that it comprises a device for forming a pressure of 1 atm in a dielectric medium.  29. The device according to p. 10, or 11, or 12, or 13, or 14, or 15, or 16, or 17, or 18, or 19, or 20, or 21, or 22, or 23, or 24, or 25, or 26, or 27, characterized in that it contains means for forming a pressure of less than 1 atm in a dielectric medium.  30. The device according to p. 10, or 11, or 12, or 13, or 14, or 15, or 16, or 17, or 18, or 19, or 20, or 21, or 22, or 23, or 24, or 25, or 26, or 27, characterized in that it contains means for forming a pressure of more than 1 atm in a dielectric medium.  31. The device according to paragraphs. 10-30, characterized in that it contains means for increasing the temperature value of the dielectric medium.

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