The use of accelerators and the phenomena of collisions of elementary particles with high-order energy to generate electrical energy. The «Electron» Project. Monograph

Editor Boxodir Xoshimovich Karimov

Editor Farruh Murodjonovich Sharofutdinov

Illustrator Ibratjon Xatamovich Aliyev

Cover design Ibratjon Xatamovich Aliyev

Cover design Farruh Murodjonovich Sharofutdinov

Reviewer, Doctor of Technical Sciences, Professor of the Scientific Research Institute "Physics of Semiconductors and Microelectronics" at the National University of Uzbekistan Obbozjon Xokimovich Qo'ldoshev

Reviewer, Doctor of Physical and Mathematical Sciences, Professor and Head of the Department of "Technological Education" of the Faculty of Physics and Technology of Fergana State University Salim Madraximovich Otajonov

Reviewer, Candidate of Physical and Mathematical Sciences, Associate Professor of the Department of "Technological Education" of the Faculty of Physics and Technology of Fergana State University Boxodir Xoshimovich Karimov

Reviewer, Candidate of Physical and Mathematical Sciences, Associate Professor of the Faculty of Computer Design Systems of the Fergana Polytechnic Institute Sultonali Mukaramovich Abduraxmonov

Reviewer, Doctor of Philosophy in Physical and Mathematical Sciences, Senior Lecturer at the Faculty of Physics and Mathematics of Ferghana State University Sapura Malikovna Zaynolobidinova

Reviewer, lecturer at the Faculty of Physics and Mathematics of Fergana State University Dilshod Quldoshaliyevich Yuldoshaliyev

Pedagogical consultant on the 1st section, Candidate of Philosophical Sciences, Associate Professor of the Department of Sociology of Fergana State University Baxromjon Nomonjonov

Pedagogical consultant on the 1st section, Candidate of Pedagogical Sciences, Associate Professor of the Department of Information Security of the Fergana Branch of the Tashkent University of Information Technologies Inomjon Uktamovich Bilolov

Consultant in Physical Sciences Abdurasul Abdusoliyevich Ergashev

Proofreader Ibratjon Xatamovich Aliyev

Proofreader Gulnoza Muxtarovna Sobirova

Proofreader Abdurasul Abdusoliyevich Ergashev

© Ibratjon Xatamovich Aliyev, 2023

© Farruh Murodjonovich Sharofutdinov, 2023

ISBN 978-5-0059-5377-3

Created with Ridero smart publishing system

Preface

Our world is immersed in a huge ocean of energy, we are flying in infinite space at an incomprehensible speed. Everything is spinning, moving – all the energy. We have a huge task ahead of us – to find ways to extract this energy. Then, extracting it from this inexhaustible source, humanity will move forward with giant strides!

Nikola Tesla

Energy has been important for all mankind since ancient times. Every day a person consumes more and more energy, and if earlier the main source of energy was fire, today its role is increasingly being performed by electric current. With the help of electricity, lamps are lit, computers work, books are printed, food is heated and cars are already driving. Electricity has entered into all corners of human life and is an essential resource.

For the first time, work on the generation of electric current began with experiments on the study of electromagnetic induction by Michael Faraday, but for a long time these works were not implemented in the face of industrial plants and installations. Initially, only steam engines were used to perform certain work by James Watt, and only after the invention of the armature winding of dynamoelectric machines by the Belgian Zenob Theophil Gram in 1871, it became possible to obtain electric current industrially.

Thus, the first power station was a hydroelectric power station, created in 1878 by an English engineer, Baron William Armstrong at his estate Cragside, in England. The generated electricity was used for lighting, heating, hot water supply and other household work.

But for the people and all mankind, electricity began to serve only 4 years later, in the winter of January 12, 1882, in London, when the world's first public coal-fired electric power station by Thomas Edison, built according to his own project, started working. Since then, mankind has been industrially using electric current, of course, a lot has already changed since then, the technologies of the famous inventor Nikola Tesla have been introduced to use alternators, as in power transmission systems, on the same basis of alternating current.

But also, in order to satisfy their needs, man has invented a number of methods and technologies for obtaining and generating electric current on a large scale. But are all these methods so safe and do they manage to fully perform their function?

To date, to generate electric current and meet the needs of mankind in this resource, technologies for generating electric energy from heat (steam pressure) are used, which is clearly expressed in the technologies of thermal power plants (thermal power plants), where by burning coal, natural gas and other combustible resources having some energy potential in their structure, they receive steam that creates sufficient pressure for the movement of steam generator turbines, which, using the phenomenon of electromagnetic induction, converts kinetic energy (energy of motion, in this case, the energy of rotation, turbines under the action of steam force), that is, the force of steam pressure into an electric current that is already transmitted through power lines (power lines) to consumers for further use.

Also, hydroelectric power plants (hydroelectric power plants), nuclear power plants (nuclear power plants), wind farms (wind farms), SPES (solar panel power plants) are used as sources of electric energy. Other technologies are also known, such as methods of obtaining current from lightning, waves and other natural forces, but they are not used on a large scale, for this reason it is enough to consider only the above types of power plants, with their own methods of generating large electrical energy.

The TPP technology was considered, if we stop at the HPP, then this power plant is based on generating an electric current from kinetic, and in the case of being at a high altitude, potential (energy that an object possesses, being at a certain height due to gravitational force or gravity, while potential energy is involved with a further transition to kinetic) energy water and rotation of the generator turbines at high speed and subsequent generation of electric current, also using the phenomenon of electromagnetic induction, on which the principles of all electric generators are based.

The next type of power plant, namely nuclear power plants, are stations whose principle is based on one of the most progressive and newest methods of generating electric energy, namely, on the basis of generating electric current from atomic energy, which is released after the decay of uranium—235 or uranium-238 nuclei, depending on the type of station after they are bombarded with thermal (having an energy that is numerically equal to the energy at normal temperature) by neutrons. Due to the fact that after each subsequent reaction, a maximum of 3, and more often 2 additional neutrons are released, a chain reaction occurs with the release of 200 MeV, with each reaction, with a rapid increase in the total energy of the body, which leads to an increase in temperature.

And at the same time, there comes a moment when there is enough energy to transfer it to water, which is irradiated and transfers heat to the second water circuit, through which the already circulating water rotates steam generators, while the temperature does not reach critical temperatures, due to the fact that the water is under pressure, which increases the levels of constant temperatures for this liquid.

Describing the wind farm, it is worth noting that the principle of electromagnetic induction is also preserved there and more than one generator is used, which rotate under the force of the wind, although they rotate with a lower frequency, respectively generating less power.

The final one, also becoming more popular and relevant every day, is the SPES. This type of station by the method of generating electric current is radically different from the others. This type of stations is based on the phenomenon of photoelectronic emission, which occurs when specially manufactured panels are irradiated with sunlight, the electric charge generated in this case is output and transferred already to the transmission lines.

But it is also worth noting that each type of power plants has significant disadvantages, of course not in its design, but in the effect exerted on nature and the environment. For example, thermal power plants [8] generate a huge amount of anhydride carbonate, which is released into the atmosphere and causes such an effect, which is referred to as global warming, which is a consequence of the so-called greenhouse effect.

We will describe all these problems for the following power plants:

hydroelectric power plants [9]:

· Disaster risk (difficult construction in case of earthquakes and other natural disasters);

· Danger of fish migration (whole species of various fish may die);

· Danger of nearby cities (in case of a problem with the plate within a radius of many kilometers, cities will be flooded).

NPP [10]:

· Uranium is a non-renewable resource;

· Cannot replace fossil fuels;

· Depends on fossil fuels;

· Uranium mining is harmful to the environment;

· Very persistent waste, decomposed for a long time;

· The danger of nuclear disasters;

· The presence of the effect of changing the planetary radioactive background;

· High explosion hazard;

· Difficulty of recovery, in the event of a disaster.

WES [11]:

· Presence of noise;

· High cost of buildings;

· Long payback period in case of implementation;

· Inconstancy and unregulated wind flow;

· Low energy efficiency.

SPES [12]:

· Lack of energy extraction at night;

· High energy storage costs;

· Relatively high price of solar cells;

· Daily and seasonal variability of solar radiation;

· Local climatic changes unfavorable for the use of solar energy;

· Difficulties with accumulation and concentration of energy;

· The daily energy flux density of solar radiation is low;

· Installation takes up large areas;

· High production and construction costs;

· Low generated power.

Analyzing the above facts, it becomes clear that a development is needed that can generate electric current with greater efficiency, on a larger scale, and also more safely than with the help of technologies used today. And if we consider all possible ways of obtaining electrical energy, then there is an explanation for why this study, which has been going on for more than 12 years, was so called – "Electron".

Initially, the search for a new source of electrical energy began back in 2010. The first stage of the study was to search for such a method in classical mechanisms. More than 500 different mechanisms were analyzed, but all of them were not effective until the first magnetic type of device was presented for the first time in 2016, which, using the force of magnetic repulsion, created vibrations that caused the output of 3—4 water jets, the potential energy of which was converted into electric current. But this version of the device was not strong enough and effective enough, and after an experimental test, a number of shortcomings were found, which caused the rejection of this model.

This was followed by 34 mechanisms, which distinguished themselves by following the first more successful version. But when they did not find their confirmation, it was necessary to abandon them. For 4 years, since 2014, the so-called «electric era» has been going on, when various mechanisms of an electric, magnetic and electromagnetic nature were investigated. And although mechanisms with electric generators, solar panels, transformers, diodes, transistors and many other elements have been developed, but, unfortunately, they have not found their confirmation. Then, starting in 2019, the «quantum era» began.

In March 2019, the first project with elementary particles was developed, and then the project changed its own name and adopted the name "Electron", since the idea was based on splitting an electron and conducting interactions with the creation of a special "structure" already with hypothetical components of the electron particle. Due to this, the components in the face of Umidon and Raanon particles were studied in detail. Then for the first time scientific articles on this topic were published: "Behavior of an electron in an atom", "Electron particle", "Electron features", "Linear Electron Accelerator in Power engineering" and many others. They also took part in the international event InnoWeek 2019.

But after some debate, it was found that this model, as well as the methods of its implementation, cannot be translated into reality. The next model was the technology of collision of two electron beams in the energy output, as it was assumed due to some anomaly that followed from the conclusions of the formulas. But there were problems, the solution of which was not found, as well as a detailed introduction with an explanation of this phenomenon. Therefore, it was necessary to move from this model to technologies for the use of nuclear reactions. At this stage, from the beginning of 2020, the "Nuclear Era" began, when hundreds and even thousands of nuclear reactions were investigated. The total number of studied nuclear reactions, which were analyzed at this stage from the beginning of 2021 to February 2021, is 1,062 reactions.

And thanks to the definition of nuclear reactions with a large energy yield, a whole complex of these interactions was created. And although the technology no longer had a relationship with the electron, but the name of the study has not changed to this day. And although more than 10 scientific articles were published, they were also described in 2 volumes of the work "Constructor of Worlds", as well as presented to several companies, such as Acwa Power in February and a number of energy companies in September 2021. But today this technology has been improved and has a more simplified look, which opens up a number of possibilities.

It is this technology that is described in this research, which is currently considered to have no analogues in the whole world. As can be seen from the history of this study, the path of this technology was not easy, and it is much better than its "brothers" and "predecessors", which demonstrates a lot of experience and a strong desire to achieve this goal for the whole of humanity, which gave strength to overcome a number of very different difficulties, and only a part of which it was described above when retelling the entire history of the study.

As a result, it can be concluded that nuclear reactions deserve more attention as the newest source of electrical energy on a huge scale. Of course, uranium reactions are already actively used today, thermonuclear reactions are also very popular, for which searches are still underway for their use for peaceful purposes.

But it is also possible to use completely new types of nuclear reactions with a larger yield and a larger cross section of the nuclear reaction. But first it is necessary to understand in more detail the concepts of nuclear reactions themselves. This work tells about the technology that will allow generating electric current with the specified parameters and data.

For a better understanding of the material being explained, as well as to create the convenience of describing the device, initially a special introductory course in the very topic of nuclear physics was prepared in the first section. But since this course is not aimed at covering all the material, only the necessary or important points from the entire course of nuclear physics and high-energy physics are indicated.

After the reader is intrigued by unexplained concepts about nuclear reactions and about the purpose of the entire study, the explanation begins with the very explanation of the stages of human cognition of the structure of matter. The first knowledge and thoughts of Aristotle, Herodotus, the great thinkers Avicenna, Biruni, Sir Newton and many others. And also describes the history of classification.

The sudden problem of radioactivity, even more intriguing to the reader, becomes an additional help, after which everything is led to the description of the atom. Then the models of the atom created and described by great scientists with their experimental confirmations are explained, after which the speech smoothly proceeds to the description of the atomic nucleus and many other particles.

And finally, one of the most intriguing moments comes, namely, the description of nuclear reactions, the derivation of formulas, calculations, models, and finally, the description of a variety of experiments that simply fascinate with their scales and designs. And when our dear reader is fully prepared for the research and analysis of the new technology with all its complexities, the second section begins.

There, a complete theoretical description is given, various assumptions and proofs are built that fully support the main idea and intent. And already in the following sections, the experimental representation is analyzed, as well as the whole picture of the implementation of this experiment in reality.

It is in this way that a full-fledged idea, a separate idea, is formed and rises right in front of the reader, which is of enormous importance for all mankind, ensuring the generation of electric energy on a huge scale, buildings will become easier and faster compared to other electric power stations, however, as well as the costs of their construction. At the same time, the possibility of providing electric current to the entire population will increase. The energy and information hunger will disappear, it will be possible not to be afraid of large losses in wires and to increase the transition to the transmission of electrical energy without wires, as Nikola Tesla predicted back in the 1900s.

The number of various experiments conducted in various research institutes, which are now waiting for the latest source of electrical energy, will increase. A person will be able to extend the time of his stay in space several times and may even take a swing at seemingly insane ideas about creating artificial atoms from electrical energy. At the same time, the number of various assumptions and riddles that will be reflected in the works of science fiction writers and writers will increase. The whole human world will sway and begin to move with leaps and bounds and a great future will come.

But in order to realize all this, you need to take the first step, namely, to enter into the depths of the Electron research.

Ibratjon Xatamovich Aliyev

Sharofutdinov Farroh Murodjonovich

Section 1. Theoretical calculations

Chapter 1. The History of Atomism

Everything consists of particles… things differ from each other by the particles they consist of, their order and location…

Democritus

The quantum world of elementary particles and the atomic nucleus is amazing in its beauty, structure and scale. And then this world will also be considered in all its difficulties. But initially it is necessary to understand the very essence of the first steps in the discovery of the atom, the very particle with which everything began. The first chapter is radically different from the rest of the chapters because it was created specifically not only for higher minds who are already operating with rather complex concepts, but also for the young generation just entering the path of this amazing science. Therefore, in this chapter everything is described as simply and elementary as possible. So, without further ado, the history of the greatest atomic science begins…

Since the most ancient times, people have been trying to determine the structure of our world, to understand what it consists of. Initially, all these questions were purely philosophical, for this reason there was such a thing as atomism, according to this theory, all substances, objects, bodies consisted of indivisible particles – atoms. This idea was widely supported in ancient times, first appearing in various parts of our planet from ancient India to ancient Greece and the Eastern world.

For example, in Ancient Greece atomism was also widely supported by Democritus of Abder, Leucippus and others. Opponents of the ideas of atomism could only claim that matter divides indefinitely. Democritus' teaching was also based on the idea that atoms are not only indivisible, but their number is infinite, they are not created, and they are eternal, and the properties of objects depend on atoms. A great contribution to the idea of atomism was also made by the philosopher Epicurus, and later by the poet Lucretius. But if everything was clear with the statement of the very concept of the atom, since the atom is translated from ancient Greek as "indivisible", that is, atoms could not be divided, then there were problems with their forms. For the first time, the idea of the shapes of the atom was put forward by Plato, assuming that atoms have the shapes of Platonic bodies or regular polyhedra like a cube, pyramid, tetrahedron, dodecahedron, octahedron and others, that is, polyhedra whose faces are equal to each other. Atomism deserved a lot of attention after active references to this idea by Aristotle himself, after which this idea began to spread around the world.

In the Eastern world, where outstanding thinkers and geniuses conducted their research and performed excellent research at the Mamun Academy, there were also separate opinions on the topic of atomism. Such outstanding scientists as Abu Rayhan Biruni, ibn Sina, Abu Nasr ibn Iraq, Mahmud Khujandi, Ahmad ibn Muhammad Khorezmi, Ahmad ibn Hamid Naisaburi and many others conducted their experiments at the Mamun Academy itself. Many of them are outstanding scientists, if Abu Ali ibn Husayn ibn Abdallah ibn Sina, also known as ibn Sina or Avicenna in Europe created the "Canon of Medical Science and is considered the father of medicine, then Abu Rayhan Biruni is an encyclopedic scientist who conducted research in physics, mathematics, astronomy, natural sciences, history, chronology, linguistics, indology, earth sciences, geography, philosophy, cartography, anthropology, astrology, chemistry, medicine, psychology, theology, pharmacology, history of religion and mineralogy. He is also considered the creator of the first globe, also the first person to measure the radius of the planet using trigonometric patterns, as well as the first who predicted the presence of the continent of America.

To date, the letters of Abu Rayhan Biruni and ibn Sina have been preserved, along with their works, where scientists also debated on the topic of the structure of matter. According to the assumption of scientists, the world consisted of particles smaller than an atom, it is there that one can see the assumptions that the atom particle, which was then considered indivisible, is divisible, but not to infinity. As for their shape, then it was assumed that the atoms have a spherical shape, since the sphere was considered a kind of ideal model, therefore, the atoms should be like this.

Time passes and a variety of discoveries are made. But about the ideas of Epicurus, however, as well as about atomism, they forget, because the ideas of Epicurus contradicted Christian teachings and the church forbade its use, as well as the assertion that atoms exist. But the French Catholic priest Pierre Gassendi revived the idea of atomism, somewhat changing the notion that atoms were created by God. And after the defense of atomism by the chemist Robert Boyle – an outstanding chemist and author of the work "The Skeptical Chemist", as well as by Sir Isaac Newton, who himself was revered as an outstanding scientist, atomism was adopted by the end of the 17th century.

Let us quote Sir Newton himself on this topic from a translation of his works: "It seems to me that from the very beginning God created matter in the form of solid, weighty, impenetrable, mobile particles and that he gave these particles such dimensions, such shape and such other properties and created them in such relative quantities as he needed it was for the purpose for which he created them. These primary particles are absolutely solid: they are immeasurably harder than the bodies that consist of them – so hard that they never wear out and do not break into pieces, because there is no such force that could divide into parts what God himself created inseparable and whole on the first day of creation. Precisely because the particles themselves remain intact and unchanged, they can form bodies that have the same nature and the same structure forever and ever; for if the particles were worn out or broken into pieces, the nature of things depending on them would change. Water and earth, made up of old, worn-out particles and fragments, would differ in structure and properties from water and earth, built from still whole particles at the beginning of creation. Therefore, in order for nature to be durable, all changes in the bodies of nature can consist only in a change of location, in the formation of new combinations and in the movements of these eternal particles… God could create particles of matter with different sizes and can have different shapes, place them at different distances from each other, endow them, perhaps, with different densities and different acting forces. In all this, at least, I do not see any contradictions… So, apparently, all bodies were built from the above-mentioned solid impenetrable particles, which were placed in space on the first day of creation at the direction of God's mind."

And if at that time Boyle's ideas were established that there are "simple bodies" (chemical elements) and "perfect mixtures" (chemical compounds) and any "perfect mixtures" can be divided into "simple bodies", then in the book "The New System of Chemical Philosophy" of 1808, John Dalton put forward the first idea about which of the substances, to which type is subject. But before that, Lavoisier proved that mass is constant, it does not disappear anywhere and does not appear out of nowhere. Davy also discovered a number of chemical elements: hydrogen, oxygen, nitrogen, carbon, sulfur, phosphorus, sodium and potassium were discovered by him in 1807, and in 1808 he also discovered such elements as calcium, strontium, barium and magnesium. Iron, zinc, copper, lead, silver, platinum, gold and mercury were also discovered.

Their discovery did not take much more work, since many of them were isolated from ores, isolated from chemical compounds. And already water, ammonia, carbon dioxide and many other compounds were already considered perfect mixtures. And now, Dalton, having everything he needed, decided to determine the atomic masses of all chemical elements, and also enter them all into tables, that is, classify them. So, Dalton introduced his own designation for each chemical element, for example, for hydrogen he introduced a circle icon with a dot in the center, for oxygen there was a sign – an ordinary circle, and for carbon there was a sign of a painted black circle, etc. To calculate the masses of atoms, Dalton conducted some experiments.

Initially, he evaporated water, and on the upper part he installed substances with which hydrogen reacted better, calculating changes in both the mass of the substance with which the interaction took place or from the volume of steam, Dalton could determine which part of the water consists of hydrogen and which of oxygen. Thus, having determined that 1/8 of the total mass of water consists of hydrogen, and 7/8 of oxygen, Dalton decided that oxygen is heavier than hydrogen and assigned a mass equal to 1 to hydrogen and 7 to oxygen. The same analysis of ammonia showed 1 for hydrogen and 5 for nitrogen. After analyzing it in this way, Dalton compiled his own table of chemical elements.

Needless to say, although this was the first step on the path of knowledge, all these statements were not true. But it lasted for quite a long time and various assumptions were based on it. One of these hypotheses was published in the journal "Philosophical Annals" by the London physician William Prout and was devoted to the idea that all atoms consist of hydrogen. But of course, this hypothesis was not true like many other assumptions of that time.

And if then, the atomic unit of mass was taken as the mass of a hydrogen atom, then today the exact unit is considered to be 1/12 of the mass of a carbon atom and is named as an A. E. M. or atomic unit of mass. And chemical elements today are usually designated from the first two or one letter of their name in Latin, for example, hydrogen is designated as H due to the name Hydrogenium («Generating water» in Latin), Nitrogen – N or Nitrogenium – «Giving birth to saltpeter», iron – Fe or Ferrum, copper – Cu – Cuprum, carbon – C – Carboneum. This system was adopted on September 3, 1860 after the Italian chemist Stanislao Cannizzaro at the International Congress in Karlsruhe proposed this method in his speech.

After that, it was customary to record chemical compounds using these symbols, and the number of atoms was indicated in the lower right corner, so for example, the compound of carbon and hydrogen (water) is written as H2O, ammonia – NH3, sulfuric acid H2SO4, etc. This method is very convenient because it creates opportunities for using symbolic notation and not there is no need to write down all the symbols several times, for example, for a cane sugar molecule – C6H12O6 (6 carbon atoms, 12 hydrogen atoms and 6 oxygen atoms). Instead of CCCCCCHHHHHHHHHHHOOOOOO, you can easily and simply write C₆H₁₂O₆.

If everything is already clear with the notation, then there remains one very interesting consequence. Taking into account the fact that 1 atomic unit of mass is equal to 1/12 of a carbon atom, this makes it possible to calculate the masses of all chemical elements using compounds with carbon. For a better explanation, let’s give an example. Suppose there is a certain compound of carbon and hydrogen, if you act on it with an electric current or heat it, then it is possible, if it is solid, to melt, if the liquid is evaporated and to obtain a finite volume of carbon and hydrogen. From the ratio of their masses and volumes, it is possible to determine how many hydrogen atoms account for one carbon atom, and already from the ratio of their masses, it is possible to calculate the mass of hydrogen. So if we divide the methane compound into carbon and hydrogen, we get 4 times more hydrogen than carbon in volume, so we can conclude that for 1 carbon atom, there are 4 hydrogen atoms and the CH₄ compound is obtained. And as for the masses, in this ratio it turns out that the mass of 1 hydrogen atom is almost 1/12 of the mass of a carbon atom or 1.00811 am. Exactly the same method can be used to determine the masses for all other atoms (Table 1.1).