The power of natural earthquakes comes from the earth's own nuclear energy.
Guo Desheng Jiamusi University Mathematics Department Yichun Tangwanghe Party School
abstract:
According to methodology, the study of crustal movement and deformation must be comprehensively analyzed and summarized from the physical and chemical perspectives of matter. Physical change, chemical change and nuclear fission are the main ways to generate power when the object itself is deformed. The kinetic energy and potential energy of an object make it deform or move, and substances change chemically to form chemical energy, which makes it deform or move. Kinetic energy, potential energy, chemical energy and nuclear energy are the absolute factors that constitute the power of matter itself. According to years of careful study, it is found that there are both physical and chemical changes on the earth. In the chemical changes of the earth's substances, various substances are transformed into new inorganic substances, organic substances, simple substances and nuclear energy, which have the characteristics of energy release and form power. Comparing the location of underground energy materials with earthquakes, it can be concluded that the location of earthquakes is closely related to the location of nuclear materials. Combining a large number of facts and documents, according to a series of complex relationships between earthquakes and energy substances, we can deduce the fact that the power of natural earthquakes comes from nuclear energy inside the earth.
Key words: uranium; Uranium mine; Plutonium; Californium; Radon; Fission; Fusion; Rot; Half-life; Neutron; Earthquake; Natural nuclear reactor.
Foreword:
Under the influence of human activities, the global climate changes rapidly, various natural disasters occur frequently, and the climate deterioration intensifies, which poses a great threat and inadaptability to human survival. How to solve this problem has become an urgent task for geoscientists and scholars all over the world.
Since ancient times, scientific researchers have been entangled in the "dynamics" of earthquakes, using the "plate theory" to conduct numerous studies, and finally did not draw scientific conclusions. Why is this happening? The methodology gives an explanation. To study geological deformation, we must start with the dynamics of physical changes and chemical changes, and analyze and judge the dynamics of natural disasters such as earthquakes. Only by finding the power source of geological disasters can all geological disasters be solved.
Through a large number of historical data and documents, combined with my own understanding and summary for many years, according to the methodology and correct logical thinking analysis and judgment, in the long-term serious research and summary, I have a comprehensive understanding and deeper understanding of the dynamic roots of geological disasters, and have a comprehensive analysis and rigorous discussion on geological disasters such as earthquakes by using correct thinking logic and combining with documents.
First, the crustal deformation analysis
The deformation of an object is nothing more than kinetic energy, potential energy, chemical energy and nuclear energy formed by physical and chemical changes. Crustal deformation is the result of external factors and internal kinetic energy, potential energy, chemical energy and nuclear energy. Outside the earth, there are wind energy, light energy, water energy and mountain energy. There are energy substances such as coal, oil, natural gas and nuclear substances in the earth, and volcanic eruption and earthquake of these substances are a kind of energy release, which leads to crustal shaking. Because there are all kinds of combustible energy substances and nuclear substances underground, the "power" of volcanic eruption and earthquake must come from the interior of the earth. Therefore, we should study and analyze the geological structure of the earth and various energy substances to find out the root cause of crustal deformation.
Second, the location analysis of earthquakes and underground energy substances
According to the article "Basins and alluvial plains play a decisive role in the formation and mineralization of coal", it is concluded that coal and natural gas will form in basins and impact plains, and the coal-forming zone is also the zone where earthquakes occur. For example, in Shanxi, there have been numerous major earthquakes in history. Shanxi is a major coal-producing province, and earthquakes, coal mines and natural gas are closely related. According to a large number of historical documents, such as the combination of uranium and natural gas, we know that uranium and natural gas also exist in basins, impact plains and their basin-mountain margins, so there are such facts in basins, impact plains and their surroundings.
Coal, natural gas, petroleum, uranium deposits and earthquakes occupy a special position in basins and impact plains. In the special position of basins and impact plains, we have found countless coal mines, natural gas mines, oil mines and uranium mines, which are the most important substances that can release energy on earth. In such a special geographical position, earthquakes occur from time to time, and there are countless complicated relationships between earthquakes and these energy materials. [ 1.2.3.4.5]
Third, can all underground energy substances release energy underground?
For the energy substances buried underground, what we know is mainly coal, oil, natural gas, gas and nuclear substances. Can these energy substances stored underground release energy?
According to the combustion and explosion characteristics of coal, oil and natural gas, their combustion and explosion require oxygen conditions and open flames, and the amount of oxygen determines the amount of energy released. Earthquakes are often caused by gas explosion in mines, which is the condition for underground gas concentration and sufficient oxygen explosion. Underground, if coal, natural gas and oil are completely released, then there must be enough oxygen. But it turns out that underground oxygen is not enough to release these energy substances. But now, a large number of facts and countless related documents prove that there is a uranium mine [2.3.4.5] associated with natural gas underground. Uranium is a nuclear substance and a basic fuel used in various fields, which releases huge energy. For nuclear matter, there is no need for any conditions, only one "neutron" impact is needed to release the energy of nuclear matter. [9]
Fourth, analyze the characteristics of nuclear matter existing in the earth.
The underground nuclear material discovered now is uranium ore with atomic number 92. There are three isotopes of uranium 234, uranium 235 and uranium 238 in nature. The half-life of uranium 238 is about 4.5 billion years, that of uranium 235 is about 700 million years, and that of uranium 234 is about 250,000 years. Uranium ore contains uranium 234, uranium 235 and uranium 238. [6]
With reference to "On Uranium _ Plutonium and Fission Products of Uranium _ Also on Some Problems of Radioactive Materials Leaked from the 201Fukushima Nuclear Accident", the process of decay and fission of nuclear materials and the continued decay of high-energy fragments are introduced in detail. Among the three isotopes of uranium, U234 has great energy. The energy released by 1g U235 fission is equivalent to that released by 2.5 tons of high-quality coal. When uranium U235 is bombarded by neutrons and thermal neutrons, there are more than 60 ways of fission, and more than 20 kinds of high-energy fragments are formed by fission. The main high-energy fragments are strontium 89 (half-life 50 days), strontium 90 (half-life 29 years) and krypton (half-life 65433). Uranium 233, barium 14 1, and other fragments, these high-energy fragments will continue to decay and fission for a certain period of time, and continue to release energy. [6]
There are traces of plutonium in uranium ore. The isotopes of plutonium are 13, and there are 244 and 239 in nature. The reserves are very small and the half-life is very long. The artificial isotopes of plutonium are PU238, PU240, PU234, PU232, PU235, PU236, PU237, PU246, etc. The half-life of PU238 is about 88 years, and that of PU240 is about 6500 years. During the research, it is found that there is still a very small amount of californium in the earth, which mainly exists in uranium mines with high uranium content. [6.27.28]
Isotopes of californium There are 20 known isotopes of californium, all of which are radioactive isotopes. The most stable ones are californium -25 1 (half life is 898 years), californium -249(35 1 year), californium -250( 13.08) and californium-252 (2.645 years). The half-lives of other isotopes are less than one year, and most of them are even less than 20 minutes. The mass number of californium isotopes ranges from 237 to 256. [34.35]
Californium-252 is a strong neutron source, so it is extremely radioactive and very dangerous. Californium-252 has a probability of 96.9% that α decays (losing two protons and two neutrons) and forms curium -248, leaving a probability of spontaneous fission of 3. 1%. A microgram of californium-252 releases 2.3 million neutrons per second, with an average of 3.7 neutrons per spontaneous fission. Most other californium isotopes decay with α to form an isotope of curium (atomic number 96). It can be used as a neutron source for Qualcomm. [9.29] The usable amount of californium is very small, which limits its application. However, as a source of fractured fragments, it is used in nuclear research. [ 7.9.24.26 ]
If californium occurs in uranium ore with high uranium content, californium is a strong neutron source, and decay will release neutrons. For uranium ore with high uranium content, it will lead to fission, just like the egg cells of mature women, which will split when they meet sperm.
Uranium can spontaneously and artificially fission, producing huge energy and emitting light and heat at the same time. Uranium fission is the most common in nuclear power plants. After heating, uranium atoms release 2 to 4 neutrons and then hit other atoms, thus forming a chain reaction and spontaneous fission, leading to an explosion. [ 12]
Verb (abbreviation of verb) Comparative analysis of uranium formation energy and earthquake release energy
According to the "Richter earthquake" proposed by American seismologists Kurt and Gutenberg, the energy released by Wenchuan M8 earthquake is about 1 100 million tons of TNT. According to the energy released by one kilogram of uranium fission is equivalent to the energy released by 20 thousand tons of TNT, how many uranium ores are needed for Wenchuan earthquake is deduced. The proportion of uranium in general uranium ore is about 0.75/ 100. According to this standard, it is 60 thousand. Convert 654.38 billion tons of TNT equivalent into uranium fission energy. It is calculated that 50,000 kilograms of uranium is needed, which is about 66.67 million tons of uranium ore. That is to say, if 66.67 million tons of uranium ore is completely fission, it will produce 654.38+100 million tons of TNT equivalent.
20 12, 165438 10. On 5 October, it was learned from the Ministry of Land and Resources that a large uranium mine with a reserve of 30,000 tons was discovered in Inner Mongolia. If 30,000 tons of uranium ore is completely split, the energy generated is equivalent to 4.5 billion tons of TNT equivalent. 201665438+1October1October 14 The reporter learned from the video conference on land and resources work in the whole region that seven large-scale uranium deposits have been discovered in Inner Mongolia, and if all the uranium deposits in Inner Mongolia are released, it will far exceed 4.5 billion TNT equivalent. In contrast, if the uranium deposits in Inner Mongolia are completely fission, the energy formed will far exceed 8. [23]
Before and after the earthquake, the radon content changed obviously.
Radon is a radioactive inert gas, and uranium is the parent of radon, so there is radon where there is uranium. According to this statement, if radon changes on the surface, uranium and other nuclear substances may exist underground, and now uranium deposits are often detected by radon changes. On the other hand, many facts show that radon has changed obviously after the earthquake. After the earthquake, the radon in the Longmenshan fault zone is obviously different. Radon will appear in places with uranium deposits, and radon is directly related to uranium. [ 13. 14. 16.25]
7. The decay and fission of uranium deposits are highly consistent with earthquakes and aftershocks.
According to Oklo phenomenon, there are natural nuclear reactors on the earth, which will produce nuclear decay, nuclear fission and release energy in a certain period of time. The size and content of uranium ore determine the energy release. Once uranium ore decays and splits, it will release huge energy, resulting in earthquakes and earthquake phenomena. [ 19.20.2 1.22]
According to the coexistence of natural gas and uranium deposits, basins and alluvial plains play a decisive role in coal-forming and mineralization, and it is inferred that uranium deposits and earthquakes occurred at the same location, [1.3].
According to the fact that there is still a very small amount of californium in the earth, californium mainly exists in uranium mines with high uranium content. Once californium and its isotopes exist in uranium deposits, the fission time of uranium deposits is determined by californium. Californium and its isotopes have been decaying for 900 years, decades and tens of minutes, and are the neutron sources of nuclear changes.
According to the fact that uranium is the mother of radon, radon will naturally leave the mother when uranium fission, and radon gas will naturally change.
According to the uranium reserves in Inner Mongolia, 30,000 tons of uranium has the equivalent of a major earthquake.
According to the high-energy fragments produced by uranium fission, neutrons released by fission or decay of other nuclear substances and their isotopes will continue to collide and fission again. There are many isotopes of californium, and the decay time of these isotopes ranges from 20 minutes to hundreds of years. More importantly, neutrons are released. When high-energy debris receives neutrons, it will continue to fission, thus forming a continuous energy release until the energy of nuclear matter is released, which is highly similar to the aftershock process after each major earthquake.
According to the characteristics of nuclear fission, it is impossible to predict uranium nuclear fission in the earth with sound waves.
From the above findings, it can be seen that the location of uranium mine and natural gas, the energy of uranium mine and earthquake energy are in the same position, the TNT equivalent generated by earthquake matches the TNT equivalent converted from uranium mine, and the process of earthquake and aftershock is very similar to the process of nuclear fission releasing energy. [ 15.38]
Eight, thinking and analysis of nuclear fusion
The process of nuclear fusion is also a process of energy release. Nuclear fusion is that two atoms with small mass synthesize a larger atom, and nuclear fission is that one atom with large mass splits into two smaller atoms. Under the same conditions, nuclear fusion releases far more energy than nuclear fission. There is no explanation and explanation of natural nuclear fusion in the earth's interior in historical materials and literature, only literature shows that there is evidence of 3H in the earth's interior. According to the existing data and literature, whether there is nuclear fusion inside the earth has not been scientifically confirmed, especially because the conditions of nuclear fusion are harsh and require ultra-high temperature, and there will be high temperature in volcanic eruption and nuclear fission on the earth. Can the temperature they produce meet the conditions of nuclear fusion, and is there nuclear fusion in nuclear fission? [37.39]
Nine. Earthquake mitigation method
It is also reported that there have been few earthquakes in Australia in recent years. Through understanding, Australia is a country with high uranium production and a long mining history. Up to now, it has a history of more than 80 years, and many uranium mines have been discovered and mined. After uranium mining, the phenomenon of natural nuclear reactor in Oklo no longer exists. In recent decades, there have been few earthquakes in Australia. Is it related to the massive exploitation of uranium mines? Thinking is necessary. [33]
Earthquake belongs to the release of energy, but for underground energy substances, the energy of uranium mine is huge, and the way of energy release of uranium mine is very simple. The release condition is that uranium content reaches a certain level and there is a neutron source, so uranium fission leads to energy release and crustal vibration.
Through the above analysis, the most effective means to eliminate earthquakes is to quickly find and mine uranium deposits, remove this nuclear substance that can release energy from the earth, and eliminate the hidden dangers of earthquakes. This is a very feasible method. On the other hand, the uranium content in the existing uranium mining area is identified, because when the uranium ore reaches a certain content, fission conditions will be formed. [8. 15. 17]
X. Formation of tsunami
Tsunamis, like earthquakes, are the release of huge energy in the ocean. However, according to the existing data and literature, it is still impossible to determine what kind of energy substances are released by the tsunami. The scientific community has not demonstrated the characteristics of combustible ice in detail, and there is no relevant literature and empirical evidence whether there is nuclear material at the bottom of the ocean. So it is still difficult to determine what kind of energy substances are caused by the tsunami.
conclusion
Through the above logical analysis and inference, if the documents and data used are scientific, then the earthquake is no longer a mystery. Natural earthquakes and aftershocks are all caused by uranium content to some extent. In uranium ore with high content, californium and californium isotopes will decay, releasing neutrons, leading to uranium fission, releasing energy to generate great power, causing earthquake vibration and aftershocks caused by countless continuous fission. At the same time, according to the basin and impact plain, coal formation and geological disasters have played a decisive role, and natural gas and uranium deposits coexist. We can find all kinds of minerals that were difficult to find in the past, and at the same time provide a reasonable direction for reducing earthquakes, find out the reasons for reducing the occurrence of major earthquakes, and find out the reasons why human beings are not trapped by earthquakes. This is an unprecedented breakthrough in benefiting mankind and re-understanding the earth.
refer to
1. Basins and alluvial plains have played a decisive role in the formation, mineralization and geological disasters of coal —— Guo Desheng science and technology prospect? , 20 16 (26) :304-305
2. A preliminary study on the relationship between natural gas, coal and uranium: a case study of Dongsheng area in Ordos Basin? , 2005
3. Integrating the ore (reservoir) system and cooperating with various energy resources and minerals in the basin —— Taking Ordos Basin as an example, Wang Yi? , Yang Weili? , Deng Jun? Wu Berlin? , Li Ziying? Journal of Geology? , 20 14 , 88 (5) :8 15-824
4. Study on the combination forms of various energy and mineral resources in Ordos Basin * * * * Li Jiangtao Shandong University of Science and Technology, 2005.
5. The existence of oil, gas, coal and uranium in the northern margin of Qaidam Basin and its geological significance. Wang Dan, Northwest University, 20 15.
6. About Uranium _ Plutonium and Fission Products of Uranium _ Also on radioactive materials leaked from the 201KLOC-0/Fukushima nuclear accident. , 20 13 (4) :75-80
Are the 7.248 cm and 252Cf spontaneous fission prompt neutron spectrum measurement packages still connected? And Liu? Wen Yulin? , Fan Tieshuan? , Badenkov? High energy physics and nuclear physics? , 200 1 , 25 (4) :304-308
8. Discussion on approximate simulation method of shock vibration effect of underground nuclear explosion Xue Yulong, Tang, Mo Meili-Blasting -20 13
9. Talking about the Neutron Source for californium-252 Nuclear Power Station-Technology and Innovation -20 17
10. An experimental system of liquid metal cooled reactor which can realize critical and subcritical operation experiments. , Wu yican? Song yonglai
1 1. Extraction of Cf and Cm by Some Monobasic Acid Organic Phosphates? , Wang Ruizhen? , Fan, Nuclear Chemistry and Radiochemistry? 1982 , 4 (3) : 186- 186
12. calculation and analysis of decay exothermic power of different grades of plutonium materials Zhu Jinhui's nuclear technology? 20 16 ( 1) :39-44
13. Indian radon survey for uranium deposits A.S. Uranium Geology in Nach, Burkhardt? , 1973 (6) :45-47
14. use radon content change to predict earthquakes. Wu Di World Science? , 1984 (7) :64-65
/kloc-research progress of nuclear explosion seismology since 0/5.90 s? Mu Qiduo's World Earthquake Translation Series? , 1994 (4) : 1-7
16. Preliminary analysis of post-earthquake effect characteristics of radon observation values in Wenchuan M8.0 earthquake? Ren Hongwei, earthquake? , 2009 , 29 ( 1) : 12 1- 13 1
17. The "big technology" of underground nuclear explosion to destroy Tian Wu in the great earthquake? , 2000 (6) :3 1-3 1
18.3MeV neutron-induced fission determination of uranium isotope abundance Qiao Yahua, Wu Jizong, Yang Yi, atomic energy science and technology? , 20 12 , 46 (7) :878-880
19. Natural reactors and nuclear fuels Journal of Li Huadong Institute of Geology 1940 10.
20. Oklo phenomenon-natural nuclear reactor "world nuclear geological science"? , 1982 (5)
2 1. Natural nuclear reactor Liu Tiegeng's Earth and Environment? 1976 (4) :34
22. Natural fission reactor-Oklo phenomenon Ye Ling world science? , 1990 (4) :20-22
Research progress of nuclear explosion seismology since 1990s? Mu Qiduo's World Earthquake Translation Series? , 1994 (4) : 1-7
24. Determination of californium isotopes and their daughters in californium sources? Liu Hengjun, Atomic Energy Science and Technology? , 1983 , 17 ( 1) : 18- 18
25. Geochemical characteristics of Longmenshan fault zone after the earthquake Xu Hongbiao Ma Fuhai Lei Qingxiong He Jianxian
26. decay spectroscopy study of fission fragments of ~ (26.~ CF spontaneous fission source? , Haibin Tian? , Zhou Jianzhong? , Shi Shuanghui? , Gu Jiahui? General meeting of members? , 2004
27.44.0 44.144.2 44.3 44.4 anl donors. General situation of human health: californium. Argonne national laboratory. August 2005.
28. John Amesley. Building blocks of nature: a guide to elements new. New york, NY: Oxford University Press. 20 1 1. ISBN 978-0- 19-960563-7.
29. development. 252 californium fast fission chamber Li Jiansheng? , Zhang Yi? Today? Nuclear electronics and detection technology Li Runliang? , 200 1 , 2 1 (4) :264-267
30. Florida State University: A new discovery of rare earth element californium-a new chemical material? , 20 15 (5) :266-266
3 1. californium can be used for safe storage of radioactive waste. Modern material dynamics of Li Dong? , 20 14 ( 12) :3-3
32. The californium isotope produced by carbon ion bombardment of uranium? , SG Thompson? J.k. street? Seeburg Office of Science and Technology; Technical information test ...? , 1950 , 8 1 ( 1) : 154- 154
33. When did Jin Ruoshi inspect Australian uranium resources? Su Yongjun's geological survey and research? , 20 13 (4) :276-280
34. China ferroalloy online Knowledge Base
α decay properties of 35.247Cf, 248Cf, 252Fm and 254Fm? , 20 16 , 4 13 (3) :423-43 1
36. Investigation on radiation level of nine lignite coal mines in Xinjiang Liu Fudong? , sheng Wei Ming? , Zhang Zhiwei? , Liu Yanyang? , Chen Ying? Annual report of China Institute of Atomic Energy? , 20 10 ( 1) :32 1-322
37. Principles of Nuclear Fusion Zhu Beijing: University of Science and Technology of China Press 1992, (5)
38. The distribution of uranium and thorium in the outer core, nuclear fission and its influence on geodynamics? 1999 S 1
39. Evidence of ~ 3h in the Earth's interior Jiang Yusheng He Ming Institute of Nuclear Physics, China Academy of Atomic Energy, Beijing