NUCLEAR-RADIOACTIVE REACTIONS IN EARTH CRUST THE GENERATOR OF EARTHQUAKE HARBINGERS
( Pp. 68-72)
More about authors
Rakhimov Rustam Kh.
Dr. Sci. (Eng.); Head, Laboratory No. 1; Institute of Materials Science of the Academy of Sciences of the Republic of Uzbekistan; Institute of Renewable Energy Sources; Tashkent, Republic of Uzbekistan
Институт материаловедения Академии наук Республики Узбекистан
г. Ташкент, Республика Узбекистан Makhsudov Asatulla U. starshiy nauchnyy sotrudnik
Institute of Materials Science, SPA “Physics-Sun”, Academy of Science of Uzbekistan Zufarov Mars A. junior researcher, Laboratory of Heat-accumulating, Heat-insulating Materials and Solar Technologies; Institute of Materials Science of the SPA “Physics-Sun” of the Academy of Science of Uzbekistan; Tashkent, Republic of Uzbekistan
Институт материаловедения Академии наук Республики Узбекистан
г. Ташкент, Республика Узбекистан Makhsudov Asatulla U. starshiy nauchnyy sotrudnik
Institute of Materials Science, SPA “Physics-Sun”, Academy of Science of Uzbekistan Zufarov Mars A. junior researcher, Laboratory of Heat-accumulating, Heat-insulating Materials and Solar Technologies; Institute of Materials Science of the SPA “Physics-Sun” of the Academy of Science of Uzbekistan; Tashkent, Republic of Uzbekistan
Abstract:
The article offers a method to predict earthquakes based on recording earthquake harbingers that are variations of neutron fluxes and intensity of charged particles of the earth’s crust. The obtained result indicates a possibility to determine an earthquake 10 hours and even longer in advance with an indication of the epicenter. Different earthquake precursors forming fluxes of neutrons and charged particles in nuclear and radioactive reactions with the earth’s crust are mentioned herein.
How to Cite:
Rakhimov R.K., Makhsudov A.U., Zufarov M.A., (2018), NUCLEAR-RADIOACTIVE REACTIONS IN EARTH CRUST THE GENERATOR OF EARTHQUAKE HARBINGERS. Computational Nanotechnology, 3 => 68-72.
Reference list:
Serdyukova A.S., Cantans Yu.T. Isotopes of Rn and the products of their decay in nature. M.: Atomizdat, 1975. R. 283.
Sasaki T., Gunji Ya., Okuda T. Mathematical Modeling of Radon Emanation // Journal of Nuclear Science and Technology, 2004. Vol. 41, No 2. R. 142-151.
Yuldashbaev T.S., Maksudov A.U. Development of a technique for recording earthquake precursors from observations of temporal variations in the flux of cosmic rays and neutrons // DAN RUz, 2010. No 3. R. 37-41.
Yuldashbaev T.S., Maksudov A.U. Preliminary results of studying the temporal variation of cosmic rays in a new experimental device // DAN RUz, 2012. No 2. R. 20-22.
Maksudov A.U. The patent for the utility model The device for recording earthquake precursors No. FAP 01088 . 04.02.15. Registered in the State Register of Utility Models of the Republic of Uzbekistan, Tashkent, 24.03.16.
Maksudov A.U., Zufarov M.A. // Measurement of neutron and charged particle fluxes toward earthquake prediction // Earthquake Scince, 2017. № 30 (5-6). R. 283-288. https://doi.org/10.1007/ s11589-017-0198-z.
Kramer-Ageev E.A., Lavrenchik V.N., Samosadny V.T., Protasov V.P. Experimental methods of neutron research. M.: Energoatomizdat, 1990.
Abramov A.I. et. all. Osnovi experimentalnikh metodov yadernoi phisiki. M.: Atomizdat, 1970.
Murzin V.S. Introduction to the physics of cosmic rays. M.: Atomizdat, 1979.
Al-Jarallah M. // The Secrets of Atomic Radiation. Dhahran, Saudi Arabia http://faculty.kfupm.edu.sa/PHYS/mibrahim.
Sasaki T., Gunji Ya., Okuda T. Mathematical Modeling of Radon Emanation // Journal of Nuclear Science and Technology, 2004. Vol. 41, No 2. R. 142-151.
Yuldashbaev T.S., Maksudov A.U. Development of a technique for recording earthquake precursors from observations of temporal variations in the flux of cosmic rays and neutrons // DAN RUz, 2010. No 3. R. 37-41.
Yuldashbaev T.S., Maksudov A.U. Preliminary results of studying the temporal variation of cosmic rays in a new experimental device // DAN RUz, 2012. No 2. R. 20-22.
Maksudov A.U. The patent for the utility model The device for recording earthquake precursors No. FAP 01088 . 04.02.15. Registered in the State Register of Utility Models of the Republic of Uzbekistan, Tashkent, 24.03.16.
Maksudov A.U., Zufarov M.A. // Measurement of neutron and charged particle fluxes toward earthquake prediction // Earthquake Scince, 2017. № 30 (5-6). R. 283-288. https://doi.org/10.1007/ s11589-017-0198-z.
Kramer-Ageev E.A., Lavrenchik V.N., Samosadny V.T., Protasov V.P. Experimental methods of neutron research. M.: Energoatomizdat, 1990.
Abramov A.I. et. all. Osnovi experimentalnikh metodov yadernoi phisiki. M.: Atomizdat, 1970.
Murzin V.S. Introduction to the physics of cosmic rays. M.: Atomizdat, 1979.
Al-Jarallah M. // The Secrets of Atomic Radiation. Dhahran, Saudi Arabia http://faculty.kfupm.edu.sa/PHYS/mibrahim.
Keywords:
fission, neutron flux, charged particles, seismic activity, energy, detector.
Related Articles
PUBLIC LAW (STATE LAW) SCIENCES Pages: 35-39 DOI: 10.33693/2541-8025-2024-20-6-35-39 Issue №166197
The Role of the Strategy for the Development of the Mineral Resource Base of the Russian Federation in Improving Strategic Planning of Subsoil Use: Legal Aspect
legislation
subsoil
national security
strategic planning
mineral resource base
Show more
4. MODEL-ORIENTED DESIGN Pages: 33-35 Issue №9439
CREATION OF GLOBAL NETWORKS OF REGISTRATION OF HARBINGERS OF EARTHQUAKE
variation
energy
detector
neutron flux
charged particles
Show more
05.13.18 MATHEMATICAL MODELING, NUMERICAL METHODS AND COMPLEX PROGRAMS Pages: 40-45 Issue №12384
REGRESSIONS MODELS FOR FORECASTING OF EARTHQUAKES
variation
detector
charged particles
the magnitude
the epicenter
Show more
Multiscale modeling for information control and processing Pages: 57-61 DOI: 10.33693/2313-223X-2020-7-3-57-61 Issue №17377
Mathematical modelling of mountain shocks and earthquakes related to volcanism
gravity
energy
volcanism
analysis
approximate equation
Show more
4. PLASMA, HIGH FREQUENCY, MICROWAVE AND LASER TECHNOLOGIES Pages: 33-35 Issue №10450
DATE FOR DETECTING THE EARTHQUAKE PRECURSORS MODERNIZED INSTALLATION
earthquake
detector
neutron flux
charged particles
Show more
3. PLASMA, HIGH FREQUENCY, MICROWAVE AND LASER TECHNOLOGIES Pages: 52-61 Issue №6518
MONITORING OF SEISMIC HARBINGERS FOR THE FORECAST OF EARTHQUAKES
variation
energy
detector
neutron flux
charged particles
Show more
Letters to the editor Pages: 68-71 DOI: 10.33693/2313-223X-2020-7-4-68-71 Issue №17956
Mathematical modeling of the diffusion process of a semiconductor detector
diffusion
drift
surface concentration
diffusion
activation
Show more
Radiation Safety Aspects Pages: 72-76 DOI: 10.33693/2313-223X-2020-7-3-72-76 Issue №17377
The mechanism of anomaly of charged particles before the earthquake
gas emissions
decay
intensity
nuclear interactions
charged particles
Show more
Elements of Computing Systems Pages: 112-118 DOI: 10.33693/2313-223X-2023-10-1-112-118 Issue №22811
Increasing the Reliability of Earthquake Prediction
decay
radon
neutron flux
charged particles
seismic activity
Show more
6. LEGAL SUPPORT OF ENTREPRENEURIAL ACTIVITIES Pages: 70-72 Issue №4641
Category «term» in the legislation about the supply on the market of thermal energy
the market of thermal energy
price
the contract
energy
the condition of the contract
Show more
