Increasing the Reliability of Earthquake Prediction
( Pp. 112-118)
More about authors
Rakhimov Rustam Kh.
Doctor of Engineering; Head at the Laboratory No. 1; Institute of Materials Science of the SPA “Physics-Sun” of the Academy of Sciences of the Republic of Uzbekistan; Institute of Renewable Energy Sources
Institute of Materials Science of the SPA “Physics-Sun” of the Academy of Science of Uzbekistan
Tashkent, Republic of Uzbekistan
Institute of Materials Science of the SPA “Physics-Sun” of the Academy of Science of Uzbekistan
Tashkent, Republic of Uzbekistan
Abstract:
This article discusses the possibility of early earthquake prediction using radon monitoring in conjunction with the method of detecting charged particles, which will allow more accurate prediction of the time of the event, with a more accurate indication of the epicenter of the future earthquake and will dramatically reduce such a drawback as false predictions.
How to Cite:
Rakhimov R.Kh. Increasing the Reliability of Earthquake Prediction. Computational Nanotechnology. 2023. Vol. 10. No. 1. Pp. 112–118. (In Rus.) DOI: 10.33693/2313-223X-2023-10-1-112-118
Reference list:
Mavlyanov G.A., Ulomov V.I., Sultankhadzhaev A.N. et al. The phenomenon of changes in chemical and gas (elements and isotopes) compositions of groundwater in periods, preceding and accompanying the earthquake. Priority number and date: No. 129 dated February 21, 1966.
Mavlyanov G.A., Sultankhodzhaev A.N. et al. Anomalous variations of hydrogeochemical parameters of underground waters of Eastern Fergana – a harbinger of the Alai earthquake 2.XI.78 g. Uzbek geol. zh. 1981. No. 2. Pp. 9–13. (In Rus.)
Tashmukhamedov M.G., Ziyavuddinov P.C. Hydrogeoseis-mological effects of the Nazarbayev earthquake of De-cember 2, 1980. Theses of the report all-union meetings: Hydrogeochemical studies on prognostic polygons. Alma-Ata, 1983. Pp. 87–91.
Zakirov T.Z. Features of the distribution of radon concentration in the groundwater of some seismically active zones of Uzbekistan (in connection with the search for earthquake precursors): Abstract of dis. ... of Cand. Sci. (Geol. and Mineral.). Tashkent, 1984.
Zavyalov A.D. The slope of the recurrence graph as a harbinger of strong earthquakes in Kamchatka. Earthquake Forecast. 1984. No. 5. Pp. 173–184. (In Rus.)
Kutsenko M.O., Zavyalov A.D. The probability of an earthquake at the waiting time interval according to the complex of prognostic signs. XII Ural Youth Scientific School of Geophysics. 2011. Pp. 131–136. (In Rus.)
Zavyalov A.D. Analysis of the results of testing the predictive algorithm of GOATS from 1985 to 2000 in various seismically active areas. Physics of the Earth. 2002. No. 4. Pp. 16–30. (In Rus.)
Zavyalov A.D. Map of expected earthquakes in Greece in 1996–2002: Forecast and implementation. Physics of the Earth. 2003a. No. 1. Pp. 3–8. (In Rus.)
Osipov V.I. Natural disasters at the turn of the XXI century. Vestn. RAS. 2001. Vol. 71. No. 4. Pp. 291–302. (In Rus.)
Zavyalov A.D. Retrospective test of the GOAT algorithm for Western Turkey. Physics of the Earth. 2003. No. 11. Pp. 29–41. (In Rus.)
Sobolev G.A., Ponomarev A.V. Acoustic emission and stages of destruction preparation in a laboratory experiment. Volcanology and Seismology. 1999. No. 4–5. Pp. 50–62. (In Rus.)
Sobolev G.A., Ponomarev A.V. Physics of earthquakes and harbingers. Moscow: Nauka, 2003. 270 p.
Chebrov V.N., Saltykov V.A., Serafimova Yu.K. Forecasting of earthquakes in Kamchatka. Moscow: Svetoch Plus, 2011. 304 p.
Kasahara K. Earthquake mechanics. Cambridge: Camb. Univ. Press, 1981. 284 p.
Zavyalov A.D. Algorithm “Map of expected earthquakes” (MEE): Results of three decades of testing and latest findings. Ecological Bulletin of Research Centers of the Black Sea Economic Cooperation (BSEC). 2016. Vol. 2. No. 1. Pp. 81–91.
Zavyalov A.D. Medium-term earthquake forecast: Fundamentals, methodology, implementation. Moscow: Nauka, 2006. 254 p.
Ulomov V.I., Polyakova T.P., Medvedeva N.S. On the long-term forecast of strong earthquakes in Central Asia and in the Black Sea-Caspian region. Physics of the Earth. 2002. No. 4. Pp. 31–47. (In Rus.)
Zavyalov A.D. Algorithm of GOATS: 35 years of testing and recent results. In: Theses report II All-Russian Scientific Conference with international. Participation “Modern methods of seismic hazard assessment and earthquake prediction”. September 29–30, 2021, Moscow: ITPZ RAS, 2021. Pp. 47–48.
Rakhimov R.H., Maksudov A.U. Mechanism of charged particle anomaly before earthquake. Computational Nanotechnology. 2020. Vol. 7. No. 3. Pp. 72–76. (In Rus.)
Rakhimov R.Kh., Jalilov M.L., Makhsudov A.U. Mathematical modelling of mountain shocks and earthquakes related to volcanism. Computational Nanotechnology. 2020. Vol. 7. No. 3. Pp. 57–61.
Rakhimov R.Kh., Makhsudov A.U., Zufarov M.A. Nuclear-radioactive reactions in earth crust the generator of earthquake harbingers. Computational Nanotechnology. 2018. No. 3. Pp. 68–72.
Rakhimov R.H., Umaraliev N., Jalilov M.L., Maksudov A.U. Regression models for earthquake prediction. Computational Nanotechnology. 2018. No. 2. Pp. 40–45. (In Rus.)
Rajapov S.A., Nurboev K.M., Mullagalieva F.G. et al. Development of silicon detectors and electronic blocks for alpha, beta and gamma radiation radiometer. Computational Nanotechnology. 2022. Vol. 9. No. 3. Pp. 45–52. (In Rus.) DOI: 10.33693/2313-223X-2022-9-3-45-52
Muminov A., Rajapov S.A., Rajapov B.S., Rakhimov R.H. Detectors of ionizing radiation based on neutron-doped silicon. Computational Nanotechnology. 2016. No. 4. Pp. 136–137. (In Rus.)
Rakhimov R.H., Muminov R.A., Rajapov S.A. et al. Application of a radonometer based on silicon surface barrier detectors for monitoring radon concentration. Computational Nanotechnology. 2017. No. 2. Pp. 85–88. (In Rus.)
Rajapov S.A., Rajapov B.S., Rakhimov R.H. Features of the technology of manufacturing silicon surface-barrier detectors with a large sensitive working area for measuring the activity of natural isotopes. Computational Nanotechnology. 2018. No. 1. Pp. 151–154. (In Rus.)
Rajapov S.A., Rakhimov R.H., Dzhapklich M. et al. Semiconductor detectors of nuclear radiation based on heterojunction structures Al–αGe–pSi–Au for measuring low-intensity ionizing radiation. Computational Nanotechnology. 2018. No. 3. Pp. 65–67. (In Rus.)
Rajapov S.A., Rakhimov R.H., Rajapov B.S. et al. Development of a radonometer based on silicon detectors with a large sensitive area. Computational Nanotechnology. 2019. Vol. 6. No. 1. Pp. 65–68. (In Rus.)
Rajapov S.A., Rakhimov R.H., Rajapov B.S., Zufarov M.A. Silicon-lithium ΔE alpha radiation detectors for radiometer. Computational Nanotechnology. 2019. Vol. 6. No. 2. Pp. 157–159. (In Rus.)
Rajapov S.A., Rakhimov R.H., Rajapov B.S. et al. Development of silicon diffusion n–p detectors of ionizing radiation. Computational Nanotechnology. 2019. Vol. 6. No. 3. Pp. 112–115. (In Rus.)
Rajapov S.A., Rakhimov R.H., Rajapov B.S., Zufarov M.A. Calculation of the stages of the technological process of manufacturing PPD detectors using computer mathematical modeling and the manufacture of an alpha radiometer based on them. Computational Nanotechnology. 2020. Vol. 7. No. 2. Pp. 21–28. (In Rus.)
https://chem.ru/radon.html
Mavlyanov G.A., Sultankhodzhaev A.N. et al. Anomalous variations of hydrogeochemical parameters of underground waters of Eastern Fergana – a harbinger of the Alai earthquake 2.XI.78 g. Uzbek geol. zh. 1981. No. 2. Pp. 9–13. (In Rus.)
Tashmukhamedov M.G., Ziyavuddinov P.C. Hydrogeoseis-mological effects of the Nazarbayev earthquake of De-cember 2, 1980. Theses of the report all-union meetings: Hydrogeochemical studies on prognostic polygons. Alma-Ata, 1983. Pp. 87–91.
Zakirov T.Z. Features of the distribution of radon concentration in the groundwater of some seismically active zones of Uzbekistan (in connection with the search for earthquake precursors): Abstract of dis. ... of Cand. Sci. (Geol. and Mineral.). Tashkent, 1984.
Zavyalov A.D. The slope of the recurrence graph as a harbinger of strong earthquakes in Kamchatka. Earthquake Forecast. 1984. No. 5. Pp. 173–184. (In Rus.)
Kutsenko M.O., Zavyalov A.D. The probability of an earthquake at the waiting time interval according to the complex of prognostic signs. XII Ural Youth Scientific School of Geophysics. 2011. Pp. 131–136. (In Rus.)
Zavyalov A.D. Analysis of the results of testing the predictive algorithm of GOATS from 1985 to 2000 in various seismically active areas. Physics of the Earth. 2002. No. 4. Pp. 16–30. (In Rus.)
Zavyalov A.D. Map of expected earthquakes in Greece in 1996–2002: Forecast and implementation. Physics of the Earth. 2003a. No. 1. Pp. 3–8. (In Rus.)
Osipov V.I. Natural disasters at the turn of the XXI century. Vestn. RAS. 2001. Vol. 71. No. 4. Pp. 291–302. (In Rus.)
Zavyalov A.D. Retrospective test of the GOAT algorithm for Western Turkey. Physics of the Earth. 2003. No. 11. Pp. 29–41. (In Rus.)
Sobolev G.A., Ponomarev A.V. Acoustic emission and stages of destruction preparation in a laboratory experiment. Volcanology and Seismology. 1999. No. 4–5. Pp. 50–62. (In Rus.)
Sobolev G.A., Ponomarev A.V. Physics of earthquakes and harbingers. Moscow: Nauka, 2003. 270 p.
Chebrov V.N., Saltykov V.A., Serafimova Yu.K. Forecasting of earthquakes in Kamchatka. Moscow: Svetoch Plus, 2011. 304 p.
Kasahara K. Earthquake mechanics. Cambridge: Camb. Univ. Press, 1981. 284 p.
Zavyalov A.D. Algorithm “Map of expected earthquakes” (MEE): Results of three decades of testing and latest findings. Ecological Bulletin of Research Centers of the Black Sea Economic Cooperation (BSEC). 2016. Vol. 2. No. 1. Pp. 81–91.
Zavyalov A.D. Medium-term earthquake forecast: Fundamentals, methodology, implementation. Moscow: Nauka, 2006. 254 p.
Ulomov V.I., Polyakova T.P., Medvedeva N.S. On the long-term forecast of strong earthquakes in Central Asia and in the Black Sea-Caspian region. Physics of the Earth. 2002. No. 4. Pp. 31–47. (In Rus.)
Zavyalov A.D. Algorithm of GOATS: 35 years of testing and recent results. In: Theses report II All-Russian Scientific Conference with international. Participation “Modern methods of seismic hazard assessment and earthquake prediction”. September 29–30, 2021, Moscow: ITPZ RAS, 2021. Pp. 47–48.
Rakhimov R.H., Maksudov A.U. Mechanism of charged particle anomaly before earthquake. Computational Nanotechnology. 2020. Vol. 7. No. 3. Pp. 72–76. (In Rus.)
Rakhimov R.Kh., Jalilov M.L., Makhsudov A.U. Mathematical modelling of mountain shocks and earthquakes related to volcanism. Computational Nanotechnology. 2020. Vol. 7. No. 3. Pp. 57–61.
Rakhimov R.Kh., Makhsudov A.U., Zufarov M.A. Nuclear-radioactive reactions in earth crust the generator of earthquake harbingers. Computational Nanotechnology. 2018. No. 3. Pp. 68–72.
Rakhimov R.H., Umaraliev N., Jalilov M.L., Maksudov A.U. Regression models for earthquake prediction. Computational Nanotechnology. 2018. No. 2. Pp. 40–45. (In Rus.)
Rajapov S.A., Nurboev K.M., Mullagalieva F.G. et al. Development of silicon detectors and electronic blocks for alpha, beta and gamma radiation radiometer. Computational Nanotechnology. 2022. Vol. 9. No. 3. Pp. 45–52. (In Rus.) DOI: 10.33693/2313-223X-2022-9-3-45-52
Muminov A., Rajapov S.A., Rajapov B.S., Rakhimov R.H. Detectors of ionizing radiation based on neutron-doped silicon. Computational Nanotechnology. 2016. No. 4. Pp. 136–137. (In Rus.)
Rakhimov R.H., Muminov R.A., Rajapov S.A. et al. Application of a radonometer based on silicon surface barrier detectors for monitoring radon concentration. Computational Nanotechnology. 2017. No. 2. Pp. 85–88. (In Rus.)
Rajapov S.A., Rajapov B.S., Rakhimov R.H. Features of the technology of manufacturing silicon surface-barrier detectors with a large sensitive working area for measuring the activity of natural isotopes. Computational Nanotechnology. 2018. No. 1. Pp. 151–154. (In Rus.)
Rajapov S.A., Rakhimov R.H., Dzhapklich M. et al. Semiconductor detectors of nuclear radiation based on heterojunction structures Al–αGe–pSi–Au for measuring low-intensity ionizing radiation. Computational Nanotechnology. 2018. No. 3. Pp. 65–67. (In Rus.)
Rajapov S.A., Rakhimov R.H., Rajapov B.S. et al. Development of a radonometer based on silicon detectors with a large sensitive area. Computational Nanotechnology. 2019. Vol. 6. No. 1. Pp. 65–68. (In Rus.)
Rajapov S.A., Rakhimov R.H., Rajapov B.S., Zufarov M.A. Silicon-lithium ΔE alpha radiation detectors for radiometer. Computational Nanotechnology. 2019. Vol. 6. No. 2. Pp. 157–159. (In Rus.)
Rajapov S.A., Rakhimov R.H., Rajapov B.S. et al. Development of silicon diffusion n–p detectors of ionizing radiation. Computational Nanotechnology. 2019. Vol. 6. No. 3. Pp. 112–115. (In Rus.)
Rajapov S.A., Rakhimov R.H., Rajapov B.S., Zufarov M.A. Calculation of the stages of the technological process of manufacturing PPD detectors using computer mathematical modeling and the manufacture of an alpha radiometer based on them. Computational Nanotechnology. 2020. Vol. 7. No. 2. Pp. 21–28. (In Rus.)
https://chem.ru/radon.html
Keywords:
decay, radon, neutron flux, charged particles, seismic activity, energy, detector.
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