Systematization of Ionospheric, Geodynamic, and Thermal Precursors of Strong (М ≥ 6) Earthquakes Registered from Space

 
PIIS020596140002352-8-1
DOI10.31857/S020596140002352-8
Publication type Article
Status Published
Authors
Affiliation: AEROCOSMOS Research Institute for Aerospace Monitoring
Address: Russian Federation
Affiliation: AEROCOSMOS Research Institute for Aerospace Monitoring
Address: Russian Federation
Affiliation: AEROCOSMOS Research Institute for Aerospace Monitoring
Address: Russian Federation
Affiliation: AEROCOSMOS Research Institute for Aerospace Monitoring
Address: Russian Federation
Journal nameIssledovanie Zemli iz kosmosa
EditionIssue 4
Pages3-19
Abstract

Here we describe the features of formation of short- and mid-term strong (М ≥ 6) earthquake precursors registered from space. A database containing variations of parameters of ionospheric, geodynamic, and thermal fi elds registered from space during preparation and running of signifi cant seismic events has been created. This database is an important element of a single system of catastrophic natural disaster comprehensive monitoring. A technique for collection and systematization of satellite and relevant information, as well as data processing methods to obtain information on irregular variations of various geophysical fi elds in seismic regions are presented here. This database contains general information on more than 4000 earthquakes, as well as the characteristics of 80 strong earthquakes (magnitudes from 6.0 to 9.1) occurred in various locations of the world between the years of 1990–2017. Examples of visualization and analysis of data on various precursors of the earthquake in Italy on August 24, 2016 (M = 6.2) contained in the database are given here.

Keywordsearthquakes, earthquake precursors, remote sensing, database, natural disasters
Received22.12.2018
Publication date22.12.2018
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1. Akopyan S.Ts., Bondur V.G., Rogozhin E.A. Tekhnologiya monitoringa i prognozirovaniya sil'nykh zemletryasenij na territorii Rossii s ispol'zovaniem metoda sejsmicheskoj ehntropii // Fizika Zemli. 2017. № 1. S. 34–53.

2. Andrianov V.A., Smirnov V.M. Opredelenie vysotnogo profilya ehlektronnoj kontsentratsii ionosfery Zemli po dvukhchastotnym izmereniyam radiosignalov iskusstvennykh sputnikov Zemli // Radiotekhnika i ehlektronika. 1993. T. 38. № 7. S. 1326.

3. Bondur V.G. Aehrokosmicheskie metody i tekhnologii monitoringa neftegazonosnykh territorij i ob'ektov neftegazovogo kompleksa // Issled. Zemli iz kosmosa. 2010. № 6. S. 3–17.

4. Bondur V.G. Printsipy postroeniya kosmicheskoj siste-my monitoringa Zemli v ehkologicheskikh i prirodnoresursnykh tselyakh // Izv. vuzov. Geodeziya i aehrofotos'emka. 1995. № 2. S. 14–38.

5. Bondur V.G. Sovremennye podkhody k obrabotke bol'shikh potokov giperspektral'noj i mnogospektral'noj aehrokosmicheskoj informatsii // Issled. Zemli iz kosmosa. 2014. № 1. S. 4–17.

6. Bondur V.G., Voronova O.S. Variatsii ukhodyaschego dlinnovolnovogo izlucheniya pri podgotovke i protekanii sil'nykh zemletryasenij na territorii Rossii v 2008 i 2009 godakh // Izv. vuzov. Geodeziya i aehrofotos'emka. 2012. № 1. S. 79–85.

7. Bondur V.G., Garagash I.A, Gokhberg M.B., Rodkin M.V. Ehvolyutsiya napryazhennogo sostoyaniya Yuzhnoj Kalifornii na osnove geomekhanicheskoj modeli i tekuschej sejsmichnosti // Fizika Zemli. 2016. №1. C. 120–132.

8. Bondur V.G., Garagash I.A., Gokhberg M.B., Lapshin V.M., Nechaev Yu.V. Svyaz' mezhdu variatsiyami napryazhenno-deformirovannogo sostoyaniya zemnoj kory i sejsmicheskoj aktivnost'yu na primere Yuzhnoj Kalifornii // Dokl. RAN. 2010. T. 430. № 3. S. 400–404.

9. Bondur V.G., Garagash I.A., Gokhberg M.B., Lapshin V.M., Nechaev Yu.V., Steblov G.M., Shalimov S.L. Geomekhanicheskie modeli i ionosfernye variatsii dlya krupnejshikh zemletryasenij pri slabom vozdejstvii gradientov atmosfernogo davleniya // Dokl. RAN. 2007. T. 414. № 4. S. 540–543.

10. Bondur V.G., Zverev A.T. Kosmicheskij metod prognoza zemletryasenij na osnove analiza dinamiki sistem lineamentov // Issled. Zemli iz kosmosa. 2005a. № 3. S. 37–52.

11. Bondur V.G., Zverev A.T. Metod prognozirovaniya zemletryasenij na osnove lineamentnogo analiza kosmicheskikh izobrazhenij // Dokl. RAN. 2005b. T. 402. № 1. S. 98–105.

12. Bondur V.G., Zverev A.T. Mekhanizmy formirovaniya lineamentov, registriruemykh na kosmicheskikh izobrazheniyakh pri monitoringe sejsmoopasnykh territorij // Issled. Zemli iz kosmosa. 2007. № 1. S. 47–56.

13. Bondur V.G., Zverev A.T., Gaponova E.V., Zima A.L. Issledovanie iz kosmosa deformatsionnykh voln – predvestnikov zemletryasenij, proyavlyayuschikhsya v dinamike lineamentnykh sistem // Issled. Zemli iz kosmosa. 2012. №1. S. 3–20.

14. Bondur V.G., Krapivin V.F., Savinykh V.P. Monitoring i prognozirovanie prirodnykh katastrof. M: Nauchnyj mir, 2009. 692 s.

15. Bondur V.G., Savin A.I. Kontseptsiya sozdaniya sistem monitoringa okruzhayuschej sredy v ehkologicheskikh i prirodno-resursnykh tselyakh // Issled. Zemli iz kosmosa. 1992. № 6. S. 70–78.

16. Bondur V.G., Smirnov V.M. Metod monitoringa sejsmoopasnykh territorij po ionosfernym variatsiyam, registriruemym sputnikovymi navigatsionnymi sistemami // Dokl. RAN. 2005. T. 402. № 5. S. 675–679.

17. Bondur V.G., Starchenkov S.A. Metody i programmy obrabotki i klassifikatsii aehrokosmicheskikh izobrazhenij // Izv. vuzov. Geodeziya i aehrofotos'emka. 2001. № 3. S. 118–143.

18. Gvishiani A.D., Dzeboev B.A., Agayan S.M. O novom podkhode k raspoznavaniyu mest vozmozhnogo vozniknoveniya sil'nykh zemletryasenij na Kavkaze // Fizika Zemli. 2013. № 6. S. 3–19.

19. Zav'yalov A.D. Srednesrochnyj prognoz zemletryasenij. Osnovy, metodika, realizatsiya. M.: Nauka, 2006. 256 s.

20. Zotov O.D., Gul'el'mi A.V., Sobisevich L.E., Sobisevich A.L. O magnitnykh predvestnikakh zemletryasenij // Fizika Zemli. 2013. № 6. S. 139–147.

21. Lyubushin A.A. Analiz kogerentnosti global'nogo sejsmicheskogo shuma, 1997–2012 // Fizika Zemli. 2014. № 3. S. 18–27.

22. Prirodnye opasnosti Rossii. Monogr. v 6 t. T. 2. Sejsmicheskie opasnosti / Otv. red. G.A. Sobolev. M.: Izd-vo «KRUK», 2000. 296 s.

23. Prirodnye opasnosti Rossii. Sejsmicheskie opasnosti / Pod red. V.I. Osipova, S.K. Shojgu. M.: Nedra, 2001. 287 s.

24. Pulinets S.A., Bondur V.G., Tsidilina M.N., Gaponova M.V. Proverka kontseptsii sejsmo-ionosfernykh svyazej v spokojnykh geliogeomagnitnykh usloviyakh na primere Venchuan'skogo zemletryaseniya v Kitae 12 maya 2008 g. // Geomagnetizm i aehronomiya. 2010. T. 50. № 2. S. 240–252.

25. Savin A.I., Bondur V.G. Nauchnye osnovy sozdaniya i diversifikatsii global'nykh aehrokosmicheskikh sistem // Optika atmosfery i okeana. 2000. T.13. № 1. S. 46–62.

26. Sobolev G.A., Ponomarev A.V. Fizika zemletryasenij i predvestniki. M.: Nauka, 2003. 270 s.

27. Tikhonov A.N., Goncharskij A.V., Stepanov V.V. i dr. Regulyariziruyuschie algoritmy i apriornaya informatsiya. M.: Nauka, 1983. 200 s.

28. Fedotov S.A. Dolgosrochnyj sejsmicheskij prognoz dlya Kurilo-Kamchatskoj dugi. M.: Nauka, 2005. 302 s.

29. Baklanov A.A., Bondur V.G., Klaic Z.B., Zilitinkevich S.S. Integration of geospheres in Earth systems: Modern queries to environmental physics, modelling, monitoring and education // Geofi zika. 2012. № 29(2). P. 1–4.

30. Bondur V.G., Kuznetsova L.V. Satellite Monitoring of Seismic Hazard Area Geodynamics Using the Method of Lineament Analysis // 31st Int. Symp. Rem. Sens. Environm. ISRSE, 2005. P. 376–379.

31. Bondur V.G., Smirnov V.M. Monitoring of Ionosphere Variations During the Preparation and Realization of Earthquakes Using Satellite Navigation System Data. // 31st Int. Symp. Rem. Sens. Environm. ISRSE, 2006. P. 372–375.

32. Bondur V.G., Tsidilina M.N., Gaponova E.V., Voronova O.S. Joint analysis of various precursors of seismic events using remote sensing data at the example of earthquake in Italy (24.08.2016, M6.2) // 17-th Int. Multidiscipl. Sci. GeoConf. SGEM 2017, 29 June – 5 July, 2017. Albena, Bulgaria. R. 149–162.

33. Davis C.A., Keilis-Borok V., Molchan G., Shebalin P., Lahr P., Plumb C. Earthquake prediction and disaster preparedness: Interact. anal. // Natural Hazards Review, ASCE. 2010. № 11, 4. R. 173–184.

34. Dey S., Singh R.P. Surface latent heat fl ux as an earthquake precursor // Natural Hazards and Earth Syst. Sci. 2003. V. 3. P. 749–755.

35. Harrison R.G., Aplin K.L., Rycroft M.J. Atmospheric electricity coupling between earthquake regions and the ionosphere // J. Atm. and Solar-Terrestr. Phys. 2010. V. 72 № 5–6. P. 376–381. doi: 10.1016/j.jastp.2009.12.004 http://geoenv.ru

36. Keilis-Borok V., Gabrielov A., Soloviev A. Geo-complexity and earthquake prediction // Encyclopedia of Complexity and Systems Science / Ed. R. Meyers. N.Y.: Springer, 2009. R. 4178–4194.

37. Liu J.Y., Le H., Chen Y.I., Chen C.H., Liu L., Wan W., Su Y.Z., Sun Y.Y., Lin C.H., Chen M.Q. Observations and simulations of seismoionospheric GPS total electron content anomalies before the 12 January 2010 M 7 Haiti earthquake // J. Geophys. Res. 2011. V. 116. № A4.

38. Pulinets S.A., Ouzounov, D.P., Karelin A.V., Davidenko D.V. Physical Bases of the Generation of Short-Term Earthquake Precursors: A Complex Model of Ionization-Induced Geophysical Processes in the Lithosphere–Atmosphere–Ionosphere–Magnetosphere System // Geomagn. and Aeron. 2015. V. 55. № 4. R. 540–558.

39. Sorokin V.M., Hayakawa M. Generation of seismic-related DC electric fi elds and lithosphere-atmosphere-ionosphere coupling // Modern Appl. Sci. 2013. V. 7. № 6. P. 1–25.

40. Tronin A.A. Satellite Remote Sensing in Seismology. A Review // Rem. Sens. 2010. V. 2. № 1. P. 124–150.

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