The Fine Structure of Coseismic Electromagnetic Response Based on Geomagnetic and Seismological Observations

A. A. Soloviev; Соловьев А. А.; I. M. Aleshin; Алешин И. М.; S. V. Anisimov; Анисимов С. В.; A. G. Goev; Гоев А. Г.; A. N. Morozov; Морозов А. Н.; D. S. Sapronov; Сапронов Д. С.; E. N. Solovieva; Соловьева Е. Н.

doi:10.31857/S0002333724050141

The Fine Structure of Coseismic Electromagnetic Response Based on Geomagnetic and Seismological Observations

作者: Soloviev A.A.¹^,2, Aleshin I.M.¹^,2, Anisimov S.V.², Goev A.G.²^,3, Morozov A.N.¹^,2, Sapronov D.S.¹, Solovieva E.N.¹^,2
隶属关系:
1. Geophysical Center, Russian Academy of Sciences
2. Schmidt Institute of Physics of the Earth, Russian Academy of Sciences
3. Sadovsky Institute of Geosphere Dynamics, Russian Academy of Sciences
期: 编号 5 (2024)
页面: 195-209
栏目: Articles
URL: https://journals.rcsi.science/0002-3337/article/view/272064
DOI: https://doi.org/10.31857/S0002333724050141
EDN: https://elibrary.ru/EJBUYC
ID: 272064

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This paper examines the response in geomagnetic field variations caused by the 2020–2023 earthquakes with magnitudes Mw ≥ 7.0 in the Aegean Sea and eastern Turkey. A detailed comparison of high-precision observations of the geomagnetic field and seismograms recorded at complex geophysical observatories within a radius of 3000 km from the epicenters was carried out. The joint analysis involves averaged 1-s data on the rate of change of the magnetic field and records from broadband seismic stations. Their characteristics are assessed in both time and frequency domains. The spectral characteristics of body and surface waves are separately compared with those of the geomagnetic signal. It is shown that the beginning of disturbance in the magnetic field at each observatory strictly coincides with the arrival of the P-wave and intensifies with the arrival of S-waves. The maximum geomagnetic disturbance is caused by surface waves. The amplitude of electromagnetic excitations is proportional to the amplitude of the parent seismic phases. Thus, the coseismic nature of the observed electromagnetic signal has been confirmed, suggesting its excitation in the Earth’s crust as seismic waves propagate.

关键词

earthquake, seismoelectromagnetic effects, geomagnetic field, seismology, coseismic effect

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作者简介

A. Soloviev

Geophysical Center, Russian Academy of Sciences; Schmidt Institute of Physics of the Earth, Russian Academy of Sciences

编辑信件的主要联系方式.
Email: a.soloviev@gcras.ru
俄罗斯联邦, Moscow, 119296; Moscow, 123995

I. Aleshin

Geophysical Center, Russian Academy of Sciences; Schmidt Institute of Physics of the Earth, Russian Academy of Sciences

Email: a.soloviev@gcras.ru
俄罗斯联邦, Moscow, 119296; Moscow, 123995

S. Anisimov

Schmidt Institute of Physics of the Earth, Russian Academy of Sciences

Email: a.soloviev@gcras.ru
俄罗斯联邦, Moscow, 123995

A. Goev

Schmidt Institute of Physics of the Earth, Russian Academy of Sciences; Sadovsky Institute of Geosphere Dynamics, Russian Academy of Sciences

Email: a.soloviev@gcras.ru
俄罗斯联邦, Moscow, 123995; Moscow, 119334

A. Morozov

Geophysical Center, Russian Academy of Sciences; Schmidt Institute of Physics of the Earth, Russian Academy of Sciences

Email: a.soloviev@gcras.ru
俄罗斯联邦, Moscow, 119296; Moscow, 123995

D. Sapronov

Geophysical Center, Russian Academy of Sciences

Email: a.soloviev@gcras.ru
俄罗斯联邦, Moscow, 119296

E. Solovieva

Geophysical Center, Russian Academy of Sciences; Schmidt Institute of Physics of the Earth, Russian Academy of Sciences

Email: a.soloviev@gcras.ru
俄罗斯联邦, Moscow, 119296; Moscow, 123995

参考

Адушкин В.В., Овчинников В.М., Санина И.А., Ризниченко О.Ю. “Михнево”: от сейсмостанции № 1 до современной геофизической обсерватории // Физика Земли. 2016. № 1. С. 108–119. doi: 10.7868/S0002333715060010
Антоновская Г.Н., Конечная Я.В., Ваганова Н.В., Басакина И.М., Морозов А.Н., Шахова Е.В., Михайлова Я.А., Данилов К.Б. Вклад уникальной научной установки “Архангельская сейсмическая сеть” в изучение сейсмичности Российской Арктики // Геодинамика и тектонофизика. 2022. Т. 13. № 2. С. 1–8.
Гвишиани А.Д., Соловьёв А.А., Сидоров Р.В., Краснопёров Р.И., Груднев А.А., Кудин Д.В., Карапетян Д.К., Симонян А.О. Успехи организации геомагнитного мониторинга в России и ближнем зарубежье // Вестник ОНЗ РАН. 2018. № 10. NZ4001. doi: 10.2205/2018NZ000357
Гоев А.Г., Алешин И.М., Константиновская Н.Л., Резниченко Р.А., Юдочкин Н.А., Дробышев М.Н. Новые широкополосные сейсмические станции в центральной части Восточно-европейской платформы // Физика Земли. 2024. (подана в редакцию)
Иванов А.Г. Эффект электризации пластов земли при прохождении через них упругих волн // Докл. АН СССР. 1939. Т. 24. № 1. С. 41–43.
Канониди Х.Д. Об источнике особого вида геомагнитных пульсаций во время землетрясений // Изв. ВУЗов. Северо-кавказский регион. Естественные науки. № 2. 2014. С. 29–44.
Кудин Д.В., Соловьев А.А., Сидоров Р.В., Старостенко В.И., Сумарук Ю.П., Легостаева О.В. Система ускоренной подготовки квазиокончательных данных стандарта ИНТЕРМАГНЕТ // Геомагнетизм и аэрономия. 2021. Т. 61. № 1. С. 46–59. doi: 10.31857/S0016794021010090
Рябова С.А., Шалимов С.Л. О геомагнитных вариациях, наблюдаемых на поверхности Земли и приуроченных к сильным землетрясениям // Физика Земли. 2022. № 4. С. 30–45. doi: 10.31857/S0002333722040081
Смирнов В.Б., Шебалин П.Н. От редколлегии журнала “Физика Земли” // Физика Земли. 2023. № 6. C. 3–4. doi: 10.31857/S0002333723060121
Соловьев А.А. Геомагнитный эффект землетрясений Mw = 7.5–7.8 в Турции 6 февраля 2023 г. // Докл. РАН. Науки о Земле. 2023. Т. 511. № 1. С. 78–85. doi: 10.31857/S2686739723600613
Соловьев А.А., Кудин Д.В., Сидоров Р.В., Котиков А.Л. Детектирование геомагнитного джерка 2020 г. по оперативным данным магнитных обсерваторий “Санкт-Петербург” и “Климовская” // Докл. РАН. Науки о Земле. 2022. Т. 507. № 1. С. 85–90. doi: 10.31857/S2686739722601375
Соловьев А.А., Сидоров Р.В., Красноперов Р.И., Груднев А.А., Хохлов А.В. Новая геомагнитная обсерватория “Климовская” // Геомагнетизм и аэрономия. 2016. Т. 56. № 3. С. 365–379.
Ahmad R.A., Singh R.P., Adris A. Seismic hazard assessment of Syria using seismicity, DEM, slope, active faults and GIS // Remote Sensing Applications: Society and Environment. 2017. V. 6. P. 59–70. doi: 10.1016/j.rsase.2017.04.003
Akkar S., Azak T., Çan T. et al. Evolution of seismic hazard maps in Turkey // Bulletin of Earthquake Engineering. 2018. V. 16. P. 3197–3228. doi: 10.1007/s10518-018-0349-1
Alver F., Kılıçarslan Ö., Kuterdem K., Türkoğlu M., Şentürk M.D. Seismic Monitoring at the Turkish National Seismic Network (TNSN) // Summ. Bull. Internatl. Seismol. Cent., July–December 2017. 2019. 53(II). P. 41–58. doi: 10.31905/D9GRP8RD
Güvercin S.E., Karabulut H., Konca A.O., Doğan U., Ergintav S. Active seismotectonics of the East Anatolian Fault // Geophysical Journal International. 2022. V. 230. № 1. P. 50–69. doi: 10.1093/gji/ggac045
Hayakawa M., Kasahara Y., Nakamura T., MutoF., Horie T., Maekawa S., Hobara Y., Rozhnoi A.A., Solovieva M., Molchanov O.A. A statistical study on the correlation between lower ionospheric perturbations as seen by subionospheric VLF/LF propagation and earthquakes // J. Geophys. Res. 2010. V. 115.A09305. doi: 10.1029/2009JA015143
International Seismological Centre. 2024a. International Seismograph Station Registry (IR). doi: 10.31905/EL3FQQ40
International Seismological Centre. 2024b. On-line Bulletin. doi: 10.31905/D808B830
Kadirioğlu F.T., Kartal R.F. The new empirical magnitude conversion relations using an improved earthquake catalogue for Turkey and its near vicinity (1900–2012) // Turkish Journal of Earth Sciences. 2016. V. 25. № 4. P. 300–310. doi: 10.3906/yer-1511-7
Kudin D., Soloviev A., Matveev M., Shevaldysheva O. On a novel approach to correcting temperature dependencies in magnetic observatory data // Applied Sciences. 2023. V. 13. № 14 8008. doi: 10.3390/app13148008
Molchanov O. A., Hayakawa M. Seismo-Electromagnetics and Related Phenomena: History and Latest Results // TERRAPUB. Tokyo. 2008. 189 p.
Molchanov O., Kulchitsky A., Hayakawa M. Inductive seismo-electromagnetic effect in relation to seismogenic ULF emission // Nat. Hazards Earth Syst. Sci. 2001. V. 1. P. 61–67. doi: 10.5194/nhess-1-61-2001
Sakkas V. Ground Deformation Modelling of the 2020 Mw 6.9 Samos Earthquake (Greece) Based on InSAR and GNSS Data // Remote Sens. 2021. V. 13. 1665. doi: 10.3390/rs13091665
Soloviev A., Dobrovolsky M., Kudin D., Sidorov R. Minute values of X, Y, Z components and total intensity F of the Earth’s magnetic field from Geomagnetic Observatory Klimovskaya (IAGA code: KLI)ESDB repository. Geophysical Center of the Russian Academy of Sciences. 2015. doi: 10.2205/kli2011min
Soloviev A., Dzeboev B., Karapetyan J., Grudnev A., Kudin D., Sidorov R., Nisilevich M., Krasnoperov R. Minute values of X, Y, Z components and total intensity F of the Earth’s magnetic field from Geomagnetic Observatory Gyulagarak (IAGA code: GLK). ESDB repository. Geophysical Center of the Russian Academy of Sciences. 2020. doi: 10.2205/GLK2020min
Soloviev A., Gvishiani A., Turuntaev S., Sidorov R., Ryakhovsky I., Kudin D., Krasnoperov R., Grudnev A. 1-second sampled values of X, Y, Z components and total intensity F of the Earth’s magnetic field from Geomagnetic Observatory Mikhnevo (IAGA code: MHV). ESDB repository. 2023. Moscow. doi: 10.2205/MHV2023sec
Soloviev A., Kopytenko Y., Kotikov A., Kudin D., Sidorov R., Matveev M. 2020 definitive data from geomagnetic observatory Saint Petersburg (IAGA code: SPG): minute values of X, Y, Z components and total intensity F of the Earth’s magnetic field. ESDB repository, GCRAS. 2021. Moscow. doi: 10.2205/SPG2020min-def
St-Louis B. INTERMAGNET Operations Committee and Executive Council, 2020. INTERMAGNET Technical Reference Manual, Version 5.0.0
Surkov V.V., Pilipenko V.A., Sinha A.K. Possible mechanisms of co-seismic electromagnetic effect // ActaGeod.Geophys. 2018. V. 53. P. 157–170. doi: 10.1007/s40328-018-0211-6
Thomson A.W.P., Flower S.M. Modernizing a global magnetic partnership // Eos. 2021. V. 102. doi: 10.1029/2021EO156569
Yamazaki K. Revised set of equations describing the seismo-electromagnetic coupled wave field in an ambient geomagnetic field // Geophysical Journal International. 2024. V. 236. № 2. P. 946–951. doi: 10.1093/gji/ggad461

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2. Fig. 1. Map of earthquake epicenters with magnitude Mw ≥ 7 for the period 01.01.2020–02/15/2024. according to USGS data (gray circles), selected magnetic observatories providing 1-second data (black stars – observatories of the INTERMAGNET network, hollow stars – not included in the INTERMAGNET observatories), and seismic stations (indicated by triangles).

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3. Fig. 2. Graphs Fs (top) and dF (bottom) for 10/30/2020, plotted from the second data of the BDV (a) and KLI (b) observatories, and for February 5-6, 2023 from the second data of the GLK (c) and KLI (d) observatories. The moments of the first entry are indicated by vertical dotted lines.

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4. Fig. 3. Graphs of geomagnetic indices Kp, ap (top) and Dst (bottom) for October 29-30, 2020 (a) and February 5-6, 2023 (b).

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5. Fig. 4. Noise characteristics of the data of the variometers of the KLI (a) and MHVg (b) observatories based on 1-second observations of the vertical Z-component.

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6. Fig. 5. Examples of combined graphs of the northern (upper), eastern (middle) and vertical (lower) components of the displacements (blue) and dB/dt (orange) in normalized form minus the average according to a pair of observations KLM-KLI for ZT-1 (a); VJF-SPG for ZT-2 (b); KHC-BDV for ZT-2 (c); MHVs-MHVg for ZT-3 (d); TASB-GLK for ZT-3 (e). The vertical dotted line indicates the moment of arrival of the P-wave at the corresponding seismic station.

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7. Fig. 6. Examples of periodograms based on normalized data for three displacement components (blue) and two horizontal components of the rate of change of the magnetic field (orange) recorded in a 15-minute interval from the moment of the first entry: pairs of observation points GKP-HLP and MHVs-MHVg for the event ZT-1 (a); KHC-BDV and ADZR-KLI for the ZT-2 event (b); TASB-GLK and PUL-SPG for the ZT-3 event (c).

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8. Fig. 7. Periodograms of the Z-components of the seismic signal during the passage of the Rayleigh wave (above) and three components (X, Y, Z) of the dB/dt electromagnetic response at three pairs of observation points: VJF-SPG (ZT-1) (a); MHVs-MHVg (ZT-3) (b); PUL-SPG (ZT-3) (b).

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9. Fig. 8. Periodograms of the seismic signal module |(N, Z)| during the passage of volumetric P and S waves (above) and three components (X, Y, Z) of the dB/dt electromagnetic response at a pair of MHVs-MHVg observation points for the ZT-2 event.

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