Ключевые слова
корни литосферы
сквозные талики
термофлюидные каналы
Раздел
Статистика
Как цитировать
Аннотация
Представлены результаты исследования глубинного строения литосферы Восточной Сибири. На основе данных о толщине ледяного горизонта многолетней мерзлоты, аномалий силы тяжести, аномалий геомагнитного поля и сейсмологических данных получена модель строения литосферы областей со стабильной толщиной ледяного горизонта. Показано, что районы с большими значениями толщины ледяного горизонта тяготеют к участкам литосферы с мощными, имеющими повышенную плотность и намагниченность, корнями. Сделано предположение, что стабильность горизонтов многолетней мерзлоты обеспечивается холодными блоками корней литосферы, препятствующими поступлению тепла из мантии. Для поиска эндогенных причин климатических рисков в районах с ускоренной деградацией многолетней мерзлоты построены глубинные разрезы земной коры. Анализ данных о толщине ледяного горизонта совместно с глубинными разрезами показал, что определяющее влияние на процесс разрушения мерзлоты оказывают флюидные потоки, поднимающиеся с глубины ~50–100 км вдоль вертикальных разломных зон. Ускоренная деградация мерзлоты над флюидно-магматическими каналами приводит к появлению специ-фических зон таяния в виде сквозных таликов. Проведенные исследования позволяют понять возможные причины разрушения инфраструктуры в зоне мерзлоты и дать прогноз расположения наиболее вероятных районов ускоренной деградации.
Библиографические ссылки
Bogoyavlensky V.I., Bogoyavlensky I.V., Nikonov R.A. Rezultaty aerokosmicheskikh i ekspeditsionnykh issledovany krupnykh vybrosov gaza na Yamale v rayone Bovanenkovskogo mestorozhdeniya // Arktika: ekologiya i ekonomika. 2017. № 3(27). S. 4–17. https://doi.org/10.25283/2223-4594-2017-3-4-17 [Bogoyavlenskiy V. I., Bogoyavlenskiy I.V., Nikonov R.A. Results of aerial, space and field investigations of large gas blowouts near bovanenkovo field on Yamal peninsula // Arctic: Ecology and Economy. 2017. Iss. 3(27). P. 4–17 (in Russian)].
Bogoyavlensky V.I., Sizov O.S., Bogoyavlensky I.V., i dr. Degazatsiya Zemli v Arktike: kompleksnyye issledovaniya rasprostraneniya bugrov pucheniya i termokarstovykh ozer s kraterami vybrosov gaza na poluostrove Yamal // Arktika: ekologiya i ekonomika. 2019. № 4(36). S. 52–68. https://doi.org/10.25283/2223-4594-2019-4-52-68 [Bogoyavlensky V.I., Sizov O.S. , Bogoyavlensky I.V., Nikonov R.A., Kargina T.N. Earth degassing in the Arctic: comprehensive studies of the distribution of frost mounds and thermokarst lakes with gas blowout craters on the Yamal peninsula // Arctic: Ecology and Economy. 2019. Iss. 4 (36). P. 52–68 (in Russian)].
Volkov A.V., Galyamov A.L., Lobanov K.V. Mineralnoye bogatstvo tsirkumarkticheskogo poyasa // Arktika: ekologiya i ekonomika. 2019. № 1 (33). S. 106–117. https://doi.org/10.25283/2223-4594-2019-1-106-117 [Volkov A.V., Galyamov A.L., Lobanov K.V. The mineral wealth of the circum-arctic belt // Arctic: Ecology and Economy. 2019. Iss. 1 (33). P. 106–117 (in Russian)].
Vorobyev A.E. Perspektivy nanotekhnology osvoyeniya gazogidratnykh resursov arkticheskogo shelfa Rossii // Vestnik MGTU. 2016. T. 19. № 1/1. S. 70–81 https://doi.org/10.21443/1560-9278-2016-1/1-70-81 [Vorob’yev A.E. Prospects of nanotechnologies of developing gaseous-hydrate resources of Russian Arctic shelf // Vestnik of MSTU. 2016. V. 19. Iss. 1/1. P. 70–81 (in Russian)].
Gazoprovody i nefteprovody Rossii [Elektronny resurs]. URL: https://energybase.ru/pipeline (data obrashcheniya 03.11.2020) [Russian gas and oil pipelines [Elektronnyj resurs] URL: https://energybase.ru/pipeline (accessed 03.11.2020)].
Konishchev V.N. Reaktsiya vechnoy merzloty na potepleniye klimata // Vestnik Moskovskogo universiteta. Seriya 5. Geografiya. 2009. № 4. S. 10–20 [Konishchev V.N. Response of permafrost to the climate warming // Vestnik Moskovskogo universiteta. Seriya 5, Geografiya. 2009. Iss. 4. P. 10–20 (in Russian)].
Kopytenko Yu.A., Latysheva O.V., Petrova A.A. Vliyaniye razlomnykh zon zemnoy kory na evolyutsiyu tolshchiny i kromki ledyanogo pokrova Arktiki // Trudy Voyenno-kosmicheskoy akademii imeni A.F.Mozhayskogo. 2020. Vyp. 674. S. 207–212 [Kopytenko Yu.A., Latysheva O.V., Petrova A.A. Influence of the Earth's crust fault zones on the evolution of the thickness and edge of the Arctic ice cover // Proceedings of the Military Space Academy named after A. F. Mozhaisky. 2020. Iss. 674. P. 207–212 (in Russian)].
Kopytenko Yu.A., Petrova A.A. Komponenty magnitnykh anomaly Amerazyskogo basseyna // Trudy XV Vserossyskoy konferentsii «Prikladnyye tekhnologii gidroakustiki i gidrofiziki». SPb. 2020a. S. 292–295 [Kopytenko Yu.A., Petrova A.A. Components of magnetic anomalies in the Amerasian basin // Materials of XV conference «Applied technologies of hydroacoustics and Hydrophysics». Saint-Petersburg. 2020a. P. 292–295 (in Russian)].
Kopytenko Yu.A., Petrova A.A. Rezultaty razrabotki i primeneniya komponentnoy modeli magnitnogo polya Zemli v interesakh magnitnoy kartografii i geofiziki // Fundamentalnaya i prikladnaya gidrofizika. 2016. T. 9. № 2. S. 88–106 [Kopytenko Yu.A., Petrova A.A. The development and use of a component model of the Earth's magnetic field for magnetic cartography and geophysics// Fundamentalnaya i prikladnaya gidrofizika. 2016. V. 9. Iss. 2. P. 88–106 (in Russian)].
Kopytenko Yu.A., Petrova A.A. Komponenty morskikh lineynykh magnitnykh anomaly Mirovogo okeana. Ch. 1. Severnaya Atlantika // Fundamentalnaya i prikladnaya gidrofizika. 2018. T. 11 № 4. S. 34–41. https://doi.org/10.7868/S2073667318040056 [Kopytenko Yu.A., Petrova A.A. Components of marine linear magnetic anomalies of the World ocean. Part 1. North Atlantic // Fundamentalnaya i prikladnaya gidrofizika. 2018. V. 11. Iss. 4. P. 34–41 (in Russian].
Kopytenko Yu.A., Petrova A.A. Mirovyye karty komponent magnitnogo polya zemli epokhi 2020 // Trudy XV Vserossyskoy konferentsii «Prikladnyye tekhnologii gidroakustiki i gidrofiziki». SPb. 2020b. S. 288–291 [Kopytenko Yu.A., Petrova A.A. World maps earth's magnetic field component of the epoch 2020 // Materials of XV conf. «Applied technologies of hydroacoustics and Hydrophysics». Saint-Petersburg. 2020b. P. 288–291 (in Russian)].
Kopytenko Yu.A., Petrova A.A., Guryev I.S., Labetsky P.V., Latysheva O.V. Analiz informativnosti magnitnogo polya zemli v okolozemnom kosmicheskom prostranstve // Kosmicheskiye issledovaniya». 2021. T. 59. № 3. S. 185–191. https://doi.org/10.31857/S0023420621030067 [Kopytenko Y.A., Petrova A.A., Alekseev V.F., Gur’ev I.S., Labetskiy P.V. application of altitude models of Earth’s magnetic field for solving geophysical problems. Cosmic Research. 2021. Iss. 57. № 3. P. 163–168. https://doi.org/10.1134/S0010952519030067].
Kopytenko Yu.A., Chernous S.A, Petrova A.A. i dr. Issledovaniya izmeneny polozheniya avroralnogo ovala v usloviyakh smeshcheniya magnitnogo polyusa Zemli // «Sbornik trudov shkoly-konferentsii Problemy Geokosmosa 2018» 2018. S. 338–343 [Kopytenko Yu. A., Chernouss S., Petrova A.A et al. The Study of Auroral Oval Position Changes in Terms of Moving of the Earth Magnetic Pole // Problems of Geocosmos–2018, Springer Proceedings in Earth and Environmental Sciences. 2019. S. 289–296. https://doi.org/10.1007/978-3-030-21788-4_25].
Nalivkina E.B. Evolyutsiya rannedokembryskoy zemnoy kory. SPb.: Izd-vo VSEGEI, 2004. 204 s. [Nalivkina E.B. Evolution of the Early Precambrian crust // SPb: Izd. VSEGEI, 2004. 204 p. (in Russian)].
Nalivkina E.B., Petrova A.A. Magnetitovaya zona zemnoy kory kontinentov. SPb.: Izd. VSEGEI, 2018. 46 s. [Nalivkina E.B., Petrova A.A. The magnetite zone of the continental crust. SPb: Izd. VSEGEI, 2018. 46 p. (in Russian)].
Pavlenko V.I. Arkticheskaya zona Rossyskoy Federatsii v sisteme obespecheniya natsionalnykh interesov strany // Arktika: ekologiya i ekonomika. 2013. № 4 (12). S. 16–25 [Pavlenko V.I. The Arctic zone of the Russian Federation in the system of ensuring the national interests of the country // Arctic: ecologiya and economika. 2013. Iss. 4(12). P 16–25 (in Russian)].
Pavlenkova N.I. Priroda regionalnykh seysmicheskikh granits v zemnoy kore i verkhney mantii // Sbornik trudov fiziko-khimicheskiye i petrofizicheskiye issledovaniya v naukakh o zemle. Moskva. 2018. S. 250–253 [Pavlenkova N.I. Nature of regional seismic boundaries in the earth's crust and upper mantle // Sb. trudov fiziko-khimicheskie i petrofizicheskie issledovaniia v naukakh o zemle. Moscow. 2018. P. 250–253 (in Russian)].
Pavlenkova N.I. Rol flyuidov v formirovanii neodnorodnosti zemnoy kory i verkhney mantii // Sbornik trudov konferentsii Sovremennaya tektonofizika. Metody i rezultaty. Moskva. 2013. S. 56–68 [Pavlenkova N.I. Role of fluids in the formation of inhomogeneity of the earth's crust and upper mantle // Sb. trudov konferentsii Sovremennaia tektonofizika. Metody i rezultaty. Moscow. 2013. P. 56–68 (in Russian)].
Petrishchev M.S., Petrova A.A., Kopytenko Yu.A., Latysheva O.V. Magnitnyye anomalii dokembriya v okolozemnom prostranstve // Materialy 17 konf. «Sovremennyye problemy distantsionnogo zondirovaniya zemli iz kosmosa». IKI RAN. Moskva, 2019. S. 162–163 [Petrishchev M.S., Petrova A.A., Kopytenko Yu.A., Latysheva O.V. Precambrian magnetic anomalies in near-earth space // Materials 17 Conf. «Modern problems of remote sensing of the earth from space». SRI RAS. 2019. Moscow, 2019. P 162–163 (in Russian)].
Petrova A.A. Metodika spektralno-korrelyatsionnogo analiza anomalnogo geomagnitnogo polya // Avtoref. diss. kand. f.-m. nauk. Moskva, 1976. 25 s. [Petrova A.A. Method of spectral correlation analysis of an anomalous geomagnetic field // Avtoref. Diss. kand. ph.-m. nauk. Moscow, 1976. 25p. (in Russian)].
Petrova A.A. Metodika spektralno-prostranstvennogo analiza geomagnitnogo polya // Geofizichesky sbornik AN USSR. 1977. Vyp. 76. S. 55–66 [Petrova A.A. Method of spectral-spatial analysis of the geomagnetic field // Geofizicheskii sbornik AN USSR.1977. Iss. 76. P. 55–66 (in Russian)].
Petrova A.A. Tsifrovyye karty komponent vektora induktsii magnitnogo polya // Sb. trudov IZMIRAN. Moskva. 2015. S. 412–423 [Petrova A.A. Digital maps component of the magnetic field induction vector // Sb. trudov IZMIRAN, Moscow: 2015. P. 412–423 (in Russian)].
Petrova A.A., Karasik A.M. Statisticheskaya zavisimost parametrov spektralnoy struktury magnitnogo polya ot relyefa magnitnogo fundamenta Severnogo Ledovitogo okeana // Okeanologiya. 1979. T. XIX. № 3. S. 526–528 [Petrova A.A. Karasik A.M. Statistical dependence of the parameters of the magnetic field spectral structure on the relief of the magnetic foundation of the Arctic ocean // Oceanology. 1979. V. XIX. Iss. 3. P. 526–528 (in Russian)].
Petrova A.A., Kolesova V.I. Sposob geofizicheskoy razvedki. A.S. 1289232 SSSR. 1986 [Petrova A.A., Kolesova V.I. Method of geophysical exploration. A.S. 1289232 USSR. 1986. (in Russian)].
Petrova A.A., Kopytenko Yu.A. Flyuidnyye sistemy Mamsko-Bodaybinskoy mineragenicheskoy zony Severnogo Zabaykalya // Vestnik KRAUNTs. Seriya: Nauki o Zemle. 2019b. Vyp. 41. №1. S. 37–53. https://doi.org/10.31431/1816-5524-2019-1-41-37-53 [Petrova A.A., Kopytenko Yu.A. Fluid system of the Mamsko-bodaybinskiy mineragenic zone of the Northern Transbaikalia region // Vestnik KRAUNTs. Nauki o Zemle. 2019b.V. 1(41). P. 37–53 (in Russian)].
Petrova A.A., Kopytenko Yu.A. Geotermalnyye zony yuga Vostochnoy Sibiri // Vestnik KRAUNTs. Seriya: Nauki o Zemle. 2019a. Vyp. 42. № 2. S. 25–41. https://doi.org/10.31431/1816-5524-2019-2-42-25-41 [Petrova A.A., Kopytenko Yu.A. Geothermal zones of the south of East Siberia // Vestnik KRAUNTs. Nauki o Zemle. 2019a. V. 2(42). P. 25–41 (in Russian)].
Petrova A.A., Latysheva O.V. Verifikatsiya modeli anomaly komponent magnitnogo polya Arktiki // Materialy Vserossyskoy konferentsii: Globalnyye problemy Arktiki i Antarktiki. FITsKIA RAN. Arkhangelsk 2020. S. 279–284 [Petrova A.A., Latysheva O.V. Verification of the model of anomalies of the Arctic magnetic field components // Proceedings of the International conference «Global Problems of the Arctic and Antarctic». FCIARctic. Arkhangelsk. 2020. P. 279–284 (in Russian)].
Petrova A.A., Latysheva O.V., Kopytenko Yu.A. Opasnyye prirodnyye yavleniya endogennogo kharaktera v Arkticheskoy zone Rossyskoy Federatsii // Materialy Vserossyskoy konferentsii: Globalnyye problemy Arktiki i Antarktiki. FITsKIA RAN. Arkhangelsk 2020a. S. 815–820 [Petrova A.A., Latysheva O.V., Kopytenko Yu.A. Endogenous natural hazards in the Arctic zone of the Russian Federation // Proceedings of the International conference «Global Problems of the Arctic and Antarctic». FCIARctic. Arkhangelsk. 2020a. P. 815–820 (in Russian)].
Petrova A.A., Latysheva O.V., Kopytenko Yu.A. Prirodnyye yavleniya endogennogo proiskhozhdeniya v Arkticheskom basseyne // Vestnik KRAUNTs. Nauki o Zemle. 2020b. № 4. Vyp. 48. S. 37–53. https://doi.org/10.31431/1816-5524-2020-4-48-49-63 [Petrova A.A., Latysheva O.V., Kopytenko Yu.A. Natural phenomena of endogenic origin in the Arctic basin // Vestnik KRAUNTs. Nauki o Zemle. 2020b.V. 4(48). P. 37–53 (in Russian)].
Petrova A.A., Petrishchev M.S. Flyuidnyye sistemy Sredizemnomorya // Vestnik KRAUNTs. Nauki o Zemle. 2011. № 1. Vypusk №17. S. 23–33 [Petrova A.A., Petrishchev M.S. Fluid systems of the Mediterraneann // Vestnik KRAUNTs. Nauki o Zemle. 2011. V. 1(17). P. 23–33 (in Russian)].
Petrova A.A., Petrishchev M.S. Areal bazaltov triasa Urengoyskogo rayona Zapadnoy Sibiri po geomagnitnym dannym // Materialy II shkoly-seminara «Gordinskiye chteniya». IFZ RAN. Moskva. 2013. S. 155–160 [Petrova A.A., Petrishchev M.S. The areal of Triassic basalts in the Urengoy district of Western Siberia according to geomagnetic data // Materials of the II school-seminar « Gordinsky readings ». IFZ RAS. Moscow.2013. P. 155–160 (in Russian)].
Petrova A.A., Petrishchev M.S., Kopytenko Yu.A., Latysheva O.V. Vyyavleniye flyuidopodvodyashchikh kanalov v Arkticheskikh moryakh po anomaliyam magnitnogo i gravitatsionnogo poley // Materialy Vserossyskoy konferentsii: Globalnyye problemy Arktiki i Antarktiki. FITsKIA RAN. Arkhangelsk 2020v. S. 810–815 [Petrova A.A., Petrishchev M.S., Kopytenko Yu.A., Latysheva O.V. Identification of fluid-carrying channels in the Arctic seas by magnetic and gravitational field anomalies // Proceedings of the International conference «Global Problems of the Arctic and Antarctic». FCIARctic. Arkhangelsk. 2020c. P. 810–815 (in Russian)].
Prognozno-mineragenicheskaya karta rossyskoy Federatsii i ee kontinentalnogo shelfa. Masshtab 1:2 500 000 // Gl. redaktor O.V. Petrov. SPb.: Izd-vo VSEGEI, 2016 [Forecast-mineragenic map of the Russian Federation and its continental shelf. Scale 1:2 500 00 // Chief Editor Petrov O.V. SPb.: Izd. VSEGEI, 2016 (in Russian)].
Starostin V.I., Izbekov E.D., Razin L.V., Sakiya D.R. Perspektivy obnaruzheniya krupnykh i unikalnykh mestorozhdeny blagorodnykh metallov na Severo-Vostoke Sibirskoy platformy // Vestnik Moskovskogo universiteta. 2016. S. 34–43 [Starostin V.I., Izbekov E.D., Razin L.V., Sakiya D.R. Perspectives of the detection of large and unique noble metal deposits in the Northeastern Siberian platform // Vestnik Moskovskogo universiteta. Seriâ 4, Geologiâ. 2016. Iss. 2. P. 34–43 (in Russian)].
Stogny G.A., Stogny V.V. Struktura yugo-vostochnogo obramleniya Severo-Aziatskogo kratona // Tektonika kory i mantii. Tektonicheskiye zakonomernosti razmeshcheniya poleznykh iskopayemykh. Materialy XXXVIII Tektonicheskogo soveshchaniya. 2005. T. 2. S. 238–241 [Stogny G.A., Stogny V.V. Structure of the southeastern rim of the North Asian Craton // The proceedings of the XXXVIII Tectonic meeting. 2005. V. 2. P. 238–241 (in Russian)].
Skhema razmeshcheniya metallogenicheskikh zon, rudnykh rayonov i rudnykh uzlov Rossii. Masshtab 1:14 000 000 // SPb.: Izd-vo VSEGEI, 2005 [Placement scheme of metallogenic zones, ore areas and ore nodes in Russia. Scale 1:14 000 000 // SPb.: Izd. VSEGEI, 2005 (in Russian)].
Khromova T.E., Medvedev A.A., Muravyev A.Ya., Zverkova N.M. Elektronny atlas «Sneg i led na Zemle» // Led i sneg. 2015. № 2 (130). S. 5–8. https://doi.org/10.15356/2076-6734-2015-2-5-8 [Khromova T.Y., Medvedev A.A., Muraviev A.Ya., Zverkova N.M. Digital Atlas «Snow and Ice on the Earth» // Ice and Snow. 2015. Iss. 2 (130). P. 5–8 (in Russian)].
Amante C. and Eakins B.W. ETOPO1 1 Arc-Minute Global Relief Model: Procedures, Data Sources and Analysis. NOAA Technical Memorandum NESDIS NGDC-24. National Geophysical Data Center, NOAA. 2009. P. 1–19. https://doi.org/10.7289/V5C8276M.
Artemieva, I.M., Global 1ox1o thermal model TC1 for the continental lithosphere: implications for lithosphere secular evolution // Tectonophysics. 2006. V. 416. P. 245–277.
Bonvalot S., Balmino G., Briais A. et al. World Gravity Map // Commission for the Geological Map of the World. Eds. BGI-CGMW-CNES-IRD. Paris. 2012. http://bgi.omp.obs-mip.fr.
International Seismological Centre (2020). On-line Bulletin [Elektronnyj resurs]. URL: https://doi.org/10.31905/D808B830 (accessed 20.11.2020).
Jansson J.K., Taş N. The microbial ecology of permafrost // Nat. Rev. Microbiol. 2014. V. 6. P. 414–425. https://doi.org/10.1038/nrmicro3262.
Litvinova T., Petrova A. Heterogeneous structure of the lithosphere of the Taimyr Peninsula // Session EMRP2.3/ERE6.7 Advancements in magnetic anomaly studies and natural resources exploration. Vienna. 2016. EGU2016-12688.
Litvinova T., Petrova A. Search a way out of fluid-magmatic activity on the periphery of the thermal structure Siberian magnetic anomaly // Geophysical Research Abstracts. V. 19. EGU General Assembly, Session EMRP2.2/ERE6.6 - Advancements in magnetic field studies and natural resources exploration. Vienna. 2017. EGU2017-12376.
Petrova A.A., Kolesova V.I., Domaratskij S.N. The Space-Spectral Analysis Method in Applied Geophysics // Russian Airborne Geophysics and Remote sensing. Golden. Colorado. 1992. P. 525–534.
Petrova A.A., Kopytenko Y.A., Petrishchev M.S. Deep fluid systems of Fennoscandia greenstone belts // Practical and Teoretical Aspects of Geological Interpretation of Gravitational, Magnetic and Electric Fields. 2019. P. 239–247. https://doi.org/10.1007/978-3-319-97670-9_28.
Pollack H.N., Hurter S.J., Johnson J.R. Heat flow from the Earth’s interior: analysis of the global data set // Rev. Geophysics.1993. V. 31. P. 267–280.
Shur Yu., Kenneth M. Hinkel, Frederick E. Nelson The transient layer: implications for geocryology and climate–change science // Permafrost and Periglac. Process. 2005. V. 16. Iss. 1. P. 5–17. https://doi.org/10.1002/ppp.518.
Stolbovoi V., McCallum I. CD-ROM «Land Resources of Russia», International Institute for Applied Systems Analysis and the Russian Academy of Science. Laxenburg. Austria.2002.
Thebault E., Vigneron P., Langlais B., Hulot G. A Swarm lithospheric magnetic field model to SH degree 80 // Earth, Planets and Space. 2016. V. 68. Iss. 1. P. 1–13. https://doi.org/10.1186/s40623-016-0510-5.
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