The reasons for enormous accumulation of the geodynamic tension in Eastern Turkey: a multidisciplinary study

by

Lev Eppelbaum a

,

Youri Katz b

,

Zvi Ben-Avraham c

a. Azerbaijan State Oil and Industry University, 20 Azadlig Ave., Baku, Azerbaijan
b. Steinhardt Museum of Natural History & National Research Center, Faculty of Life Sciences, Tel Aviv University, Ramat Aviv, Tel Aviv, Israel
c. Department of Geophysics, Faculty of Exact Sciences, Tel Aviv University, Ramat Aviv, Tel Aviv, Israel
* Author to whom correspondence should be addressed
2023.2(2); https://doi.org/10.58396/gges020202
Received: 19 Jan 2024 / Accepted:04 Feb 2024 / Published: 18 Feb 2024

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2023-12-21

Abstract

The catastrophic earthquakes in Eastern Turkey (Eastern Mediterranean) require their geodynamic understanding. The two most decisive events with magnitudes of 7.95 and 7.86 on 06.02.2023, followed by a series of more than 10,000 significant aftershocks. These tragic events led to the death of more than 60 thousand people. The above values indicate the colossal tension created in the Earth's crust. The region where these strongest earthquakes occurred is a complex junction zone of four tectonic plates: Eurasian, Arabian, African, and Anatolian. The joint movement of these plates (consisting, in turn, of tectonic elements of different ages) occurs at an average rate of 6–18 mm per year. After two marked powerful shocks and a series of aftershocks, some sectors of the Anatolian plate shifted to the southwest by more than 11 meters. Our recent publications indicated the presence of a giant, rotating quasi-ring structure below the Easternmost Mediterranean. This research contains significant newly obtained data. The quantitative analysis of the sat-ellite-derived gravity data indicates the lower mantle occurrence of the anomalous target. Examination of the geoid anom-alies map also testifies to the deep origin of this structure. The regional seismic tomography data confirm the presence of anomalous zones at a depth of 1500-1700 km. The GPS vector map and the comprehensive review of paleomagnetic data display the counterclockwise rotation of this structure. Analysis of the recently constructed magnetic field ΔZ pattern commonly proves the presence of this quasi-ring structure. The newly developed paleobiogeographic map is consistent with the proposed physical–geological model. A widespread analysis of tectonic, petrological, and mineralogical data implies a connection between the discovered deep structure and near-surface processes. A crucial for understanding the nature of the considered seismic stress is its location near the expressed bend of the Mesozoic terrane belt, where the Arabian Plate is deeply intruded into the Alpine-Himalayan belt. Thus, the rotation of this giant deep structure may accu-mulate the stress effect retrieved from the satellite, airborne, and surface geophysical observations. We propose that this stress, along with the known Earth’s crust seismological activity in this region, is the causative reason for the catastrophic geodynamic events in Eastern Turkey.
Keywords:

Geodynamics, GPS, gravity, magnetic and paleomagnetic data analysis, geoid isolines, paleobiogeographical scheme, integrated analysis, counterclockwise rotation.

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Email: cmce@sandermanpub.com (Aamina Soung)

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Sanderman Publishing was founded in the United States in 2018 to connect global researchers by providing efficient and impartial publishing services. Starting with the printed journals, Sanderman Publishing have turned all journals to golden open access journals since 2022, which allows readers to read and refer to the content without any cost.