Evaluation of Displacements Caused by Strike-Slip Deformations Using Correlation Characteristics Based on Potential Field Data
Author:
Senchina Natalia111ORCID, Asoskov Artem2, Gorelik Gleb1
Affiliation:
1. Saint Petersburg Mining University 2. Russian Geological Research Institute (VSEGEI)
Abstract
The identification of faults is a common objective in geophysical potential field methods. Vertical discontinuities such as reverse faults, also known as tectonic faults, can easily be distinguished through their effect on gravity and magnetic fields, appearing as gradient zones or areas of change in the field. However, identifying strike-slip faults is one of the biggest challenges for potential field methods as they are characterized by a complex series of anomalies with varying signs in the fault zone, as well as displacement of anomaly axes between the strike-slipped blocks. The goal of this study is to suggest a transformation that would aid in the identification of shear zones through the calculation of the displacement along the discontinuity. The proposed approach involves calculating the correlation coefficient between parallel profiles using moving windows. The position of the window with the highest calculated correlation coefficient allows estimating of the discontinuity displacement magnitude. The method was tested using a synthetic field and data from the magnetic field of the Kolbeinsi Ridge.
Publisher
Geophysical Center of the Russian Academy of Sciences
Subject
General Earth and Planetary Sciences
Reference33 articles.
1. Ageev, A. S., R. K. Ilalova, A. M. Duryagina, and I. V. Talovina (2019), A link between spatial distribution of the active tectonic dislocation and groundwater water resources in the Baikal-Stanovaya shear zone, Mining Informational and analytical bulletin, 5, 173–180, https://doi.org/10.25018/0236-1493-2019-05-0-173-180 (in Russian)., Ageev, A. S., R. K. Ilalova, A. M. Duryagina, and I. V. Talovina (2019), A link between spatial distribution of the active tectonic dislocation and groundwater water resources in the Baikal-Stanovaya shear zone, Mining Informational and analytical bulletin, 5, 173–180, https://doi.org/10.25018/0236-1493-2019-05-0-173-180 (in Russian). 2. Akhverdiev, A. T., N. T. Karimova, D. A. Kozhevnikova, and T. E. Karimova (2018), Origin of deep faults and their classification, Science, Technology and Education, 8(49), 15–22 (in Russian)., Akhverdiev, A. T., N. T. Karimova, D. A. Kozhevnikova, and T. E. Karimova (2018), Origin of deep faults and their classification, Science, Technology and Education, 8(49), 15–22 (in Russian). 3. Alekseev, V. (2020), Deep structure and geodynamic conditions of granitoid magmatism in the Eastern Russia, Journal of Mining Institute, 243, 259, https://doi.org/10.31897/pmi.2020.3.259., Alekseev, V. (2020), Deep structure and geodynamic conditions of granitoid magmatism in the Eastern Russia, Journal of Mining Institute, 243, 259, https://doi.org/10.31897/pmi.2020.3.259. 4. Alekseev, V. (2021), Tectonic and magmatic factors of Li-F granites localization of the East of Russia, Journal of Mining Institute, 248, 173–179, https://doi.org/10.31897/pmi.2021.2.1., Alekseev, V. (2021), Tectonic and magmatic factors of Li-F granites localization of the East of Russia, Journal of Mining Institute, 248, 173–179, https://doi.org/10.31897/pmi.2021.2.1. 5. Arkadiev, N. A. (1969), On the structures of ore fields in connection with shear deformations, Journal of Mining Institute, 58(2), 100–105 (in Russian)., Arkadiev, N. A. (1969), On the structures of ore fields in connection with shear deformations, Journal of Mining Institute, 58(2), 100–105 (in Russian).
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