Detailed information



The article consist of two parts. In the beginning we show the results of comprehensive research of tectonic settings in Baikal-Stanovaya shear zone. This high seismic geological structure develops in the south margin of the Siberian platform. By interpretation geological and geophysical data we suppose that the Baikal-Stanovaya shear zone has the segmented main fault which can be mapped from the lake of Baikal to the Okhotsk sea. Complex and developed net of the secondary faults can be interpreted by left-lateral theoretical model of deformation ellipsoid. In the second part of article we describes the necessity to consider the data of tectonic studies when conducting hydrogeological zoning of the territory. The results of the study of the mutual distribution of the mapped tectonic disturbances of the Baikal-Stanovaya regional shear zone with established kinematic characteristics and sources of groundwater in the region are presented. It was found that the areas of underground waters are drawn to areas of tectonic tension discharge having predominant faults with shear and thrust-shear kinematics. The results of this research are actual for improving safety in mining Forthemore, this study has additional information for hydrogeological zonation.

For citation: Ageev A. S., Ilaliva R. K., Duryagina A. M., Talovina I. V. A link between spatial distribution of the active tectonic dislocation and groundwater water resources in the Baikal-Stanovaya shear zone. Gornyy informatsionno-analiticheskiy byulleten'. 2019;5:173-180. [In Russ]. DOI: 10.25018/0236-1493-2019-05-0-173-180.



: 5
ISBN: 0236-1493
УДК: 551.243.8
DOI: 10.25018/0236-1493-2019-05-0-173-180
Authors: Ageev A. S., Ilalova R. K., Duryagina A. M., Talovina I. V.

Authors' Information:
A.S. Ageev, Assistant of Chair,
e-mail: ageev_as@pers.spmi.ru, ageev.alesha2011@yandex.ru,
R.K. Ilalova, Assistant of Chair,
I.V. Talovina, Doctor of Geological and Mineralogical Sciences,
Acting Head of Chair,
A.M. Duryagina, Candidate of Geological and Mineralogical Sciences,
Assistant Professor,
Saint-Petersburg Mining University, 199106, Saint-Petersburg, Russia.
Corresponding author: A.S. Ageev, e-mail: ageev_as@pers.spmi.ru.

Key words:
Tectonics, the Baikal-Stanovaya shear zone, strike-slip faults, interpretation of geological-geophysical data, seismology, focal mechanisms, hydrogeological zoning, mineral water sources.


1.        Ageev A. S. Features of the deep structure and expression in geophysical fields regional shift boundaries. Comparison of the main morphology parameters of the San Andreas and Baikal-Stanovaya strike-slip zones, 67th Bergund Huttenmannischer Tag 2016, 2016, pp. 40—45.


2.        Ageev A. S., Egorov A. S. Features of the deep structure of the Baikal-Stanovoy regional shear zone on geological, geophysical and distantional data in the profile 3-DV. Regional'naya geologiya i metallogeniya, 2017, no 70, pp. 36—40 [in Russ].


3.        Ageev A. S., Egorov A. S. The main deep morphology features of the Baikal-Stanovaya shear zone according to result of the interpretation geological and geophysical data. Regional'naya geologiya i metallogeniya, 2017, no 73, pp. 19—23 [in Russ].


4.        Egorov A. S. Glubinnoe stroenie i geodinamika litosphery Severnoiy Evrazii [Deep structure and dynamics of the Northern Eurasia lithosphere], Saint-Peterburg, VSEGEI, 2004, 200 p.


5.        Egorov A. S. Features of deep structure and material composition of the earth crust geostructures inside the continental Russia. Zapiski gornogo instituta, 2015, no 216, pp. 13—30. [in Russ.]


6.        Imaev V. S., Imaeva L. P., Smekalin O. P., Kozmin B. M., Grib N. N., Chipizubov A. V. A seismotectonic map of Eastern Siberia. Geodinamika i tektonofizika, 2016, Vol. 6, no 3, pp. 276—287. [in Russ.]


7.        Imaev V. S., Imaeva L. P., Kozmin B. M. Seismotectonika Olekmo-Stanovoya seismicheskoiy zony (Yuzhnaya Yakutiya). Litosfera. 2005, no 2, pp. 21—40. [in Russ].


8.        Li Xinnan, Huang Weiliang, Pierce Ian, Angster Stephen, Wesnousky Steven Characterizing the Quaternary expression of active faulting along the Olinghouse, Carson, and Wabuska lineaments of the Walker Lane. Geosphere. 2017, vol. 13, no 6, pp. 2119—2136.


9.        Gizzi F. Worldwide trends in research on the San Andreas Fault System. Arabian Journal of Geosciences, 2015, no 12, pp. 10890—10909.


10.    Seminskiy K.Zh. Vnutrennyaya struktura kontinental'nykh razryvnykh zon: tektonofizicheskiy aspekt [Internal structure of continental fracture zones: tectonophysical aspect], Novosibirsk, GEO, 2003, 244 p.


11.    Stumer D., Faulds J. E. Kinematic evolution of the Olinghouse fault and the role of a major sinistral fault in the Walker Lane dextral shear zone, Nevada, USA. Journal of Structural Geology. 2018, no 115, pp. 47—63.


12.    Thatcher W., Savage J., Simpson R. W. The Eastern California Shear Zone as the northward extension of the southern San Andreas Fault. Journal of Geophysical Research: Solid Earth. 2016, no 121, pp. 2904—2914.


13.    Gidrogeologiya SSSR [Hydrogeology of the USSR], Vol. XIX, XX, XXII. Мoscow, Nedra, 1970.


14.    Gledko V. A. Gidrogeologiya. Uchebnoe posobie [Hydrogeology. Study guide], Minsk, 2012, available at: http://www.geokniga.org/books/12731.

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