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On the structure and formation of earthquake sources in the faults located in the subsurface and deep levels of the crust. Part II. Deep level. / Ruzhich, V. V.; Kocharyan, G. G.; Savelieva, V. B. и др.

в: Geodynamics and Tectonophysics, Том 9, № 3, 01.01.2018, стр. 1039-1061.

Результаты исследований: Научные публикации в периодических изданияхстатьяРецензирование

Harvard

Ruzhich, VV, Kocharyan, GG, Savelieva, VB & Travin, AV 2018, 'On the structure and formation of earthquake sources in the faults located in the subsurface and deep levels of the crust. Part II. Deep level', Geodynamics and Tectonophysics, Том. 9, № 3, стр. 1039-1061. https://doi.org/10.5800/GT-2018-9-3-0383

APA

Ruzhich, V. V., Kocharyan, G. G., Savelieva, V. B., & Travin, A. V. (2018). On the structure and formation of earthquake sources in the faults located in the subsurface and deep levels of the crust. Part II. Deep level. Geodynamics and Tectonophysics, 9(3), 1039-1061. https://doi.org/10.5800/GT-2018-9-3-0383

Vancouver

Ruzhich VV, Kocharyan GG, Savelieva VB, Travin AV. On the structure and formation of earthquake sources in the faults located in the subsurface and deep levels of the crust. Part II. Deep level. Geodynamics and Tectonophysics. 2018 янв. 1;9(3):1039-1061. doi: 10.5800/GT-2018-9-3-0383

Author

Ruzhich, V. V. ; Kocharyan, G. G. ; Savelieva, V. B. и др. / On the structure and formation of earthquake sources in the faults located in the subsurface and deep levels of the crust. Part II. Deep level. в: Geodynamics and Tectonophysics. 2018 ; Том 9, № 3. стр. 1039-1061.

BibTeX

@article{9c3b5007fab6472e94f9a16a28dc0ef6,
title = "On the structure and formation of earthquake sources in the faults located in the subsurface and deep levels of the crust. Part II. Deep level",
abstract = "In the part 2 of the study [Ruzhich, Kocharyan, 2017], we aimed at identifying the elements of paleoearthquake sources in the crust, which formed at the hypocentral depths in the exhumed Primorsky segment of the ancient collisional suture. The study area covered the southeastern margin of the Siberian craton (Pribaikalie, East Siberia). Slickensides, pseudo‐tachyllite (basaltic glass) and other petrological evidence of intensive tectonic movements were sampled. The structure of the deep segments of the collisional suture were reconstructed from on the data on coseismic ruptures and faults, and the PT parameters were estimated. In the past decades, similar research problems were actively investigated (e.g. [Sibson, 1973; Byerlee, 1978; Morrow et al., 1992; Hodges, 2004; Kirkpatrick et al., 2012]). In Russia, the interest in studying geological and geophysical features of the deeply denuded areas in ancient faults is still limited [Sherman, 1977; Ruzhich, 1989, 1992, 1997; Savel'eva et al., 2003; Ruzhich et al., 2015; Kocharyan, 2016]. The deeply denuded Primorsky segment of the collisional suture of the Siberian Craton underwent the geological evolution of a billion years. In the analysis, we used additional geological data from the petrology studies of the Main Sayan fault zone and other exhumed fault segments, including the seismogenerating faults in the Mongolia-Baikal region [Zamaraev, Ruzhich, 1978; Zamaraev et al., 1979; Ruzhich et al., 2009]. From the PT conditions for the occurrence of the slickensides, pseudo‐tachylyte, and the Primorsky segment structure, the 40Ar/39Ar method estimated the age of the slickensides containing tourmaline at 673±4.8 Ma, which may correspond to the Neoproterozoic stage of the breakdown of the megacontinent Rodinia. Another dating, 415.4±4.1 Ma, obtained for the muscovite sample from a decompressional rupture, refers to the Early Paleozoic stage in the development of the collisional suture, when accretion of the Siberian Craton and the Olkhon terrain took place [Donskaya et al., 2003; Fedorovsky et al., 2010]. Based on these ages and other available petrological data, the depths of the heterochronous systems of coseismic ruptures were estimated: 18 km in the Neoproterozoic, and 12 km in the Middle Paleozoic stage of the seismotec-tonic evolution of the crust in Pribaikalie. The deep paleoseismological settings need to be further investigated in order to more thoroughly clarify the physical and chemical conditions that contributed to the occurrence of the ancient and recent sources of strong earthquakes in the deep segments of faults in the crust. Such information is a prerequisite for further progress towards resolving the problems of securing seismic safety in various regions.",
keywords = "Collisional suture, Coseismic fault, Exhumation of faults, Friction in faults, Isotopic dating of faults, Model of earthquake preparation, Pseudo‐tachyllite, Seismic safety, Slickenside, ZONE, coseismic fault, collisional suture, exhumation of faults, friction in faults, pseudo-tachyllite, AGE, seismic safety, SEISMICITY, ROCKS, STRENGTH, slickenside, REGION, model of earthquake preparation, isotopic dating of faults, BAIKAL RIFT",
author = "Ruzhich, {V. V.} and Kocharyan, {G. G.} and Savelieva, {V. B.} and Travin, {A. V.}",
year = "2018",
month = jan,
day = "1",
doi = "10.5800/GT-2018-9-3-0383",
language = "English",
volume = "9",
pages = "1039--1061",
journal = "Geodynamics and Tectonophysics",
issn = "2078-502X",
publisher = "Institute of the Earth's Crust",
number = "3",

}

RIS

TY - JOUR

T1 - On the structure and formation of earthquake sources in the faults located in the subsurface and deep levels of the crust. Part II. Deep level

AU - Ruzhich, V. V.

AU - Kocharyan, G. G.

AU - Savelieva, V. B.

AU - Travin, A. V.

PY - 2018/1/1

Y1 - 2018/1/1

N2 - In the part 2 of the study [Ruzhich, Kocharyan, 2017], we aimed at identifying the elements of paleoearthquake sources in the crust, which formed at the hypocentral depths in the exhumed Primorsky segment of the ancient collisional suture. The study area covered the southeastern margin of the Siberian craton (Pribaikalie, East Siberia). Slickensides, pseudo‐tachyllite (basaltic glass) and other petrological evidence of intensive tectonic movements were sampled. The structure of the deep segments of the collisional suture were reconstructed from on the data on coseismic ruptures and faults, and the PT parameters were estimated. In the past decades, similar research problems were actively investigated (e.g. [Sibson, 1973; Byerlee, 1978; Morrow et al., 1992; Hodges, 2004; Kirkpatrick et al., 2012]). In Russia, the interest in studying geological and geophysical features of the deeply denuded areas in ancient faults is still limited [Sherman, 1977; Ruzhich, 1989, 1992, 1997; Savel'eva et al., 2003; Ruzhich et al., 2015; Kocharyan, 2016]. The deeply denuded Primorsky segment of the collisional suture of the Siberian Craton underwent the geological evolution of a billion years. In the analysis, we used additional geological data from the petrology studies of the Main Sayan fault zone and other exhumed fault segments, including the seismogenerating faults in the Mongolia-Baikal region [Zamaraev, Ruzhich, 1978; Zamaraev et al., 1979; Ruzhich et al., 2009]. From the PT conditions for the occurrence of the slickensides, pseudo‐tachylyte, and the Primorsky segment structure, the 40Ar/39Ar method estimated the age of the slickensides containing tourmaline at 673±4.8 Ma, which may correspond to the Neoproterozoic stage of the breakdown of the megacontinent Rodinia. Another dating, 415.4±4.1 Ma, obtained for the muscovite sample from a decompressional rupture, refers to the Early Paleozoic stage in the development of the collisional suture, when accretion of the Siberian Craton and the Olkhon terrain took place [Donskaya et al., 2003; Fedorovsky et al., 2010]. Based on these ages and other available petrological data, the depths of the heterochronous systems of coseismic ruptures were estimated: 18 km in the Neoproterozoic, and 12 km in the Middle Paleozoic stage of the seismotec-tonic evolution of the crust in Pribaikalie. The deep paleoseismological settings need to be further investigated in order to more thoroughly clarify the physical and chemical conditions that contributed to the occurrence of the ancient and recent sources of strong earthquakes in the deep segments of faults in the crust. Such information is a prerequisite for further progress towards resolving the problems of securing seismic safety in various regions.

AB - In the part 2 of the study [Ruzhich, Kocharyan, 2017], we aimed at identifying the elements of paleoearthquake sources in the crust, which formed at the hypocentral depths in the exhumed Primorsky segment of the ancient collisional suture. The study area covered the southeastern margin of the Siberian craton (Pribaikalie, East Siberia). Slickensides, pseudo‐tachyllite (basaltic glass) and other petrological evidence of intensive tectonic movements were sampled. The structure of the deep segments of the collisional suture were reconstructed from on the data on coseismic ruptures and faults, and the PT parameters were estimated. In the past decades, similar research problems were actively investigated (e.g. [Sibson, 1973; Byerlee, 1978; Morrow et al., 1992; Hodges, 2004; Kirkpatrick et al., 2012]). In Russia, the interest in studying geological and geophysical features of the deeply denuded areas in ancient faults is still limited [Sherman, 1977; Ruzhich, 1989, 1992, 1997; Savel'eva et al., 2003; Ruzhich et al., 2015; Kocharyan, 2016]. The deeply denuded Primorsky segment of the collisional suture of the Siberian Craton underwent the geological evolution of a billion years. In the analysis, we used additional geological data from the petrology studies of the Main Sayan fault zone and other exhumed fault segments, including the seismogenerating faults in the Mongolia-Baikal region [Zamaraev, Ruzhich, 1978; Zamaraev et al., 1979; Ruzhich et al., 2009]. From the PT conditions for the occurrence of the slickensides, pseudo‐tachylyte, and the Primorsky segment structure, the 40Ar/39Ar method estimated the age of the slickensides containing tourmaline at 673±4.8 Ma, which may correspond to the Neoproterozoic stage of the breakdown of the megacontinent Rodinia. Another dating, 415.4±4.1 Ma, obtained for the muscovite sample from a decompressional rupture, refers to the Early Paleozoic stage in the development of the collisional suture, when accretion of the Siberian Craton and the Olkhon terrain took place [Donskaya et al., 2003; Fedorovsky et al., 2010]. Based on these ages and other available petrological data, the depths of the heterochronous systems of coseismic ruptures were estimated: 18 km in the Neoproterozoic, and 12 km in the Middle Paleozoic stage of the seismotec-tonic evolution of the crust in Pribaikalie. The deep paleoseismological settings need to be further investigated in order to more thoroughly clarify the physical and chemical conditions that contributed to the occurrence of the ancient and recent sources of strong earthquakes in the deep segments of faults in the crust. Such information is a prerequisite for further progress towards resolving the problems of securing seismic safety in various regions.

KW - Collisional suture

KW - Coseismic fault

KW - Exhumation of faults

KW - Friction in faults

KW - Isotopic dating of faults

KW - Model of earthquake preparation

KW - Pseudo‐tachyllite

KW - Seismic safety

KW - Slickenside

KW - ZONE

KW - coseismic fault

KW - collisional suture

KW - exhumation of faults

KW - friction in faults

KW - pseudo-tachyllite

KW - AGE

KW - seismic safety

KW - SEISMICITY

KW - ROCKS

KW - STRENGTH

KW - slickenside

KW - REGION

KW - model of earthquake preparation

KW - isotopic dating of faults

KW - BAIKAL RIFT

UR - http://www.scopus.com/inward/record.url?scp=85055621971&partnerID=8YFLogxK

U2 - 10.5800/GT-2018-9-3-0383

DO - 10.5800/GT-2018-9-3-0383

M3 - Article

AN - SCOPUS:85055621971

VL - 9

SP - 1039

EP - 1061

JO - Geodynamics and Tectonophysics

JF - Geodynamics and Tectonophysics

SN - 2078-502X

IS - 3

ER -

ID: 17245111