The Stress–Strain State of Recent Structures in the Northeastern Sector of the Russian Arctic Region

Doklady Earth Sciences - Complex research to determine the stress–strain state of the Earth’s crust and the types of seismotectonic destruction for the northeastern sector of the...     

Neotectonics of the Kharaulakh sector of the Laptev Shelf

Seismotectonic deformation and crustal stress pattern have been studied comprehensively in major seismogenic structures of the Kharaulakh sector of the Verkhoyansk fold system and adjacent parts of the Chersky seismotectonic zone. The study focuses on neotectonic structures, deep structure, and systems of active faults, as well as tectonic stress fields inferred by tectonophysical analysis of Late Cenozoic faults and folds. The results, along with geological and geophysical data, reveal main strain directions and structural patterns of crustal stress and strain in the Arctic segment of the Eurasia-North America plate boundary. The area is a junction of mid-ocean and continental structures evolving in a mixed setting of extension, compression, and their various combinations. The rotation pole of the two plates is presumably located near Buor-Khaya Bay. In this case, extension is expected to act currently upon the neotectonic structures north of the bay and compression to control those in the south and southeast. This inference is consistent with the identified zoning of stress and strain in the Kharaulakh sector.     

Seismotectonic studies of the pleistoseist area of the <Emphasis Type="Italic">M</Emphasis> <Subscript> <Emphasis Type="Italic">s</Emphasis> </Subscript> = 6.9 Ilin-Tass earthquake in northeast Yakutia

The complex seismotectonic studies of the pleistoseist area of the Ilin-Tas earthquake (M_s = 6.9), one of the strongest seismic events ever recorded by the regional seismic network in northeastern Russia, are carried out. The structural tectonic position, morphotectonic features of present-day topography, active faults, and types of Cenozoic deformations of the epicentral zone are analyzed. The data of the instrumental observations are summarized, and the manifestations of the strong seismic events in the Yana–Indigirka segment of the Cherskii seismotectonic zone are considered. The explanation is suggested for the dynamical tectonic setting responsible for the Andrei-Tas seismic maximum. This setting is created by the influence of the Kolyma–Omolon indenter, which intrudes into the Cherskii seismotectonic zone from the region of the North American lithospheric plate and forms the main seismogenic structures of the Yana–Indigirka segment in the frontal zone (the Ilin-Tas anticlinorium). The highest seismic potential is noted in the Andrei- Tas block—the focus of the main tectonic impacts from the Kolyma–Omolon superterrane. The general trend of this block coincides with the orientation of the major axis of isoseismal ellipses (azimuth 50°–85°), which were determined from the observations of macroseismic effects on the ground after the Uyandina (M_s = 5.6), Andrei-Tas (M_s = 6.1), and Ilin-Tas (M_s = 6.9) earthquakes.     

Detailed geological-geophysical studies of active fault zones and the seismic hazard in the south Yakutia region

Active faults play the key role in the formation of the morphological structures and control the seismicity in the Olekma-Stanovoi seismic zone. The detailed geological-structural and morphotectonic studies of fault zones made it possible to estimate the kinematics of the active faults and their activity degree in the Holocene (the last 10 000 years). The latter include old faults such as, for example, the Stanovoi Suture of the Proterozoic age. Most of these faults are the Late Mesozoic and Cenozoic in age. The studies were aimed at reconstructing the past seismogeological processes and were accompanied by trenching across morphological structures that are presumably associated with zones of active tectonic fractures preliminarily studied by geophysical methods. The applied approach allowed us to substantially specify the available information on the seismotectonics and the potential seismic hazard in the region.     

Paleoseismogenous deformations around ulan bator according to geological and geophysical data

The Gunzhin system of NE-trending active faults is described on the basis of results of special seis-motectonic studies carried out for the first time around Ulan Bator, Mongolia. This system crosses watershed parts of stream valley. It is named after one of them. The total length of the fault segment traced on aerial photos is 15–20 km. In valleys of some temporary stream flows there are considerable visible horizontal displacements attaining 20–25 m, which testify to the right lateral slip (Khundullun River). Revealed structural parageneses of thrusts and overthrusts, divergent as a fan-shaped system to the both sides from the axial sub-vertical shift zone, are reliably confirmed by the data of geophysical investigations. Taking into account the known correlation relationships between seismodislocation parameters (length and maximum displacement amplitude) and earthquake magnitudes, it is possible to suggest that the Gunzhin Fault generated two paleoearthquakes with the magnitude of about 7.0 in the Late Holocene. It means that displacements along that fault could attain the intensity of 9–10 degrees in the Ulan Bator territory according to the MSK-64 scale. This result must be taken into account in estimation of seismic hazard in the territory discussed.     

Dangerous geological processes in the Baikal rift zone and adjacent territories

In the context of active endogenic, exogenic, and technogenic factors, the dynamics of developing geological hazards and risks is estimated for the linear transport systems that run across the strong earthquake epicentral areas of the Baikal rift zone and adjacent territories. The presence of ancient and new seismic structures in the modern relief can be regarded as an indicator of places of intense development of exogeodynamic processes and zones of hazard.     

Paleoseismic studies of the Hustai Fault zone (Northern Mongolia)

We discuss the results of study of the Holocene seismic activity of the Hustai Fault zone, Central Mongolia. Applying seismological methods (remote, trenching, geophysics), we have revealed signs and determined the quantitative parameters of the paleoearthquake that led to the fault dissection at 3–5.5 ka. The high seismic potential of the Tola earthquake focus zone and its proximity to Ulaanbaatar confirm earlier estimates of the seismicity of the capital of Mongolia, 8 points on the MSK-64 scale.     

Seismotectonic destruction of the Earth’s crust in the zone of interaction of the northeastern side of the Baikal rift and the Aldan-Stanovoy block

The paper presents the modern structural-tectonic pattern and a tectonodynamic model of the zone of interaction of the most seismically active northeastern side of the Baikal rift zone (BRZ) and the conjugate system of seismogenic structures of the Aldan-Stanovoy block, where disastrous events with M ≥ 6.0 have been reported. Regularities in the structural formation of active faults and their kinematics are discussed. The faults form block structures accumulating significant tectonic strain. Motions between large tectonic blocks cause sudden release of the strain, which results in catastrophic events (M ≥ 6.0) with focal mechanisms of definite kinematic type.     

Paleoseismological investigation of the Kichera Fault Zone in the northern Baikal region

In the recent structure of the Baikal Rift Zone, the Kichera Fault serves as the northwestern boundary of the Angara-Kichera aggradation depression. A seismotectonic scarp 60 m high was formed as a result of normal faulting during the late Pleistocene and Holocene. The erosion-aggradation and seismic landforms testify to the nonuniform growth of this scarp. To study the character of the seismic activity in the Kichera Fault Zone, we excavated two trenches across the seismotectonic scarp. The Holocene stage of the seismotectonic activation within the fault zone and the preceding period of relative quiescence were outlined from the character of the deformations in the trench sections and previous geomorphic investigations. According to our preliminary estimations, the active stage that started at the end of the late Pleistocene and that has remained incomplete until now was accompanied by at least three rupture-forming earthquakes.