Active Flexural‐Slip Faulting: Controls Exerted by Stratigraphy, Geometry, and Fold Kinematics

et al. 2019

Tectonics

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Located at the northwestern syntaxis of the India‐Asia convergence zone, the Pamir orogen is characterized by complicated and strong active deformation. Constraining the detailed geometry and kinematics of major active structures is important both for understanding modern tectonic processes and for evaluating potential seismic hazards of the region. Our work focuses on the Muji Fault in the northeastern Pamir. Based on cumulative deformation recorded by landforms and coseismic deformation during the 2016 Mw 6.6 Aketao earthquake, we determine the spatial extent, slip motion, fault‐plane geometry, and slip rate of the fault, on the basis of which we clarify its role in the modern tectonics of the Pamir and investigate its seismic behavior and associated seismic hazards. Our study indicates that (i) the Muji Fault, along with the Kongur Extensional System to its south, acts as a boundary fault that accommodates a relative divergence rate of 1.4–2.0°/Ma between the central‐western and eastern Pamir; (ii) geometric discontinuities along the fault exerted an important control on seismic rupture termination and slip gap formation during the Aketao earthquake; and (iii) the cumulative surface‐faulting deformation cannot be formed coseismically by repetitions of the Aketao earthquake, implying significant aseismic (postseismic and/or interseismic) creeping or possibly larger (approximately Mw 7.2), surface‐faulting earthquakes. Our study highlights the usefulness of correlating cumulative and coseismic deformation patterns in active tectonic investigations and regional seismic hazard evaluations.

Section: Tectonic Settingmentioning

confidence: 99%

Cumulative and Coseismic (During the 2016 M_w6.6 Aketao Earthquake) Deformation of the Dextral‐Slip Muji Fault, Northeastern Pamir Orogen

Schoenbohm

et al. 2019

Tectonics

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“…(a) Major Cenozoic structures and seismicity and (b) geologic map of the Pamir foreland thrust system and adjacent areas (modified from T. Li et al, ). Lines A to G depict locations of geological cross sections in Figures .…”

Section: Introductionmentioning

confidence: 99%

Along‐Strike and Downdip Segmentation of the Pamir Frontal Thrust and Its Association With the 1985M_w6.9 Wuqia Earthquake

et al. 2019

JGR Solid Earth

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The Pamir Frontal Thrust along the leading edge of the northern Pamir is characterized by multiple earthquakes with moment magnitudes of 6.5–7.1. Geometric characteristics of the Pamir Frontal Thrust corresponding to these earthquakes and to future seismic hazards, however, remain largely unexplored. This study focuses on the easternmost segment of the Pamir Frontal Thrust, where the Mw 6.9 Wuqia earthquake occurred in 1985. Through interpretation of available two‐dimensional seismic reflection profiles and surface mapping data, we develop a three‐dimensional geometric model for the fault plane. Our results illustrate that, at depth, the fault plane is separated by a subhorizontal detachment horizon into upper and lower ramps, and both ramps are significantly segmented, along strike, by transfer faults or lateral ramps as well. Such along‐strike and downdip segmentation of the thrust sheet apparently plays a significant control on seismic rupture process of the Wuqia earthquake and can well explain why the region is characterized by moderate‐magnitude (Mw 6.5–7.1) events. Additionally, our study helps quantify key constraints on the Cenozoic deformation and evolution of the northeastern Pamir and, specifically, determines a total shortening of ≤43 km at the Pamir front: accommodating about 15% of the total indentation of the Pamir range into central Asia.

“…In areas dominated by active folds, flexural‐slip faults (FSFs) and bending‐moment faults (BMFs) can slice through the land surface and produce a series of subparallel, closely‐spaced geomorphic scarps (Figure c; e.g., Audin et al, ; T. Li et al, , ; Philip & Meghraoui, ; Yeats et al, ). Although the sense, orientation, and displacement of these faults cannot be extrapolated to those of the underlying causative thrust, they can provide useful information on folding kinematics (e.g., Ismat, ; T. Li et al, ; Salvini & Storti, ) and the paleoearthquake history of the underlying thrust (e.g., Gutiérrez et al, ; Kelsey et al, ; Livio et al, ; McCalpin, ). FSFs and BMnFs, as two typical secondary fault styles accommodating folding deformation, have been commonly observed in rock outcrops (e.g., Bazalgette et al, ; Fischer & Jackson, ; Gutiérrez‐Alonson & Gross, ; Horne & Culshaw, ; Tanner, ).…”

Section: Introductionmentioning

confidence: 99%

“…The Pamir‐western Kunlun and southern Tian Shan regions, northwestern China, are dominated by active thrusting and folding in their piedmonts and major intermontane basins (e.g., Allen et al, ; Goode et al, ; Huang et al, ; Hubert‐Ferrari et al, ; T. Li et al, , ; Saint‐Carlier et al, ; Scharer et al, ; S. C. Thompson et al, ; Thompson‐Jobe et al, ). Previous studies (Avouac & Peltzer, ; Heermance et al, ; Huang et al, ; T. Li et al, , ) and our new surveys document numerous sets of well‐developed FSF scarps and bending‐moment normal fault (BMnF) scarps (Figure ). The majority of FSF scarps are present in the western corner of the Tarim Basin where the Pamir and southern Tian Shan are converging at a high rate of ~7–11 mm/a (T. Li et al, ; Thompson‐Jobe et al, ), whereas the majority of BMnF scarps are present on the western Kunlun piedmont, where the modern convergent rate is <2.0 mm/a.…”

Section: Introductionmentioning

confidence: 99%

“…The majority of FSF scarps are present in the western corner of the Tarim Basin where the Pamir and southern Tian Shan are converging at a high rate of ~7–11 mm/a (T. Li et al, ; Thompson‐Jobe et al, ), whereas the majority of BMnF scarps are present on the western Kunlun piedmont, where the modern convergent rate is <2.0 mm/a. Through our recent work on prominent FSF scarps at eight sites (T. Li et al, , ), their geomorphic expression, diverse outcrop settings, and favorable conditions for formation (including bed lithology and dip, slip‐surface spacing, and folding kinematics) have been investigated and systematically summarized. In this study we focus on the BMnF scarps at four sites: Slik, Cele, Haermodun, and Atushi.…”

Section: Introductionmentioning

confidence: 99%

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Active Bending‐Moment Faulting: Geomorphic Expression, Controlling Conditions, Accommodation of Fold Deformation

Jobe

et al. 2018

Tectonics

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Bending-moment faults and flexural-slip faults (FSFs), as two basic fault styles due to bending-related tangential longitudinal strain, extensively and prominently crop out as surface scarps in the Pamir-western Kunlun and southern Tian Shan regions, northwestern China. Characteristic geomorphic expression, favorable formation conditions, and the role in folding accommodation of active FSFs have been systematically summarized in our recent studies. Here we investigate similar properties for well-developed bending-moment normal fault (BMnF) scarps at four sites. Our study concludes the following: (i) BMnF scarps are relatively sinuous compared to FSF scarps and probably trend obliquely to the fold hinge. A group of BMnF scarps can delineate a single asymmetric graben or create grabens alternating with horsts. (ii) BMnF scarps primarily overlie poorly-layered conglomerates. The fold's interlimb angle can range from~160°to <40°, and the folding kinematics can vary from active-hinge migration to fixed-hinge rotation. (iii) The fault-zone width, fault spacing, and efficiency in folding accommodation significantly decrease with (a) thinner conglomerate beds, (b) a smaller interlimb angle, and (c) the transition of the hinge from migrated to fixed. (iv) Different bed lithologies and fold geometries beneath the surface account for the predominance of BMnF scarps on the western Kunlun piedmont and FSF scarps in the Pamir-Tian Shan convergent zone.(v) Presence of BMnF scarps on the western Kunlun piedmont indicates that~4 km of fault slip is transferred northward along a detachment at the base of the Cenozoic and is ultimately absorbed by the Mazatagh Thrust in the Tarim Basin.