Your search keyword '"Zheng, Wenjun"' showing total 6 results

1. Fault slip behavior and segmentation revealed by geomorphic offset clusters: An example from the middle Riganpei Co fault, central Tibet.

Author

Tang, Qing, Zheng, Wenjun, Bi, Haiyun, Zhang, Dongli, Liu, Bingxu, and Wei, Shiqi

Subjects

*DISTRIBUTION (Probability theory), *MORPHOTECTONICS, *DISPLACEMENT (Mechanics), *SUTURE zones (Structural geology), *EARTHQUAKES

Abstract

• The Riganpei Co fault is divided into four segments based on the distribution of displacements. • The COPD within 0–30 m for each segment reveals that at least four large earthquakes ruptured this fault. • Reconstructed slip distribution shows a complex pattern of strong earthquake activities on different segments of the fault. High-resolution topographic datasets are useful for revealing offset features of fault geomorphology and are thus important for reconstructing the evolution history of faults. The Riganpei Co fault, located in the central Tibetan Plateau, is an important active fault on the northern boundary of the Bangong-Nujiang suture zone. In this study, WorldView-2 stereo images were used to generate high-resolution topographic data in a 1 km range on both flanks of the middle section of the Riganpei Co fault. We interpreted the tectonic geomorphology along the fault, classified it into distinct units, and measured the horizontal displacement of each unit. Within approximately 70 km along the fault, we obtained 396 displacement measurements ranging from 0 to 60 m. Given the evident uneven distribution of displacement, the fault was divided into four segments. In each fault segment, the reconstructed slip distributions revealed a tendency of larger displacements in the center and smaller displacements toward the ends. The cumulative offset probability distribution (COPD) of displacements displays 4–5 offset clusters in the range of 0–30 m for each segment, suggesting that at least four large earthquakes ruptured this fault. The binned COPD demonstrated that there are differences in the displacement accumulation modes among these fault segments, where the middle segment follows a characteristic slip accumulation mode. Reconstructed cumulative slip profiles revealed a complex pattern of strong earthquake activities along the Riganpei Co fault. [ABSTRACT FROM AUTHOR]

Published

2024

2. Dextral strike-slip of Sanguankou-Niushoushan fault zone and extension of arc tectonic belt in the northeastern margin of the Tibet Plateau.

Author

Lei, QiYun, Zhang, PeiZhen, Zheng, WenJun, Chai, ChiZhang, Wang, WeiTao, Du, Peng, and Yu, JingXing

Subjects

STRIKE-slip faults (Geology), GEOLOGIC faults, PLATEAUS, EPEIROGENY

Abstract

The kinematic characteristics of the Sanguankou-Niushoushan fault (SGK-NSSF) are of great significance to the understanding of the extension of the arc tectonic belt in the northeastern margin of the Tibet Plateau. Using field surveys and various data collection methods, including large-scale geological mapping, measurement of typical topographies, and dating of sedimentary strata, it was determined that the SGK-NSSF exhibits obvious dextral strike-slip characteristics and thus is not a sinistral strike-slip fault, as believed by previous researchers. The results of this study show that the geological boundaries for the Paleozoic, Mesozoic, and Cenozoic eras were all dextrally dislocated by the fault, with the faulted displacements being similar. The maximum strike-slip displacement of the fault, after elimination of topographic effects, was found to be 961±6 m. The Sanguankou fault at the northern section exhibits obvious characteristics of more recent activities, with a series of small gullies having undergone synchronized dextral writhing after traversing the fault. The average horizontal slip rate of the fault since the late Quaternary was determined to be approximately 0.35 mm/a. The pre-existing fold structures formed during the late Pliocene were dislocated by the fault and became ex situ, indicating that dextral strike-slip of the fault could not have occurred prior to the late Pliocene. The maximum displacements and average slip rates were used to estimate the onset time of the dextral strike-slip activities of the fault as being after 2.7 Ma. In this study, the understanding of previous researchers concerning the extension in the northeastern margin of the Tibet Plateau was combined with analyses of the successive relationships between fold deformations and fault activities. This led to the finding that the extension in the northeastern margin of the Tibet Plateau reached the vicinity of the SGK-NSSF during the late Pliocene (∼2.7 Ma), causing regional uplift and fold deformations of the strata there. During the early Quaternary, the northeastern compression of the Tibet Plateau and the counterclockwise rotation of the Ordos block collectively resulted in the dextral strike-slip activities of the SGK-NSSF. This then formed the foremost margin of the arc tectonic belt extension in the northeastern margin of the Tibet Plateau. [ABSTRACT FROM AUTHOR]

Published

2016

3. Analogue sandbox modeling of orogenic wedge front faulting: Roles of inherited fault zones and topographic loading.

Author

Sun, Chuang, Li, Zhigang, Zheng, Wenjun, Jia, Dong, Almeida, Rafael, Hui, Gege, Zhang, Yipeng, He, Zhiyuan, Yang, Shuang, and Fan, Xiaogen

Subjects

*OROGENIC belts, *FAULT zones, *WEDGES, *CHI-chi Earthquake, Taiwan, 1999, *EARTHQUAKES

Abstract

Earthquakes reported in the frontal belts of active orogenic wedges such as the 2013 M w 6.6 Lushan and 1999 M w 7.6 Chi-Chi earthquakes, highlight the importance of loading exerted by mountainous topography and inherited fault zones. However, their effects on formation and activation of these wedge front fault systems remain poorly understood. This study presents three sets of sandbox experiments in which topographic loading and geometry of inherited faults were first separately investigated, then explored jointly. Experiments show that smaller topographic loading favors gentle-dipping wedge front thrusts, while larger topographic loading promotes the development of steep wedge front faults. Introduced as zones of frictional weakness, all inherited faults promote deformation localization, though the steep ones are characterized by buttressing nearby rather than direct slip on themselves. When the two factors were tested integrally, four major deformation modes arose, including (1) direct reactivation; (2) fault truncation in the initial stage of compression; (3) stacking of small thrusts against the inherited fault and possible truncation in a later evolutionary stage; (4) behavior as a fossil structure. These modes show differences not only in first-order deformation styles, but also in the distribution of secondary structures, defining a basic framework and providing new guides for the interpretation of complex wedge front fault systems and their activities, in areas such as the Longmen Shan (eastern Tibet), the Tian Shan and the western margin of the Taiwan orogen. • Mountain front deformation and resultant faults are simulated. • Smaller topographic loading favors gentler mountain front fault. • Behavior of inherited faults varies with imposed mountainous topographic loading. • Four mountain front deformation modes are identified. • Simple shear kinematics in several mountain front earthquakes is reproduced. [ABSTRACT FROM AUTHOR]

Published

2022

4. Paleoseismology and slip rate of the western Tianjingshan fault of NE Tibet, China.

Author

Li, Xinnan, Li, Chuanyou, Wesnousky, Steven G., Zhang, Peizhen, Zheng, Wenjun, Pierce, Ian K.D., and Wang, Xuguang

Subjects

*PALEOSEISMOLOGY, *GEOLOGIC faults, *EARTHQUAKES, *QUATERNARY Period, *DEFORMATIONS (Mechanics)

Abstract

We present results from a detailed investigation of the horizontal displacement distribution, timing of paleoearthquakes and left-lateral slip rate on the western Tianjingshan fault. Measurements of 240 offset streams and ridges confirm that the fault is left-lateral and record evidence of repeated ∼3–4 m coseismic offsets along the 60–km–long fault. This suggests that ∼6 earthquakes may have occurred along the entire western Tianjingshan fault with repeated occurrence of earthquakes of Mw 7.2–7.5. Structural and stratigraphic relationships exposed in our five trenches in combination with previously reported studies further indicate that the fault has ruptured in as many as six paleoearthquakes since the late Quaternary. Paleoseismic data show that the average recurrence interval for Holocene earthquakes is approximately 5,000 yr. The most recent earthquake along the western Tianjingshan fault occurred ∼1.2 ± 0.1 kyr BP, indicating that this fault segment did not rupture in the M 7.5 historical earthquake of 1709 that ruptured the central Tianjingshan fault. We estimate that the Holocene slip rate of the western Tianjingshan fault is ∼1.1–1.2 mm/yr based on measurements of the age and offset of stream channels. Compared with the relatively fast slip rate of the Haiyuan fault (∼4–6 mm/yr), we suggest that the Tianjingshan fault acts as an essential active fault accommodating the sinistral displacement and crustal shortening deformation in NE Tibet. [ABSTRACT FROM AUTHOR]

Published

2017

5. Active tectonics and landform evolution in the Longxian-Baoji Fault Zone, Northeast Tibet, China, determined using combined ridge and stream profiles.

Author

Li, Xinnan, Pierce, Ian K.D., Ai, Ming, Luo, Quanxing, Li, Chuanyou, Zheng, Wenjun, and Zhang, Peizhen

Subjects

*FAULT zones, *NATURAL landscaping, *GLACIAL landforms, *PLEISTOCENE Epoch, *HOLOCENE Epoch, *TOPOGRAPHY

Abstract

The Longxian-Baoji Fault Zone (LBFZ) is the main structural link between the compressional Liupanshan Mountain in north and the extensional Weihe Basin in south, which accommodated complex deformation between the Tibetan Plateau and the Ordos Block. We determined the tectonic activity of the normal faults in the LBFZ using combined ridge and stream profiles measured from the natural landscape and simulated by a numerical model. The well-preserved geomorphic features (i.e., scarps) and steep scarp slopes show that the Guguan-Guozhen Fault (GGF) has been active during the Late Pleistocene to Holocene. The distinct decrease of scarp heights of the GGF near Badu and the low scarp and land surface slopes of ridge and stream profiles for the inferred northern extension of the GGF demonstrate that the GGF terminates near Badu and does not extend farther to the north. The Taoyuan-Guichuansi Fault is determined to be an Early-Middle Pleistocene fault, as evident from the different shapes and low scarp slopes of stream profiles. The longitudinal profiles of the Qianyang-Biaojiao Fault are characterized by two segments with different slopes, indicating that the fault may not have been active during the Quaternary. Our results show that the profile shapes, spatial pattern of scarp height, and the slopes of scarp and land surface of ridge and stream profiles are appropriate metrics of fault activity. Furthermore, we constructed the landform evolution in the LBFZ and suggest that it is closely related to the active tectonics. The change in fault activity reflects a tectonic transformation from an extensional regime to a dominantly transtensional regime. • Tectonic activity of the Longxian-Baoji Fault Zone analyzed from DEMs and modelling • Profiles and slopes of streams, interfluve ridges, fault scarps and land surfaces analyzed • Morphological differences suggest different activity and timing between different faults • Spatial-temporal fault pattern insights used to construct a landform evolution model • LBFZ topography linked to change in active tectonics from extension to transtension [ABSTRACT FROM AUTHOR]

Published

2022

6. Controls on decadal erosion rates in Qilian Shan: Re-evaluation and new insights into landscape evolution in north-east Tibet.

Author

Wang Yizhou, Zhang Huiping, Zheng Dewen, Zheng Wenjun, Zhang Zhuqi, Wang Weitao, and Yu Jingxing

Subjects

*EROSION, *LANDSCAPES, *TOPOGRAPHY, *EARTHQUAKES, *SEDIMENTATION & deposition

Abstract

Available data from the Qilian Shan in north-east Tibet suggested that decadal-scale erosion rates were closely correlated with local topographic gradient, but not with climatic factors. However, a climatic change to more arid condition was proposed to explain the discrepancy between short-term and long-term erosion rates. In order to re-evaluate the topographic, tectonic and climatic influences on erosion, we adopted five parameters (slope, mean local relief, historical cumulative seismic moment, runoff coefficient of variation and fault density) to study 11 drainage basins in north-east Tibet. Our results showed that terrain gradient, rock fracture density and rainstorm intensity had strong influence on erosion rates while 60-year cumulative seismic moments of historical earthquakes showed weaker correlations. There was a spatial variation in the erosional mechanisms across the basin, with detachment-limited dominance around the ridges (slope > 20°) and deposition dominant in the flat areas. The variation may lead to the discrepancy between short-term and long-term erosion rates. In general, our study supports the 'bath-tub' model for low relief intermountain basins, hence providing new insights into the landscape evolution of the Qilian Shan in northeastern Tibetan Plateau. [ABSTRACT FROM AUTHOR]

Published

2014