Your search keyword '"Zheng, Wenjun"' showing total 2 results

1. Orthogonal Fault Rupture and Rapid Postseismic Deformation Following 2019 Ridgecrest, California, Earthquake Sequence Revealed From Geodetic Observations.

Author

Feng, Wanpeng, Samsonov, Sergey, Qiu, Qiang, Wang, Yuqing, Zhang, Peizhen, Li, Tao, and Zheng, Wenjun

Subjects

GEODETIC observations, EARTHQUAKE aftershocks, EARTHQUAKES, SYNTHETIC apertures, PIXELS, DEFORMATION of surfaces, SATELLITE geodesy, MIMO radar

Abstract

We studied the 2019 Mw6.4 and Mw7.1 Ridgecrest, California, earthquake sequence, using Sentinel‐1 and ALOS‐2 coseismic interferograms and subpixel offsets to retrieve the three‐dimensional (3‐D) surface displacements. By inverting the 3‐D displacements, optimal dip angles of the earthquake faults and the slip model were obtained. The interferometric synthetic aperture radar‐based slip model supplemented with the analysis of GPS data shows that the Mw6.4 event ruptured two orthogonal faults and its major geodetic moment was released by sinistral motion on a NE‐SW trending fault that dips 78° NW. Right‐lateral slip on NW‐SE trending subvertical faults was responsible for the Mw7.1 earthquake. Postseismic analysis with U.S. Geological Survey earthquake catalog and GPS time series at site P595 shows that the postseismic surface deformation following the Mw7.1 event has similar temporal patterns with the postseismic moment release, but requires more energy. This implies that the early aftershocks were likely controlled by rapid afterslip following the mainshock. Key Points: The 3‐D surface displacements of the 2019 Ridgecrest earthquakes are derived from Sentinel‐1 and ALOS‐2 InSAROrthogonal fault ruptures of the Mw6.4 event are revealed by using GPS horizontal measurementsThe rapid decay of aftershocks is explained by the afterslip following the mainshocks [ABSTRACT FROM AUTHOR]

Published

2020

2. Structural geometry of the Urumqi foreland thrust system, northern Tian Shan: Insights into the seismotectonics of the 2013 M 5.1 Urumqi earthquake and deformation pattern in the Urumqi area.

Author

Wu, Chuanyong, Liu, Jianming, He, Xiaohui, Li, Zhigang, and Zheng, Wenjun

Subjects

*SURFACE fault ruptures, *THRUST belts (Geology), *EARTHQUAKE aftershocks, *THRUST, *SEISMIC reflection method, *SEISMOTECTONICS, *GRABENS (Geology), *EARTHQUAKE magnitude, *EARTHQUAKES

Abstract

In foreland thrust systems, the complex structural geometry creates greater difficulties in constraining the seismotectonics of moderate magnitude earthquakes without pronounced surface ruptures and in assessing future seismic risk. The 2013 M 5.1 Urumqi earthquake was a moderate event that occurred in the Urumqi foreland thrust system. Based on surface investigations, geological mapping, and interpretations of deep seismic reflection profiles, we suggest that the Urumqi foreland thrust belt is a typical active wedge thrust system. Two connected fault segments of the gently south-dipping blind fault ramp and the north-dipping Xishan back-thrust fault merge at a depth of ~11 km and bound the wedge-shaped fault block. Analyses of the focal mechanism and aftershock distribution indicate that the seismogenic fault responsible for the M 5.1 Urumqi event is the south-dipping Xishan fault ramp with a dip angle of ~10–30°, which highlights the potential seismic hazards of the unruptured north-dipping Xishan back-thrust ramp. The four fault branches on the hanging wall of the Xishan fault are interpreted as flexural-slip thrusts. Our results indicate that multiple surface ruptures over a 6 km-wide area may form if a large earthquake occurs along the Xishan fault system. • The seismogenic fault of the 2013 M 5.1 Urumqi event is the south-dipping blind Xishan fault ramp. • Four north-dipping fault branches on the hanging wall of the Xishan fault are flexural-slip thrusts. • Potential seismic hazard of the Urumqi foreland thrust system is estimated. [ABSTRACT FROM AUTHOR]

Published

2022