Insight into Urban Faults by Wavelet Multi-Scale Analysis and Modeling of Gravity Data in Shenzhen, China

Chuang Xu; Haihong Wang; Zhicai Luo; Hualiang Liu; Xiangdong Liu

doi:10.1007/s12583-017-0770-4

Journal of Earth Science ›› 2018, Vol. 29 ›› Issue (6) : 1340 -1348. DOI: 10.1007/s12583-017-0770-4

Geophysical Imaging from Subduction Zones to Petroleum Reservoirs

Insight into Urban Faults by Wavelet Multi-Scale Analysis and Modeling of Gravity Data in Shenzhen, China

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Abstract

Urban faults in Shenzhen are potential threat to city security and sustainable development. To improve the knowledge of the Shenzhen fault zone, interpretation and inversion of gravity data were carried out. Bouguer gravity covering the whole Shenzhen City was calculated with a 1-km resolution. Wavelet multi-scale analysis (MSA) was applied to the Bouguer gravity data to obtain the multilayer residual anomalies corresponding to different depths. In addition, 2D gravity models were constructed along three profiles. The Bouguer gravity anomaly shows an NE-striking high-low-high pattern from northwest to southeast, strongly related to the main faults. According to the results of MSA, the correlation between gravity anomaly and faults is particularly significant from 4 to 12 km depth. The residual gravity with small amplitude in each layer indicates weak tectonic activity in the crust. In the upper layers, positive anomalies along most of faults reveal the upwelling of high-density materials during the past tectonic movements. The multilayer residual anomalies also yield important information about the faults, such as the vertical extension and the dip direction. The maximum depth of the faults is about 20 km. In general, NE-striking faults extend deeper than NW-striking faults and have a larger dip angle.

Keywords

urban faults / Bouguer gravity anomaly / wavelet multi-scale analysis / gravity modeling / Shenzhen

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Chuang Xu, Haihong Wang, Zhicai Luo, Hualiang Liu, Xiangdong Liu. Insight into Urban Faults by Wavelet Multi-Scale Analysis and Modeling of Gravity Data in Shenzhen, China. Journal of Earth Science, 2018, 29(6): 1340-1348 DOI:10.1007/s12583-017-0770-4

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