Your search keyword '"Jinshui Lv"' showing total 5 results

1. Crustal structure beneath the east side of Pearl River Estuary from onshore-offshore seismic experiment

Author

Xiuwei Ye, Xuelin Qiu, Haibo Huang, Xiaona Wang, Liwei Wang, Sun Wang, Jinshui Lv, and Zuoyong Lv

Subjects

geography, geography.geographical_feature_category, Rift, South china, 020209 energy, Geology, Estuary, 02 engineering and technology, engineering.material, 010502 geochemistry & geophysics, 01 natural sciences, Seafloor spreading, Paleontology, Transition zone, 0202 electrical engineering, electronic engineering, information engineering, engineering, Submarine pipeline, Pearl, 0105 earth and related environmental sciences

Abstract

The land-sea transition zone in the northern South China Sea (SCS) records important information from the continental rifting to the seafloor spreading. The crustal structure is the key to explore the deep tectonic environment and the evolution of the SCS. In 2015, the onshore-offshore 3D deep seismic experiment was carried out on the Pearl River Estuary (PRE). Explosions and air guns were used as sources on land and at sea respectively in this experiment.Onshore seismic stations and Ocean Bottom Seismographs (OBSs) synchronously recorded the seismic signals. We focus on an onshore-offshore seismic profile (L2, SE-trending) along the eastern side of the PRE. By modelling the seismic travel times, we constructed a P-wave velocity model along the profile. The model shows that the sediment on land is thin and has seismic velocities of 4.5–5.5 km/s. In contrast, thickness of the offshore sediment gradually increases to more than 4.0 km, and the velocities vary between 2.0 km/s and 4.5 km/s. The onshore and offshore crustal velocities are 5.8–6.8 km/s and 5.5–6.8 km/s, respectively. At depth between 15 km and 20 km, a low-velocity layer (LVL; only 5.9 km/s) is detected, pinching out under the Littoral Fault Zone (LFZ). The LVL has probably accommodated the crustal extension beneath the land area, resulting in low extent of the crustal thinning. A slightly uplifted Moho exists beneath the Dongguan fault depression zone, representing a place where hot mantle materials ascend. Localized thickening of the sediments and rapid thinning of the crust characterize the LFZ, and it can be regarded as a tectonic boundary between the South China (SC) with normal continental crust and the northern SCS margin with extended continental crust.

Published

2018

2. Crustal Structure Revealed by a Deep Seismic Sounding Profile of Baijing-Gaoming-Jinwan in the Pearl River Delta

Author

Xiaona Wang, Xiang Zhang, Jinshui Lv, and Xiuwei Ye

Subjects

Seismometer, geography, Depth sounding, Tectonics, geography.geographical_feature_category, Rift, Estuary, Crust, Classification of discontinuities, Seismology, Seabed, Geology

Abstract

The Pearl River estuary area, located in the middle part of the southern China coastal seismic belt, has long been considered a potential source of strong earthquakes above magnitude 7.0. To scientifically assess the potential strong earthquake risk in this area, a three-dimensional artificial seismic sounding experiment, consisting of a receiving array and seabed seismograph, was performed to reveal the deep crustal structure in this region. We used artificial ship-borne air-gun excitation shots as sources, and fixed and mobile stations as receivers to record seismic data from May to August 2015. This paper presents results along a line from the western side of the Pearl River estuary to the western side of the Baijian–Gaoming–Jinwan profile. A two-dimensional velocity structure was constructed using seismic travel-time tomography. The inversion results show that the Moho depth is 27 km in the coastal area and 30 km in the northwest of the Pearl River estuary area, indicating that the crust thins from land to sea. Two structural discontinuities and multiple low-velocity anomalies appear in the crustal section. Inside both discontinuity zones, a low-velocity layer, with a minimum velocity of 6.05kms−1, exists at a depth of about 15 km, and another, with a minimum velocity of 6.37kms−1, exists at a depth of about 21.5 km between the middle and lower crust. These low velocities suggest that the discontinuities may consist of partly molten material. Earthquakes with magnitudes higher than 5.0 occurred in the low-velocity layer along the profile. The deep Kaiping-Enping fault, rooted in the crust, may be one of the most important channels for deep material upwelling and is related to tectonic movement since the Cretaceous in the Pearl River Delta tectonic rift basin.

Published

2020

3. Crustal Structure and tectonic attribute Revealed by a Deep Seismic Sounding Profile of Dinghu-Gaoming-Jinwan in the Pearl River Delta

Author

Xiuwei Ye, Xiang Zhang, Jinshui Lv, Baofeng Liu, Xiaona Wang, LIwei Wang, and Zuoyong Lv

Abstract

To find out the crustal structure and tectonic attribute of the Pearl river delta and offshore area(PRD), in 2015, the Guangdong Earthquake Agency collaboration with the other unit carried out a three-dimensional joint onshore-offshore seismic detection experiment in the PRD. This paper processed the data of Dinghu-Gaoming-Jinwan L1 line on the west side of PDR. We utilized ray tracing and travel-time simulation method to obtained a P-wave velocity model of the L1 profile.The study showed: Along the profile, The depth of the Moho gradually decreases from the northwestern inland 30.0km to the southwestern coastal 28.0km. Upheaval of the Moho is between Dinghu and Gaoming. The low velocity layer in the mid-crustal is a heterogeneous continuum. The velocity of low velocity layer NW side is lower than the SE side, especially between Dinghu and Gaoming. The minimum velocity is 6.05km•s-1. The deep Wuchuan-Sihui fault and Guangzhou-Enping fault may be one of the most important channels for deep material upwelling. It is the continuum upheaval of the Moho which from Dinghu, Gaoming on the west side of PDR to Qingyuan, Conghua on the east side of PDR delimited by Wuchuan-Sihui fault and Guangzhou-Enping fault.

Published

2020

4. Crustal structure revealed by a deep seismic sounding profile of Baijing-Gaoming-Jinwan in the Pearl River Delta

Author

Jinlong Sun, Xiang Zhang, Xiuwei Ye, Jinshui Lv, and Xiaona Wang

Subjects

Seismometer, geography, geography.geographical_feature_category, Rift, 010504 meteorology & atmospheric sciences, Ocean Engineering, Estuary, Crust, Classification of discontinuities, 010502 geochemistry & geophysics, Oceanography, 01 natural sciences, Tectonics, Depth sounding, Seismology, Seabed, Geology, 0105 earth and related environmental sciences

Abstract

The Pearl River Estuary area, located in the middle part of the southern China coastal seismic belt, has long been considered a potential source of strong earthquakes above magnitude 7.0. To scientifically assess the potential strong earthquake risk in this area, a three-dimensional artificial seismic sounding experiment, consisting of a receiving array and seabed seismograph, was performed to reveal the deep crustal structure in this region. We used artificial ship-borne air-gun excitation shots as sources, and fixed and mobile stations as receivers to record seismic data from May to August 2015. This paper presents results along a line from the western side of the Pearl River Estuary to the western side of the Baijing-Gaoming-Jinwan profile. A two-dimensional velocity structure was constructed using seismic travel-time tomography. The inversion results show that the Moho depth is 27 km in the coastal area and 30 km in the northwest of the Pearl River Estuary area, indicating that the crust thins from land to sea. Two structural discontinuities and multiple low-velocity anomalies appear in the crustal section. Inside both discontinuity zones, a low-velocity layer, with a minimum velocity of 6.05 km s−1, exists at a depth of about 15 km, and another, with a minimum velocity of 6.37 km s−1, exists at a depth of about 21.5 km between the middle and lower crust. These low velocities suggest that the discontinuities may consist of partly molten material. Earthquakes with magnitudes higher than 5.0 occurred in the low-velocity layer along the profile. The deep Kaiping-Enping fault, rooted in the crust, may be one of the most important channels for deep material upwelling and is related to tectonic movement since the Cretaceous in the Pearl River Delta tectonic rift basin.

Published

2018

5. Seismogenic structures of the 2006 ML4.0 Dangan Island earthquake offshore Hong Kong

Author

Chaoyan Fan, Kuiyuan Wan, Xiang Zhang, Shaohong Xia, Huilong Xu, Jinshui Lv, Pengxiang Zhou, Jinghe Cao, and Jinlong Sun

Subjects

geography, geography.geographical_feature_category, 010504 meteorology & atmospheric sciences, Anomaly (natural sciences), Ocean Engineering, Crust, Induced seismicity, Fault (geology), 010502 geochemistry & geophysics, Oceanography, 01 natural sciences, Continental margin, Seismic tomography, Intraplate earthquake, Submarine pipeline, Geology, Seismology, 0105 earth and related environmental sciences

Abstract

The northern margin of the South China Sea, as a typical extensional continental margin, has relatively strong intraplate seismicity. Compared with the active zones of Nanao Island, Yangjiang, and Heyuan, seismicity in the Pearl River Estuary is relatively low. However, a ML4.0 earthquake in 2006 occurred near Dangan Island (DI) offshore Hong Kong, and this site was adjacent to the source of the historical M5.8 earthquake in 1874. To reveal the seismogenic mechanism of intraplate earthquakes in DI, we systematically analyzed the structural characteristics in the source area of the 2006 DI earthquake using integrated 24-channel seismic profiles, onshore–offshore wide-angle seismic tomography, and natural earthquake parameters. We ascertained the locations of NW- and NE-trending faults in the DI sea and found that the NE-trending DI fault mainly dipped southeast at a high angle and cut through the crust with an obvious low-velocity anomaly. The NW-trending fault dipped southwest with a similar high angle. The 2006 DI earthquake was adjacent to the intersection of the NE- and NW-trending faults, which suggested that the intersection of the two faults with different strikes could provide a favorable condition for the generation and triggering of intraplate earthquakes. Crustal velocity model showed that the high-velocity anomaly was imaged in the west of DI, but a distinct entity with low-velocity anomaly in the upper crust and high-velocity anomaly in the lower crust was found in the south of DI. Both the 1874 and 2006 DI earthquakes occurred along the edge of the distinct entity. Two vertical cross-sections nearly perpendicular to the strikes of the intersecting faults revealed good spatial correlations between the 2006 DI earthquake and the low to high speed transition in the distinct entity. This result indicated that the transitional zone might be a weakly structural body that can store strain energy and release it as a brittle failure, resulting in an earthquake-prone area.

Published

2018