AN IMPROVED MINIMUM 1-D VP VELOCITY MODEL IN THE ONSHORE-OFFSHORE AREA OF THE PEARL RIVER ESTUARY FROM 3-D ACTIVE-SOURCE SEISMIC EXPERIMENT

doi:10.3969/j.issn.0253-4967.2021.01.008

SEISMOLOGY AND GEOLOGY ›› 2021, Vol. 43 ›› Issue (1): 123-143.DOI: 10.3969/j.issn.0253-4967.2021.01.008

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AN IMPROVED MINIMUM 1-D V_P VELOCITY MODEL IN THE ONSHORE-OFFSHORE AREA OF THE PEARL RIVER ESTUARY FROM 3-D ACTIVE-SOURCE SEISMIC EXPERIMENT

WANG Li-wei^1),2),3), WANG Bao-shan^1),4),5), YE Xiu-wei^2),3), ZHANG Yun-peng¹⁾, WANG Xiao-na^2),3), LÜ Zuo-yong^2),3)

1)Institute of Geophysics, China Earthquake Administration, Beijing 100081, China;
2)CEA Key Laboratory of Earthquake Monitoring and Disaster Mitigation Technology, Guangdong Earthquake Agency, Guangzhou 510070, China;
3)Guangdong Provincial Key Laboratory of Earthquake Early Warning and Safety Diagnosis of Major Projects, Guangdong Earthquake Agency, Guangzhou 510070, China;
4)School of Earth and Space Sciences, University of Science and Technology of China, Hefei 230026, China;
5)Mengcheng National Geophysical Observatory, University of Science and Technology of China, Hefei 230026, China

Received:2020-04-02 Revised:2020-08-06 Online:2021-02-20 Published:2021-05-06

基于人工地震资料的珠江口地区最小一维P波速度模型

王力伟^1),2),3), 王宝善^1),4),5), 叶秀薇^2),3),*, 张云鹏¹⁾, 王小娜^2),3), 吕作勇^2),3)

1)中国地震局地球物理研究所, 北京 100081;
2)广东省地震局, 中国地震局地震监测与减灾技术重点实验室, 广州 510070;
3)广东省地震局, 广东省地震预警与重大工程安全诊断重点实验室, 广州 510070;
4)中国科学技术大学, 地球和空间科学学院, 合肥 230026;
5)中国科学技术大学, 安徽蒙城地球物理国家野外科学观测研究站, 合肥 230026

通讯作者: *叶秀薇, 女, 1970年生, 正研级高级工程师, 主要从事地壳结构及震源构造研究, 电话: 020-87683176, E-mail:1424201562@qq.com。
作者简介:王力伟, 男, 1985年生, 中国地震局地球物理研究所固体地球物理专业在读博士研究生, 高级工程师, 主要从事主动震源探测和体波层析成像研究, 电话: 020-87688797, E-mail:wangliwei@cea-igp.ac.cn。
基金资助:
国家自然科学基金(41676057, 41604055); 中国地震局地震科技星火计划项目(XH18034Y); 广东省科技计划项目(2017B030314082)共同资助

Abstract

Abstract: Layered 1-D velocity models are widely used in seismic network routine locations and in seismological studies, such as earthquake relocation, focal mechanism inversion, synthetic seismogram calculation and geodynamics simulation. It’s also used as a reference model for 2-D and 3-D tomographic inversions. Therefore, obtaining a more reliable 1-D velocity model is an extremely important work for the study of earthquake source parameters and seismic tomography. The onshore-offshore area of the Pearl River Estuary is located at the transition zone between South China block and South China Sea bock, the special ocean-land transitional crustal type and the littoral fault zone, which is the regional seismic control structure passing through it, makes it a potential seismic source. Meanwhile, the Pearl River Delta has the most developed economy and dense population in South China. However, the 1-D velocity model used in seismic network routine operations has not been updated since 1990. To investigate the seismic structure and potential strong earthquake risk in this area, we conducted a 3-D active source seismic experiment in 2015, which incorporated sea-based airgun sources and land-based dynamite sources, and seismic recorders both at the onshore and offshore area in the Pearl River Estuary. A high quality subset of the data was used to derive an improved 1-D seismic V_P model for seismological studies. The model is constructed using the VELEST program with first arrival P-wave travel time data, together with station corrections, which account for shallow velocity anomalies from the true velocity model. The reliability of our new model is assessed by good fitting of the travel time data of airguns and dynamites and better earthquake relocation results.
The final 1-D model provides a good fit for travel time data. After iterative inversion, the root-mean-square travel-time error is 0.07s in the onshore area and 0.21s in the offshore area. Within 6km top of the model, the P-wave velocity of onshore area is 5.22~5.99km/s, and the offshore area is obviously lower, which is 2.11~6.03km/s. The retrieved values are in agreement with the thick sedimentary basins in the Pearl River Estuary Basin whose velocity is obvious lower. Then the velocity smoothly increases with depth, within the depth range of 6~15km, the P-wave velocity of onshore area is slightly lower than the offshore area, which may be due to the wide-spread low velocity layer at the middle crust depth in South China Block. Below the depth of 15km, the P-wave velocity of offshore area is greater than that of the onshore area, which is consistent with the high velocity layer in the base of the thinned continental crust and the gradually uplifting of Moho depth seaward as reported in the previous studies.
The spatial distribution of station corrections correlates well with the near-surface structure and geological features. In the area onshore of the Pearl River Estuary, positive values of station corrections are mostly observed in correspondence with the Pearl River Delta sedimentary basins due to its lower velocity values, such as Sanshui Sag, Shunde Sag and Dongguan Sag, etc. While stations located in granite, limestone and metamorphic rocks outcropping area show early P-wave arrivals(negative station corrections). In the area offshore of the Pearl River Estuary, the spatial distribution of station corrections shows a significant lateral variation and 80%larger than the onshore area. It has a good spatial correlation with the buried depth of the sedimentary basement inverted by reflection seismic survey, where the deposits are thicker, the station corrections are positive, the underground medium presents a low velocity, and vice versa. Negative values of station corrections are observed northwest of the NE-trending littoral fault zone, while positive values correspond to the thick sedimentary basins in the Pearl River Estuary Basin southeast of the littoral fault zone.
At last, we relocated 425 earthquakes in the onshore area and 234 earthquakes in the offshore area with M_L≥0.0 using simul2000 algorithm. The result shows that our new model is better than the South China model, the seismic travel time residual after relocation is greatly reduced, the land P wave residual is reduced by 22.6%, and the S wave is reduced by 21.2%. The sea P wave residual is reduced by 25.7%, and the S wave is reduced by 15.6%. The new model is better for regional earthquake location.
We provide a more reliable V_P velocity model, which can be used to earthquake location, earthquake source parameter inversion and 3-D velocity model studies in the Pearl River Estuary.

Key words: Pearl River Estuary, onshore-offshore seismic experiment, minimum 1-D velocity model, station corrections

摘要： 珠江口地区位于南海北部大陆的边缘, 具有洋陆过渡型地壳特征, 且NE向滨海断裂带从其中穿过, 强震风险不可忽视。文中基于2015年珠江口海陆联合三维人工地震探测数据, 人工进行初至P波震相拾取, 并使用VELEST程序分别反演了陆域和海域的最小一维P波速度模型(走时残差均方根最小)和台站校正结果。台站校正结果的空间分布与区域地形、地质构造和沉积厚度相关较好, 正值多分布在珠江三角洲沉积盆地和珠江口盆地内, 而负值多分布在花岗岩等基岩出露地区以及滨海断裂带北侧和北部断阶带内的部分隆起地区。新模型对人工地震走时的拟合精度较高, 陆域走时残差均方根为0.07s, 海域为0.21s。与华南模型相比, 新模型对区域地震定位的效果更好, 重定位后, 陆域的P波地震走时残差降低了22.6%、 S波降低了21.2%; 海域的P波地震走时残差降低了25.7%、 S波降低了15.6%。新模型可为区域地震定位、地震参数和三维成像研究提供参考。

关键词: 珠江口, 海陆地震联测, 最小一维速度模型, 台站校正

CLC Number:

P631.4

WANG Li-wei, WANG Bao-shan, YE Xiu-wei, ZHANG Yun-peng, WANG Xiao-na, LÜ Zuo-yong. AN IMPROVED MINIMUM 1-D V_P VELOCITY MODEL IN THE ONSHORE-OFFSHORE AREA OF THE PEARL RIVER ESTUARY FROM 3-D ACTIVE-SOURCE SEISMIC EXPERIMENT[J]. SEISMOLOGY AND GEOLOGY, 2021, 43(1): 123-143.

王力伟, 王宝善, 叶秀薇, 张云鹏, 王小娜, 吕作勇. 基于人工地震资料的珠江口地区最小一维P波速度模型[J]. 地震地质, 2021, 43(1): 123-143.

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AN IMPROVED MINIMUM 1-D V_P VELOCITY MODEL IN THE ONSHORE-OFFSHORE AREA OF THE PEARL RIVER ESTUARY FROM 3-D ACTIVE-SOURCE SEISMIC EXPERIMENT

基于人工地震资料的珠江口地区最小一维P波速度模型

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