3D P-WAVE VELOCITY STRUCTURE OF CRUST IN FUJIAN AREA AND ITS TECTONIC IMPLICATIONS

doi:10.3969/j.issn.0253-4967.2023.04.010

Abstract

Abstract:

The Fujian area is located tectonically at the southeastern margin of the South China continent, which consists of three sub-blocks, the northwest Fujian block, the southwest Fujian block and the east Fujian block. This region is the forefront of the interaction between the Eurasian plate and the Philippine Sea plate. Geologically, the Fujian area has undergone a complex tectonic evolution process, and the huge intrusive-volcanic rocks formed by multi-stage tectonic changes were widely exposed in this region. Since the inversion of the crustal three-dimensional P-wave velocity structure was important for understanding the tectonic evolution process and the deep seismogenic environment in the region, a lot of research work has been carried out in Fujian area, including seismic body wave tomography, ambient noise surface wave tomography and artificial seismic profiles. Although some important features of the crustal velocity structure in this region had been obtained by natural seismic body wave or ambient noise surface wave imaging, the grid lateral resolution was relatively poor(generally above 0.5° horizontally), which made it difficult to constrain effectively the detailed features of the fault zone velocity structure in this region. For example, the Fu'an-Nanjingfault zone, as an important fault zone in the region, which controlled the magmatic intrusion activities before the Mesozoic, the features of its deep velocity structure have been rarely revealed. Although the resolution of artificial seismic profiles was high, it covered a relatively limited detection range in this region.

In this paper, 3203 natural local earthquakes were selected using the observation reports of Fujian seismic network from 1999 to 2021 and integrating some data from neighboring provinces, which includes both 76423 absolute arrival time data and 389021 P-wave relative arrival time data from131 seismic stations. The test results of checkboard showed that the northwest Fujian block had poor recovery at all depths due to the limited internal seismic ray coverage, most areas of the southwest Fujian block had good recovery at all depths, and the east Fujian block could been recovered at all depths except for its northern region which had poor recovery at 0km, 25km and 30km depth. Under this resolution condition, the three-dimensional crustal P-wave fine velocity structure in Fujian region was obtained. The arrival time residual conforms to a Gaussian distribution before and after the inversion. The travel time residuals of the seismic phases were mainly distributed in the range of -1.5 to 1.5s before the inversion, and these travel time residuals of the seismic phases were mainly distributed in the range of -0.5 to 0.5s after this inversion. The travel time residuals were reduced significantly and were more concentrated around 0. Using the velocity structure obtained from the inversion and combining with the geological structure and geophysical field characteristics of this region, the tectonic implications which may be related to these features of velocity structure in the region were discussed. The main results are as follows:

(1)In the near-surface shallow layer, the P-wave low-velocity feature is mainly correlated better with the NW-trending faults, such as the Nanri island fault, Meizhou bay fault, Yong'an-Jinjiang fault and Jiulong river fault. This may be related to the relatively young activity age and more fragmented shallow parts of the NW-trending faults. The lateral variation of velocity is small in the middle and upper crust at 5km and 10km depths relative to other depths, but there is a relatively high velocity zone of P velocity in northeastern Fujian area.

(2)The P-wave velocity structure shows generally a relatively low velocity feature at 15~25km depth within the southwest Fujian block, especially in the south of the Yong'an-Jinjiang fault zone. Although the range distribution of this low velocity anomaly is relatively large, the magnitude of the anomaly is not large, and the upper crust and the bottom of the lower crust in the southwest Fujian block do not show this anomalous feature. On the other hand, the magnetotelluric sounding of the middle and lower crust of this block shows a high resistivity and the receiver function shows a low Poisson's ratio, this suggests that the low-velocity feature of this block is not caused by partial melt or ductile shear zone, but may be mainly caused by the more quartz-rich composition of the regional crust.

(3)There exist two P-wave low velocity anomalies in the middle-lower crust of the East Fujian block, which are below the two high thermal anomalous area of the geothermal heat flow in this region. It may suggest that the formation of these two relative low velocity anomalies may be related to the transformation of the coastal area into an extensional environment and the upwelling of deep mantle materials caused by the high-angle retraction of the Paleo-Pacific plate in the late Yanshanian period.

(4)The P-wave velocity features show that the velocity at the two sides of the Fuan-Nanjing fault zone is different obviously in the middle and lower crustal depths. This may imply the Fu'an-Nanjing fault has a certain control on the distribution of crustal velocity structure in the region, which is consistent with its deep characteristics of cutting the Moho interface which reflected by the Bourg gravity anomaly and aeromagnetic anomaly, which further confirms that it is a major deep fault zone in the region.

Key words: Fujian area, double-difference tomography, velocity structure, Fu'an-Nanjing fault zone

摘要：

福建地区经历了复杂的构造演化过程, 多期构造变化所形成的巨量侵入-火山岩在该区域广泛出露。文中利用1999-2021年福建地震台网的观测报告, 并融合周边省份的部分数据, 挑选出了3 203个地震, 其中包括76 423条绝对到时数据, 38 9021条P波相对到时数据。采用双差地震层析成像方法获得了福建地区地壳三维P波速度的精细结构, 横向分辨率为0.25°。除闽西北地块外, 其他区域可被检测板较好恢复。研究结果表明: 1)闽西南地块在15~25km深度普遍呈现相对低速特征, 结合区域地质背景、前人的接收函数结果及大地电磁测深数据等分析认为, 该低速特征并非由部分熔融或韧性剪切带所致, 主要是由于区域地壳更富含石英成分引起的; 2)闽东地块的中下地壳存在2个相对低速异常体, 且与地表大地热流异常相对高值区对应; 3)福安-南靖断裂带在中下地壳对该区域的地壳速度分布具有一定的控制作用, 进一步证实其是区域内的一条深大断裂带。

关键词: 福建地区, 双差层析成像, 速度结构, 福安-南靖断裂带

LI Qiang, WU Jian-ping. 3D P-WAVE VELOCITY STRUCTURE OF CRUST IN FUJIAN AREA AND ITS TECTONIC IMPLICATIONS[J]. SEISMOLOGY AND GEOLOGY, 2023, 45(4): 970-986.

李强, 吴建平. 福建地区地壳三维P波速度结构与构造含义[J]. 地震地质, 2023, 45(4): 970-986.

Figures/Tables 8

Fig. 1 Geological setting of the study area(a)and distribution of seismic stations and earthquakes used in this study(b).

Fig. 2 Time-distance curves of P-wave(a)and S-wave(b).

Table 1 Initial 1D velocity model of P waves in the Fujian area

深度/km	0	3	10	15	20	25	31.5	>31.5
V_P/km·s^-1	5.58	5.91	6.01	6.11	6.29	6.60	6.72	8.03

Fig. 3 Optimum smoothing factor(a) and damping parameter(b).

Fig. 4 Resolutions of checkboard tests of P waves at different depths.

Fig. 5 Travel time residual before(gray solid bars)and after(red hollow bars)relocation.

Fig. 6 Map views of VP at various depths.

Fig. 7 Map of VP at different depths.

References 59

[1]	蔡辉腾, 金星, 王善雄, 等. 2016. 宁化-大田-惠安地壳构造与速度结构特征[J]. 地球物理学报, 59(1): 157-168.
	CAI Hui-teng, JIN Xing, WANG Shan-xiong, et al. 2016. The crust structure and velocity structure characteristics beneath Ninghua-Datian-Hui'an[J]. Chinese Journal of Geophysics, 59(1): 157-168 (in Chinese).
[2]	陈耀安, 王培宗. 1982. 福建省区域地球物理、地球化学的基本特征及内生金属矿成矿特点的探讨[J]. 福建地质, 1(2): 69-82.
	CHEN Yao-an, WANG Pei-zong. 1982. The basic features of the regional geophysics and geochemistry in Fujian Province and the discussion on the characteristics of the mineralization of the endogenetic metallic ore deposits[J]. Geology of Fujian, 1(2): 69-82 (in Chinese).
[3]	福建省地质调查研究院. 2016. 中国区域地质志·福建志[M]. 北京: 地质出版社:877.
	Fujian Institute of Geological Survey. 2016. Regional Geology of China, Fujian Province[M]. Geological Publishing House, Beijing: 877 (in Chinese).
[4]	黄海波, 郭兴伟, 夏少红, 等. 2014. 华南沿海地区地壳厚度与泊松比研究[J]. 地球物理学报, 57(12): 3896-3906.
	HUANG Hai-bo, GUO Xing-wei, XIA Shao-hong, et al. 2014. Crustal thickness and Poisson's ratio in the coastal areas of South China[J]. Chinese Journal of Geophysics, 57(12): 3896-3906 (in Chinese).
[5]	李海艳, 蔡辉腾, 金星, 等. 2021. 利用远震P波接收函数研究中国福建地区地壳厚度和泊松比[J]. 地球物理学报, 64(3): 805-822.
	LI Hai-yan, CAI Hui-teng, JIN Xing, et al. 2021. Analysis of the crustal thickness and Poisson's ratio in Fujian, southeast China, from teleseismic P-wave receiver functions[J]. Chinese Journal of Geophysics, 64(3): 805-822 (in Chinese).
[6]	李培, 金星, 王善雄, 等. 2015. 福建邵武-南平-平潭深地震测深剖面的地壳速度结构及其构造意义[J]. 中国科学(地球科学), 45(11): 1757-1767.
	LI Pei, JIN Xing, WANG Shan-xiong, et al. 2015. Crustal velocity structure of the Shaowu-Nanping-Pingtan transect through Fujian from deep seismic sounding-tectonic implications[J]. Science in China(Ser D), 45(11): 1757-1767 (in Chinese).
[7]	李细兵, 宋晓东, 郑斯华, 等. 2019a. 利用人工爆破资料研究福建一维P波速度结构和地震定位[J]. 地球物理学报, 62(5): 1716-1733.
	LI Xi-bing, SONG Xiao-dong, ZHENG Si-hua, et al. 2019a. A 1D P-wave velocity model of Fujian Province, China and earthquake locations from controlled explosions[J]. Chinese Journal of Geophysics, 62(5): 1716-1733 (in Chinese).
[8]	李细兵, 熊振, 范小平, 等. 2019b. 福建地区地壳上地幔顶部三维速度结构及构造意义[J]. 地震地质, 41(5): 1206-1222. doi: 10.3969/j.issn.0253-4967.2019.05.009. DOI
	LI Xi-bing, XIONG Zhen, FAN Xiao-ping, et al. 2019b. The 3-D velocity structure of crust and uppermost mantle and its tectonic implications in Fujian Province[J]. Seismology and Geology, 41(5): 1206-1222 (in Chinese).
[9]	李祖宁, 郑勇, 熊熊, 等. 2014. 福建-台湾地区地壳构造及其显示的动力学构造研究[J]. 地震研究, 37(1): 29-38.
	LI Zu-ning, ZHENG Yong, XIONG Xiong, et al. 2014. Research on crustal three dimensional velocity structure in Fujian-Taiwan region and its tectonic implications[J]. Journal of Seismological Research, 37(1): 29-38 (in Chinese).
[10]	廖其林, 王振明, 邱陶兴, 等. 1990. 福州盆地及其周围地区地壳深部结构与构造的初步研究[J]. 地球物理学报, 33(2): 163-173.
	LIAO Qi-lin, WANG Zhen-ming, QIU Tao-xing, et al. 1990. Preliminary research of the crustal structure in Fuzhou Basin and its adjacent area[J]. Chinese Journal of Geophysics, 33(2): 163-173 (in Chinese).
[11]	蔺文静, 甘浩男, 王贵玲, 等. 2016. 我国东南沿海干热岩赋存前景及与靶区选址研究[J]. 地质学报, 90(8): 2043-2058.
	LIN Wen-jing, GAN Hao-nan, WANG Gui-ling, et al. 2016. Occurrence prospect of HDR and target site selection study in southeastern of China[J]. Acta Geologica Sinica, 90(8): 2043-2058 (in Chinese).
[12]	刘国兴, 韩凯, 韩江涛. 2012. 华南东南沿海地区岩石圈电性结构[J]. 吉林大学学报(地球科学版), 42(2): 536-544.
	LIU Guo-xing, HAN Kai, HAN Jiang-tao. 2012. Lithosphere electrical structure in southeast coastal region, South China[J]. Journal of Jilin University(Earth Science Edition), 42(2): 536-544 (in Chinese).
[13]	罗仁昱, 陈继锋, 尹欣欣, 等. 2021. 青海共和及周边地区的地壳三维速度结构[J]. 地震地质, 43(1): 232-248. doi: 10.3969/j.issn.0253-4967.2021.01.014. DOI
	LUO Ren-yu, CHEN Ji-feng, YIN Xin-xin, et al. 2021. Study on the 3D crustal velocity structure of body-wave in Gonghe area[J]. Seismology and Geology, 43(1): 232-248 (in Chinese).
[14]	马金清, 徐维光. 2010. 福安-南靖断裂带特征及其地质意义讨论[J]. 福建地质, 29(1): 67-72.
	MA Jin-qing, XU Wei-guang. 2010. Discussion on the characteristics and geological meanings of the Fu'an-Nanjing fault zone[J]. Geology of Fujian, 29(1): 67-72 (in Chinese).
[15]	秦社彩, 范蔚茗, 郭锋, 等. 2010. 浙闽晚中生代辉绿岩脉的岩石成因: 年代学与地球化学制约[J]. 岩石学报, 26(11): 3295-3306.
	QIN She-cai, FAN Wei-ming, GUO Feng, et al. 2010. Petrogenesis of Late Mesozoic diabase dikes in Zhejiang-Fujian Provinces: Constraints from Ar-Ar dating and geochemistry[J]. Acta Petrologica Sinica, 26(11): 3295-3306 (in Chinese).
[16]	舒良树, 周新民. 2002. 中国东南部晚中生代构造作用[J]. 地质论评, 48(3): 249-260.
	SHU Liang-shu, ZHOU Xin-min. 2002. Late Mesozoic tectonism of southeast China[J]. Geological Review, 48(3): 249-260 (in Chinese).
[17]	孙洁, 晋光文, 江钊, 等. 2001. 用大地电磁测深法研究华南地区岩浆活动及深部结构[J]. 地震地质, 23(2): 328-329.
	SUN Jie, JIN Guang-wen, JIANG Zhao, et al. 2001. Magmatic activity and the deep structure of south China inferred from magnetotelluric sounding data[J]. Seismology and Geology, 23(2): 328-329 (in Chinese).
[18]	檀玉娟, 段永红, 林吉焱, 等. 2021. 华南大陆东部地壳物质组成的地震学研究[J]. 地球物理学报, 64(9): 3150-3163.
	TAN Yu-juan, DUAN Yong-hong, LIN Ji-yan, et al. 2021. Crustal composition of the eastern South China Block based on the seismological study[J]. Chinese Journal of Geophysics, 64(9): 3150-3163 (in Chinese).
[19]	王长在, 吴建平, 杨婷, 等. 2018. 太原盆地及周边地区双差层析成像[J]. 地球物理学报, 61(3): 963-974.
	WANG Chang-zai, WU Jian-ping, YANG Ting, et al. 2018. Crustal structure beneath the Taiyuan Basin and adjacent areas revealed by double-difference tomography[J]. Chinese Journal of Geophysics, 61(3): 963-974 (in Chinese).
[20]	王鹤年, 凌洪飞, 周丽娅, 等. 2003. 福建马面山群Sm-Nd同位素年龄及其地质意义[J]. 高校地质学报, 9(4): 566-572.
	WANG He-nian, LING Hong-fei, ZHOU Li-ya, et al. 2003. Sm-Nd isotope dating and geological implications for the mesoproterozoic Mamianshan Group in Fujian Province[J]. Geological Journal of China Universities, 9(4): 566-572 (in Chinese).
[21]	王小娜, 邓志辉, 叶秀薇, 等. 2020. 广东阳江地区的地壳速度结构与地震活动性[J]. 地震地质, 42(5): 1153-1171. doi: 10.3969/j.issn.0253-4967.2020.05.008. DOI
	WANG Xiao-na, DENG Zhi-hui, YE Xiu-wei, et al. 2020. The study of crustal velocity structure and seismicity in Yangjiang area of Guangdong Province[J]. Seismology and Geology, 42(5): 1153-1171 (in Chinese).
[22]	王振华, 陈赟, 陈林, 等. 2018. 岩浆底侵的热-流变学效应及对峨眉山大火成岩省的启示[J]. 岩石学报, 34(1): 91-102.
	WANG Zhen-hua, CHEN Yun, CHEN Lin, et al. 2018. Thermal-rheological effects induced by crustal magmatic underplating and implications for Emeishan Large Igneous Province[J]. Acta Petrologica Sinica, 34(1): 91-102 (in Chinese).
[23]	韦德光, 揭育金, 黄廷淦. 1997. 福建省区域地质构造特征[J]. 中国区域地质, 16(2): 51-59.
	WEI De-guang, JIE Yu-jin, HUANG Ting-gan. 1997. Regional geological structure of Fujian[J]. Regional Geology of China, 16(2): 51-59 (in Chinese).
[24]	闻学泽, 徐锡伟, 龙锋, 等. 2007. 中国大陆东部中-弱活动断层潜在地震最大震级评估的震级-频度关系模型[J]. 地震地质, 29(2): 236-253.
	WEN Xue-ze, XU Xi-wei, LONG Feng, et al. 2007. Frequency-magnitude relationship models for assessment of maximum magnitudes of potential earthquakes on moderately and weakly active faults in eastern China mainland[J]. Seismology and Geology, 29(2): 236-253 (in Chinese).
[25]	阳杰华, 刘亮, 刘佳. 2017. 华南中生代大花岗岩省成岩成矿作用研究进展与展望[J]. 矿物学报, 37(6): 791-800.
	YANG Jie-hua, LIU Liang, LIU Jia. 2017. Current progresses and prospect for genesis of extensive Mesozoic granitoid and granitoid-related multi-metal mineralization in Southern China[J]. Acta Mineralogica Sinica, 37(6): 791-800 (in Chinese).
[26]	杨晓平, 顾梦林, 孙振国, 等. 2002. 1906年新疆玛纳斯大震区的多层次逆冲构造与深部结构[J]. 地震地质, 24(3): 303-314.
	YANG Xiao-ping, GU Meng-lin, SUN Zhen-guo, et al. 2002. Multilayered reverse faults and deep structures in the Manas earthquake area, northern Tianshan[J]. Seismology and Geology, 24(3): 303-314 (in Chinese).
[27]	叶卓, 李秋生, 高锐, 等. 2013. 中国大陆东南缘地震接收函数与地壳和上地幔结构[J]. 地球物理学报, 56(9): 2947-2958.
	YE Zhuo, LI Qiu-sheng, GAO Rui, et al. 2013. Seismic receiver functions revealing crust and upper mantle structure beneath the continental margin of southeastern China[J]. Chinese Journal of Geophysics, 56(9): 2947-2958 (in Chinese).
[28]	易锦俊, 张达, 季根源, 等. 2021. 闽西南马坑铁矿稀土元素地球化学及其对矿床成因的指示[J]. 大地构造与成矿学, 45(4): 705-726.
	YI Jin-jun, ZHANG Da, JI Gen-yuan, et al. 2021. REE geochemistry and its implication on genesis of the Makeng iron deposit in southwestern Fujian Province, China[J]. Geotectonica et Metallogenia, 45(4): 705-726 (in Chinese).
[29]	于津海, 刘潜, 胡修棉, 等. 2012. 华南晚古生代岩浆活动的新发现: 岛弧还是陆内造山?[J]. 科学通报, 57(31): 2964-2971.
	YU Jin-hai, LIU Qian, HU Xiu-mian, et al. 2012. Late Paleozoic magmatism in South China: Oceanic subduction or intracontinental orogeny?[J]. Chinese Science Bulletin, 57(31): 2964-2971 (in Chinese).
[30]	于津海, 魏震洋, 王丽娟, 等. 2006. 华夏地块: 一个由古老物质组成的年轻陆块[J]. 高校地质学报, 12(4): 440-447.
	YU Jin-hai, WEI Zhen-yang, WANG Li-juan, et al. 2006. Cathaysia Block: A young continent composed of ancient materials[J]. Geological Journal of China Universities, 12(4): 440-447 (in Chinese).
[31]	张国伟, 郭安林, 王岳军, 等. 2013. 中国华南大陆构造与问题[J]. 中国科学(地球科学), 43(10): 1553-1582.
	ZHANG Guo-wei, GUO An-lin, WANG Yue-jun, et al. 2013. Tectonics of South China continent and its implications[J]. Scientia Sinica(Terrae), 43(10): 1553-1582 (in Chinese).
[32]	张健, 王蓓羽, 唐显春, 等. 2018. 华南陆缘高热流区的壳幔温度结构与动力学背景[J]. 地球物理学报, 61(10): 3917-3932.
	ZHANG Jian, WANG Bei-yu, TANG Xian-chun, et al. 2018. Temperature structure and dynamic background of crust and mantle beneath the high heat flow area of the South China continental margin[J]. Chinese Journal of Geophysics, 61(10): 3917-3932 (in Chinese).
[33]	张丽娜, 罗艳, 陈智勇, 等. 2018. 福建及其邻区背景噪声面波群速度层析成像[J]. 地震, 38(3): 134-143.
	ZHANG Li-na, LUO Yan, CHEN Zhi-yong, et al. 2018. Surface wave group velocity tomography imaging for Fujian area from ambient noise[J]. Earthquake, 38(3): 134-143 (in Chinese).
[34]	张路, 曲国胜, 朱金芳, 等. 2007. 福建沿海盆地第四纪构造运动模式与动力学环境[J]. 地质通报, 26(3): 275-288.
	ZHANG Lu, QU Guo-sheng, ZHU Jin-fang, et al. 2007. Model of Quaternary tectonic movement and dynamic setting of basins along the coast of Fujian, China[J]. Geological Bulletin of China, 26(3): 275-288 (in Chinese).
[35]	张岳桥, 徐先兵, 贾东, 等. 2009. 华南早中生代从印支期碰撞构造体系向燕山期俯冲构造体系转换的形变记录[J]. 地学前缘, 16(1): 234-247.
	ZHANG Yue-qiao, XU Xian-bing, JIA Dong, et al. 2009. Deformation record of the change from Indosinian collision-related tectonic system to Yanshanian subduction related tectonic system in South China during the Early Mesozoic[J]. Earth Science Frontiers, 16(1): 234-247 (in Chinese).
[36]	张振杰, 左仁广. 2015. 闽西南地区大地构造演化和矿床时空分布规律[J]. 岩石学报, 31(1): 217-229.
	ZHANG Zhen-jie, ZUO Ren-guang. 2015. Tectonic evolution of southwestern Fujian Province and spatial-temporal distribution regularity of mineral deposits[J]. Acta Petrologica Sinica, 31(1): 217-229.
[37]	周金城, 蒋少涌, 王孝磊, 等. 2006. 东南沿海晚中生代镁铁质岩的Re-Os同位素组成[J]. 岩石学报, 22(2): 407-413.
	ZHOU Jin-cheng, JIANG Shao-yong, WANG Xiao-lei, et al. 2006. Re-Os isotopic compositions of late Mesozoic mafic rocks from southeastern coast of China[J]. Acta Petrologica Sinica, 22(2): 407-413 (in Chinese).
[38]	朱金芳, 方盛明, 张先康, 等. 2006. 漳州盆地及其邻区地壳深部结构的探测与研究[J]. 中国地震, 22(4): 405-417.
	ZHU Jin-fang, FANG Sheng-ming, ZHANG Xian-kang, et al. 2006. Exploration and research of deep crustal structure in the Zhangzhou Basin and its vicinity[J]. Earthquake Research in China, 22(4): 405-417 (in Chinese).
[39]	Chen J Y, Yang J H, Zhang J H, et al. 2014. Geochemical transition shown by Cretaceous granitoids in southeastern China: Implications for continental crustal reworking and growth[J]. Lithos, 196-197: 115-130. DOI URL
[40]	Gan H N, Wang G L, Wang B, et al. 2022. Abnormally low heat flow in Southeast China resulted from remnant slab subducted beneath the east Asian lithosphere[J]. Terra Nova, 34(4): 1-9. DOI URL
[41]	Gao Y, Wu J, Cai J A, et al. 2009. Shear-wave splitting in the southeast of Cathaysia block, South China[J]. Journal of Seismology, 13(2): 267-275. DOI URL
[42]	Guo F, Wu Y M, Zhang B, et al. 2021. Magmatic responses to Cretaceous subduction and tearing of the paleo-Pacific Plate in SE China: An overview[J]. Earth-Science Reviews, 212(1): 103448. DOI URL
[43]	He Z Y, Xu X S. 2012. Petrogenesis of the late Yanshanian mantle-derived intrusions in southeastern China: Response to the geodynamics of paleo-Pacific plate subduction[J]. Chemical Geology, 328: 208-221. DOI URL
[44]	Hu S B, He L J, Wang J Y. 2000. Heat flow in the continental area of China: A new data set[J]. Earth and Planetary Science Letters, 179(2): 407-419. DOI URL
[45]	Huang Z C, Gou T, Wang L S. 2021. P and S wave tomography of east-central China: Insight into past and present mantle dynamics[J]. Tectonophysics, 809: 228859. DOI URL
[46]	Jiang G Z, Hu S B, Shi Y Z, et al. 2019. Terrestrial heat flow of continental China: Updated dataset and tectonic implications[J]. Tectonophysics, 753: 36-48. DOI URL
[47]	Lin J Y, Xu T, Cai H T, et al. 2021. Crustal velocity structure of Cathaysia Block from an active-source seismic profile between Wanzai and Hui'an in SE China[J]. Tectonophysics, 811: 228874. DOI URL
[48]	Liu L, Xu X S, Xia Y. 2014. Cretaceous Pacific plate movement beneath SE China: Evidence from episodic volcanism and related intrusions[J]. Tectonophysics, 614: 170-184. DOI URL
[49]	Shen L W, Yu J H, O’Reilly S Y, et al. 2018. Tectonic switching of southeast China in the late Paleozoic[J]. Journal of Geophysical Research: Solid Earth, 123(10): 8508-8526. DOI URL
[50]	Spakman W, van der Lee S, van der Hilst R. 1993. Travel-time tomography of the European-Mediterranean mantle down to 1 400km[J]. Physics of the Earth and Planetary Interiors, 79(1-2): 3-74.
[51]	Thurber C H, Brocher T M, Zhang H J, et al. 2007. Three-dimensional P wave velocity model for the San Francisco Bay region, California[J]. Journal of Geophysical Research, 112(B7): B07313.
[52]	Thurber C, Zhang H J, Brocher T, et al. 2009. Regional three-dimensional seismic velocity model of the crust and upper mostmantle of northern California[J]. Journal of Geophysical Research: Solid Earth, 114(B1): B01304.
[53]	Waldhauser F, Ellsworth W L. 2000. A double-difference earthquake location algorithm: Method and application to the northern Hayward Fault, California[J]. Bulletin of the Seismological Society of America, 90(6): 1353-1368. DOI URL
[54]	Zandt G, Beck S L, Ruppert S R, et al. 1996. Anomalous crust of the Bolivian Altiplano, central Andes: Constraints from broadband regional seismic waveforms[J]. Geophysical Research Letters, 23(10): 1159-1162. DOI URL
[55]	Zhang H J, Thurber C. 2006. Development and applications of double-difference seismic tomography[J]. Pure and Applied Geophysics, 163(2): 373-403. DOI URL
[56]	Zhang H J, Thurber C. 2003. Double-difference tomography: The method and its application to the Hayward Fault, California[J]. Bulletin of the Seismological Society of America, 93(5): 1875-1889. DOI URL
[57]	Zhang Y Q, Shi D N, Lü Q T, et al. 2021. A fine crustal structure and geodynamics revealed by receiver functions along the Guangchang-Putian line in the Cathaysia Block, South China[J]. Tectonophysics, 815: 229007. DOI URL
[58]	Zhang Y Y, Yao H J, Xu M, et al. 2020. Upper mantle shear wave velocity structure of southeastern China: Seismic evidence for magma activities in the Late Mesozoic to the Cenozoic[J]. Geochemistry, Geophysics, Geosystems, 21(8): e2020GC009103.
[59]	Zhu S B, Shi Y L. 2011. Estimation of GPS strain rate and its error analysis in the Chinese continent[J]. Journal of Asian Earth Sciences, 40(1): 351-362. DOI URL