背景噪声和地震面波联合反演渭河盆地及邻区壳幔S波速度结构

doi:10.3969/j.issn.0253-4967.2019.05.008

摘要/Abstract

摘要： 利用陕西及邻区测震台网和中国地震科学台阵探测项目共257个宽频带台站记录的连续波形与远震数据，采用基于射线追踪的面波频散直接反演方法获得了渭河盆地及邻区地壳上地幔顶部S波速度结构，成像结果显示：1）渭河盆地顶部形成于新生代的沉积层造成其浅部显著的低速异常，盆地中、上地壳为低速结构，低速带延深至约25km深处，莫霍面相对两侧突变上隆，上地幔高速体侵入下地壳，可能与中-新生代上地幔基性-超基性铁镁质物质底侵有关。2）南鄂尔多斯块体地壳浅层东薄西厚的低速结构可能与块体遭受的整体掀斜、差异性抬升和强烈而不均匀的剥蚀有关。壳内不存在明显的低速异常，说明壳内低速体并没有贯穿整个鄂尔多斯地块，鄂尔多斯南段仍保留着稳定克拉通属性，至今还未遭受明显改造。3）秦岭造山带东、西深部结构存在差异，具有分段特征。造山带下地壳底部的低速异常，可能与造山带受青藏高原东北缘隆升和向外扩展等构造活动的影响有关，分析认为秦岭造山带存在青藏高原物质E流的下地壳流通道的可能性不大。

关键词: 背景噪声, 地震面波, S波速度结构, 渭河盆地, 频散曲线

Abstract: The Weihe Basin is the main component of the extrusion and escape shear zone between the ancient North China craton block in Ordos and the ancient Yangtze platform in Sichuan Basin, and carries the dynamic transmission from the main power source of the Qinghai-Tibet Block in the west to the North China and South China regions in the east. The basin itself plays multi roles in the east-west and north-south tectonic movement, and is an excellent site for studying the structural interlacing, dynamic transformation and transmission. At the same time, Weihe Basin is also a famous strong earthquake zone in China. Historically, there was a strong earthquake of magnitude 8 1/4 occurring in Huaxian County in 1556, causing huge casualties and property losses. In view of the special geological structures and the characteristics of modern seismicity activities in the Weihe fault-depression zone, it is necessary to carry out fine three-dimensional velocity structure detection in the deep part of Weihe Basin and its adjacent areas, so as to study the relationship between velocity structure and geological structural units and their evolution process, as well as the deep medium environment where earth￣quakes develop and occur.
We investigate the S-wave velocity structure beneath Weihe Basin and its adjacent regions based on continuous background noise data and teleseismic data recorded by 257 broadband stations in Shaanxi Province and its adjacent regions and China Seismological Science Array Exploration Project, and by adopting seismic surface wave inter-station method and background noise cross-correlation method, a total of 10 049 fundamental-mode Rayleigh surface wave phase velocity dispersion curves in the periods of 5~70s are obtained. Firstly, using the average dispersion curve in this study area, we obtain the one-dimensional average S-wave velocity structure model of the study area, and then we apply the ray-tracing surface-wave-dispersion direct inversion method to obtain the S-wave velocity structure of the crust and uppermost mantle (3~80km) beneath Weihe Basin and its adjacent regions. The test results of a 1°×1° grid checker board show that the recovery is good, except for the areas east of 111° and south of 32° of the study area, where there is almost no resolution. The imaging results show that the velocity structure beneath each tectonic unit in the study area has a certain distribution rule, and there is a good correlation between surface geological structure and deep velocity structure.
Based on the analysis of velocity slices at different depths and S-wave velocity structures of three profiles, and combined with existing geological structures, geophysics and other deep exploration research results, we obtain the following knowledge and conclusions:1)The thick sedimentary layer covering the top of Weihe Basin is the cause of low velocity anomaly in its shallow crust, the middle and upper crust of the basin are of low velocity structure, and the low-velocity zone extends about 25km, the Moho interface uplifts abruptly relative to both the Ordos Block and the Qinling orogenic belt on opposite sides, and high-speed materials from the upper mantle intrude into the lower crust, which may be related to the underplating of mafic-ultramafic materials from the upper mantle in Mesozoic-Cenozoic period; 2)The south Ordos Block is not a homogeneous whole, the low-velocity structure of the shallow crust in southern Ordos Block is thin in east and thick in west, which may be related to the overall tilting of the Ordos Basin since the Phanerozoic, as well as the differential uplift and strong and uneven denudation of the Ordos Block since the Late Cretaceous. The crustal structure of the south Ordos Block is relatively simple and homogeneous. There is no significant low-velocity structure in the curst of the block, which shows that the low-velocity structure in the crust does not penetrate the whole Ordos block. We speculate that the southern Ordos Block still maintains the stable craton property, and has not been reformed significantly so far; 3)The variation characteristics of deep structure of the Qinling orogenic belt reflect the deep crustal structure and tectonic deformation characteristics of the orogenic belt which are strongly reformed by land-land collision and suture between North China plate and Yangtze plate, intracontinental orogeny, uplift of Qinghai-Tibet Plateau and its northeastern expansion since the Late Hercynian-Indosinian period. The deep structure beneath the eastern and western Qinling orogenic belt is different and has the characteristics of segmentation. The low-velocity anomaly at the bottom of the lower crust of the orogenic belt may be affected by tectonic activities such as uplift and outward extension of the NE Tibetan plateau, and the analysis considers that there is little possibility of the existence of lower crustal circulation channel for the eastward flowing of Tibetan plateau materials in the Qinling orogenic belt. However, since the maximum depth from the inversion of this paper is 80km, which is located at the top of the upper mantle, our results cannot prove that there exists a mantle flow channel for the eastward flow of Tibetan plateau material beneath the Qinling orogenic belt.

Key words: ambient noise, seismic surface wave, S-wave velocity structure, Weihe Basin, dispersion curve

中图分类号:

P315.3⁺1

冯红武, 颜文华, 严珊, 郭瑛霞, 惠少兴, 常城. 背景噪声和地震面波联合反演渭河盆地及邻区壳幔S波速度结构[J]. 地震地质, 2019, 41(5): 1185-1205.

FENG Hong-wu, YAN Wen-hua, YAN Shan, GUO Ying-xia, HUI Shao-xing, CHANG Cheng. JOINT INVERSION OF AMBIENT NOISE AND SURFACE WAVE FOR S-WAVE VELOCITY OF THE CRUST AND UPPERMOST MANTLE BENEATH WEIHE BASIN AND ITS ADJACENT AREA[J]. SEISMOLOGY AND GEOLOGY, 2019, 41(5): 1185-1205.

参考文献

常利军, 王椿镛, 丁志峰. 2011. 鄂尔多斯块体及周缘上地幔各向异性研究［J］. 中国科学(D辑), 41(5):686-699.
CHANG Li-jun, WANG Chun-yong, DING Zhi-feng. 2011. Upper mantle anisotropy in the Ordos Block and its margins［J］. Science in China(Ser D), 41(5):686-699(in Chinese).
陈凌, 危自根, 程骋. 2010. 从华北克拉通中、西部结构的区域差异性探讨克拉通破坏［J］. 地学前缘, 17(1):212-228.
CHEN Ling, WEI Zi-gen, CHENG Cheng. 2010. Significant structural variation in the central and western North China craton and its implications for the craton destruction［J］. Earth Science Frontiers, 17(1):212-228(in Chinese).
陈强森, 鲍学伟, 徐树斌, 等. 2013. 利用背景噪声反演鄂尔多斯块体及其南缘地区地壳速度结构［J］.高校地质学报, 19(3):504-512.
CHEN Qiang-sen, BAO Xue-wei, XU Shu-bin, et al. 2013. The crustal velocity structure of the Ordos Block and its southern edge revealed from the ambient seismic noise extraction［J］. Geological Journal of China Universities, 19(3):504-512(in Chinese).
邓军, 王庆飞, 黄定华, 等. 2005. 鄂尔多斯盆地基底演化及其对盖层控制作用［J］. 地学前缘, 12(3):91-99.
DENG Jun, WANG Qing-fei, HUANG Ding-hua, et al. 2005. Basement evolution of the Ordos Basin and its constraint on cap rock［J］. Earth Science Frontiers, 12(3):91-99(in Chinese).
丁韫玉, 狄秀玲, 袁志祥. 2000. 渭河断陷地壳三维S波速度结构和V_P/V_S分布图像［J］. 地球物理学报, 43(2):194-202.
DING Yun-yu, DI Xiu-ling, YUAN Zhi-xiang. 2000. Three-dimensional shear wave velocity structure and distribution image of V_P/V_S beneath the Weihe fault depression［J］. Chinese Journal of Geophysics, 43(2):194-202(in Chinese).
房立华, 吴建平, 吕作勇. 2009. 华北地区基于噪声的瑞利面波群速度层析成像［J］. 地球物理学报, 52(3):663-671.
FANG Li-hua, WU Jian-ping, LÜ Zuo-yong. 2009. Rayleigh wave group velocity tomography from ambient seismic noise in North China［J］. Chinese Journal of Geophysics, 52(3):663-671(in Chinese).
国家地震局"鄂尔多斯周缘活动断裂系"课题组. 1988. 鄂尔多斯周缘活动断裂系［M］. 北京:地震出版社:114-136.
The Research Group on Active Fault System around Ordos Massif, State Seismological Bureau. 1988. Active Fault System around Ordos Massif［M］. Seismological Press, Beijing:114-136(in Chinese).
韩恒悦, 张逸, 袁志祥. 2002. 渭河断陷盆地带的形成演化及断块运动［J］. 地震研究, 25(4):362-368.
HAN Heng-yue, ZHANG Yi, YUAN Zhi-xiang. 2002. The evolution of Weihe down-faulted basin and the movement of the fault blocks［J］. Journal of Seismological Research, 25(4):362-368(in Chinese).
贺伟光, 陈永顺, 叶庆东, 等. 2015. 秦岭及周边地区背景噪声Love波层析成像［J］. 地球物理学进展, 30(1):47-56.
HE Wei-guang, CHEN Yong-shun, YE Qing-dong, et al. 2015. Ambient noise Love wave tomography in Qinling orogeny and surrounding area［J］. Progress in Geophysics, 30(1):47-56(in Chinese).
黄方, 何丽娟, 吴庆举. 2015. 鄂尔多斯盆地深部热结构特征及其对华北克拉通破坏的启示［J］. 地球物理学报, 58(10):3671-3686.
HUANG Fang, HE Li-juan, WU Qing-ju. 2015. Lithospheric thermal structure of the Ordos Basin and its implication to destruction of the North China Craton［J］. Chinese Journal of Geophysics, 58(10):3671-3686(in Chinese).
贾萌, 王显光, 李世林, 等. 2015. 鄂尔多斯块体及周边区域地壳结构的接收函数研究［J］. 地球物理学进展, 30(6):2474-2481.
JIA Meng, WANG Xian-guang, LI Shi-lin, et al. 2015. Crustal structure of Ordos block and surrounding regions from receiver functions［J］. Progress in Geophysics, 30(6):2474-2481(in Chinese).
李晨晶, 白登海, 薛帅, 等. 2017. 鄂尔多斯地块深部岩石圈典型结构研究［J］. 地球物理学报, 60(5):1788-1799.
LI Chen-jing, BAI Deng-hai, XUE Shuai, et al. 2017. A magnetotelluric study of the deep electric structure beneath the Ordos Block［J］. Chinese Journal of Geophysics, 60(5):1788-1799(in Chinese).
李洪强, 高锐, 王海燕, 等. 2014. 用深反射大炮对大巴山-秦岭结合部位的地壳下部和上地幔成像［J］. 地球物理学进展, 29(1):102-109.
LI Hong-qiang, GAO Rui, WANG Hai-yan, et al. 2014. Imaging the lower crust and upper mantle beneath between Qinling and Dabashan by big shots from deep seismic reflection in China［J］. Progress in Geophysics, 29(1):102-109(in Chinese).
李文辉, 高锐, 王海燕, 等. 2017. 六盘山断裂带及其邻区地壳结构［J］. 地球物理学报, 60(6):2265-2278.
LI Wen-hui, GAO Rui, WANG Hai-yan, et al. 2017. Crustal structure beneath the Liupanshan fault zone and adjacent regions［J］. Chinese Journal of Geophysics, 60(6):2265-2278(in Chinese).
李英康, 高锐, 高建伟, 等. 2015. 秦岭造山带的EW向地壳速度结构特征［J］. 地球物理学进展, 30(3):1056-1069.
LI Ying-kang, GAO Rui, GAO Jian-wei, et al. 2015. Characteristics of crustal velocity structure along Qinling orogenic belt［J］. Progress in Geophysics, 30(3):1056-1069(in Chinese).
凌媛, 陈凌, 危自根, 等. 2017. 利用噪声层析成像研究华北克拉通中-西部南段及邻区祁连造山带地壳S波各向异性速度结构［J］. 中国科学(D辑), 47(10):1202-1219.
LING Yuan, CHEN Ling, WEI Zi-gen, et al. 2017. Crustal S-velocity structure and radial anisotropy beneath the southern part of central and western North China Craton and the adjacent Qilian orogenic belt from ambient noise tomography［J］. Science in China(Ser D), 47(10):1202-1219(in Chinese).
刘宝峰, 李松林, 张先康, 等. 2003. 玛沁-靖边剖面S波资料研究与探讨［J］. 地震学报, 25(1):82-88.
LIU Bao-feng, LI Song-lin, ZHANG Xian-kang, et al. 2003. Study of crustal structure with S-wave data from Maqin-Jingbian profile［J］. Acta Seismologica Sinica, 25(1):82-88(in Chinese).
刘池洋, 赵红格, 桂小军, 等. 2006. 鄂尔多斯盆地演化-改造的时空坐标及其成藏(矿)响应［J］. 地质学报, 80(5):617-638.
LIU Chi-yang, ZHAO Hong-ge, GUI Xiao-jun, et al. 2006. Space-time coordinate of the evolution and reformation and mineralization response in Ordos Basin［J］. Acta Geologica Sinica, 80(5):617-638(in Chinese).
路利春, 王鹏, 周明霞, 等. 2017. 渭河盆地重力场与构造特征关系研究［J］. 大地测量与地球动力学, 37(S1):36-42.
LU Li-chun, WANG Peng, ZHOU Ming-xia, et al. 2017. Study on the relationship gravity field and structural characteristics in Weihe River Basin［J］. Journal of Geodesy and Geodynamics, 37(S1):36-42(in Chinese).
马丽芳. 2007. 中国地质图集［CM］. 北京:地质出版社:318-319.
MA Li-fang. 2007. China Geological Atlas［CM］. Geological Publishing House, Beijing:318-319(in Chinese).
任隽, 彭建兵, 王夫运, 等. 2012. 渭河盆地及邻区地壳深部结构特征研究［J］. 地球物理学报, 55(9):2939-2947.
REN Jun, PENG Jian-bing, WANG Fu-yun, et al. 2012. The research of deep structural features of Weihe Basin and adjacent areas［J］. Chinese Journal of Geophysics, 55(9):2939-2947(in Chinese).
司芗, 滕吉文, 刘有山, 等. 2016. 秦岭造山带与南北相邻地带远震接收函数与地壳结构［J］. 地球物理学报, 59(4):1321-1334.
SI Xiang, TENG Ji-wen, LIU You-shan, et al. 2016. Crust structure of the Qinling orogenic and the region on its north and south margins from teleseismic receiver function［J］. Chinese Journal of Geophysics, 59(4):1321-1334(in Chinese).
滕吉文, 李松岭, 张永谦, 等. 2014. 秦岭造山带与邻域华北克拉通和扬子克拉通的壳、幔精细速度结构与深层过程［J］. 地球物理学报, 57(10):3154-3175.
TENG Ji-wen, LI Song-ling, ZHANG Yong-qian, et al. 2014. Fine velocity structure and deep process in crust and mantle of the Qinling orogenic belt and the adjacent North China craton and Yangtze craton［J］. Chinese Journal of Geophysics, 57(10):3154-3175(in Chinese).
童蔚蔚, 王良书, 米宁, 等. 2007. 利用接收函数研究六盘山地区地壳上地幔结构特征［J］. 中国科学(D辑), 37(S1):193-198.
TONG Wei-wei, WANG Liang-shu, MI Ning, et al. 2007. The crust and uppermost mantle structures of Liupanshan regions from receiver functions［J］. Science in China(Ser D), 37(S1):193-198(in Chinese).
王椿镛, 吴庆举, 段永红, 等. 2017. 华北地壳上地幔结构及其大地震深部构造成因［J］. 中国科学(D辑), 47(6):684-719.
WANG Chun-yong, WU Qing-ju, DUAN Yong-hong, et al. 2017. Crustal and upper mantle structure and deep tectonic genesis of large earthquakes in North China［J］. Science in China(Ser D), 47(6):684-719(in Chinese).
王娟娟, 姚华建, 王伟涛, 等. 2018. 基于背景噪声成像方法的新疆呼图壁储气库地区近地表速度结构研究［J］. 地球物理学报, 61(11):4436-4447.
WANG Juan-juan, YAO Hua-jian, WANG Wei-tao, et al. 2018. Study of the near-surface velocity structure of the Hutubi gas storage area in Xinjiang from ambient noise tomography［J］. Chinese Journal of Geophysics, 61(11):4436-4447(in Chinese).
王兴臣, 丁志峰, 武岩, 等. 2017. 中国南北地震带北段及其周缘地壳厚度与泊松比研究［J］. 地球物理学报, 60(6):2080-2090.
WANG Xing-chen, DING Zhi-feng, WU Yan, et al. 2017. Crustal thicknesses and Poisson's ratios beneath the northern section of the North-South Seismic Belt and surrounding areas in China［J］. Chinese Journal of Geophysics, 60(6):2080-2090(in Chinese).
危自根, 褚日升, 陈凌. 2015. 华北克拉通地壳结构区域差异的接收函数研究［J］. 中国科学(D辑), 45(10):1504-1514.
WEI Zi-gen, CHU Ri-sheng, CHEN Ling. 2015. Regional differences in crustal structure of the North China Craton from receiver functions［J］. Science in China(Ser D), 45(10):1504-1514(in Chinese).
徐树斌, 米宁, 徐鸣洁, 等. 2013. 利用接收函数研究渭河地堑及其周边地壳结构［J］. 中国科学(D辑), 43(10):1651-1658.
XU Shu-bin, MI Ning, XU Ming-jie, et al. 2013. Crustal structures of the Weihe graben and its surroundings from receiver functions［J］. Science in China(Ser D), 43(10):1651-1658(in Chinese).
杨志华, 郭俊锋, 苏生瑞, 等. 2002. 秦岭造山带基础地质研究新进展［J］. 中国地质, 29(3):246-256.
YANG Zhi-hua, GUO Jun-feng, SU Sheng-rui, et al. 2002. New advances in the geological study of the Qinling orogen［J］. Geology in China, 29(3):246-256(in Chinese).
姚华建, 徐果明, 肖翔. 2004. 基于图像分析的双台面波相速度频散曲线快速提取方法［J］. 地震地磁观测与研究, 25(1):1-8.
YAO Hua-jian, XU Guo-ming, XIAO Xiang. 2004. A quick tracing method based on image analysis technique for the determination of interstation phase velocities dispersion curve of surface wave［J］. Seismological and Geomagnetic Observation and Research, 25(1):1-8(in Chinese).
余大新, 李永华, 吴庆举, 等. 2014. 利用Rayleigh波相速度和群速度联合反演青藏高原东北缘S波速度结构［J］. 地球物理学报, 57(3):800-811.
YU Da-xin, LI Yong-hua, WU Qing-ju, et al. 2014. S-wave velocity structure of the northeastern Tibetan plateau from joint inversion of Rayleigh wave phase and group velocities［J］. Chinese Journal of Geophysics, 57(3):800-811(in Chinese).
张国伟, 孟庆任, 赖绍聪. 1995. 秦岭造山带的结构构造［J］. 中国科学(B辑), 25(9):994-1003.
ZHANG Guo-wei, MENG Qing-ren, LAI Shao-cong. 1995. Structure construction of the Qinling orogenic belt［J］. Science in China(Ser B), 25(9):994-1003(in Chinese).
赵国泽, 詹艳, 王立凤, 等. 2010. 鄂尔多斯断块地壳电性结构［J］. 地震地质, 32(3):345-359. doi:10.3969/j.issn.0253-4967.2010.03.001.
ZHAO Guo-ze, ZHAN Yan, WANG Li-feng, et al. 2010. Electric structure of the crust beneath the Ordos fault block［J］. Seismology and Geology, 32(3):345-359(in Chinese).
郑晨, 丁志峰, 宋晓东. 2018. 面波频散与接收函数联合反演南北地震带北段壳幔速度结构［J］. 地球物理学报, 61(4):1211-1224.
ZHENG Chen, DING Zhi-feng, SONG Xiao-dong. 2018. Joint inversion of surface wave dispersion and receiver function for crustal and uppermost mantle structure beneath the northern North-South Seismic Zone［J］. Chinese Journal of Geophysics, 61(4):1211-1224(in Chinese).
周鼎武, 李文厚, 张云翔, 等. 2002. 区域地质综合研究的方法与实践［M］. 北京:科学出版社.
ZHOU Ding-wu, LI Wen-hou, ZHANG Yun-xiang, et al. 2002. Methods and Practice of Comprehensive Regional Geological Research［M］. Science Press, Beijing(in Chinese).
Bensen G D, Ritzwoller M H, Barmin M P, et al. 2007. Processing seismic ambient noise data to obtain reliable broad-band surface wave dispersion measurements［J］. Geophysical Journal International, 169(3):1239-1260.
Cheng C, Chen L, Yao H J, et al. 2013. Distinct variations of crustal shear wave velocity structure and radial anisotropy beneath the North China Craton and tectonic implications［J］. Gondwana Research, 23(1):25-38.
Enkelmann E, Ratschbacher L, Jonckheere R, et al. 2006. Cenozoic exhumation and deformation of northeastern Tibet and the Qinling:Is Tibetan lower crustal flow diverging around the Sichuan Basin?［J］. Geological Society of America Bulletin, 118(5-6):651-671.
Fang H J, Yao H J, Zhang H J. 2015. Direct inversion of surface wave dispersion for three-dimensional shallow crustal structure based on ray tracing:Methodology and application［J］. Geophysical Journal International, 201(3):1251-1263.
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.
Li C, Yao H J, Fang H J, et al. 2016. 3-D near-surface shear-wave velocity structure from ambient-noise tomography and borehole data in the Hefei urban area, China［J］. Seismological Research Letters, 87(4):882-892.
Li Y H, Gao M T, Wu Q J. 2014. Crustal thickness map of the Chinese mainland from teleseismic receiver functions［J］. Tectonophysics, 611:51-60.
Li Y H, Wu Q J, Pan J T, et al. 2013. An upper-mantle S wave velocity model for East Asia from Rayleigh wave tomography［J］. Earth and Planetary Science Letters, 377-378:367-377.
Lin F C, Moschetti M P, Ritzwoller M H. 2008. Surface wave tomography of the western United States from ambient seismic noise:Rayleigh and Love wave phase velocity maps［J］. Geophysical Journal International, 173(1):281-298.
Pavlis N K, Holmes S A, Kenyon S C, et al. 2012. The development and evaluation of the Earth Gravitational Model 2008(EGM2008)［J］. Journal of Geophysical Research, 117:B04406.
Rawlinson N, Sambridge M. 2004. Wave front evolution in strongly heterogeneous layered media using the fast marching method［J］. Geophysical Journal International, 156(3):631-647.
Seguin M K, Zhai Y J. 1995. Paleomagnetic constraints on the convergence of the Sino-Korean and Yangtze blocks, China［J］. Chinese Journal of Geophysics, 38(1):34-45.
Shapiro N M, Campillo M, Stehly L, et al. 2005. High-resolution surface wave tomography from ambient seismic noise［J］. Science, 37:1615-1618.
Song P H, Teng J W, Zhang X M, et al. 2018. Flyover crustal structures beneath the Qinling orogenic belt and its tectonic implications［J］. Journal of Geophysical Research:Solid Earth, 123(8):6703-6718.
Wang C Y, Sandvol E, Zhu L P, et al. 2014. Lateral variation of crustal structure in the Ordos block and surrounding regions, North China, and its tectonic implications［J］. Earth and Planetary Science Letters, 387:198-211.
Wang Q, Niu F, Gao Y, et al. 2016. Crustal structure and deformation beneath the NE margin of the Tibetan plateau constrained by teleseismic receiver function data［J］. Geophysical Journal International, 204(1):167-179.
Wang W L, Wu J P, Fang L H, et al. 2017. Sedimentary and crustal thicknesses and Poisson's ratios for the NE Tibetan plateau and its adjacent regions based on dense seismic arrays［J］. Earth and Planetary Science Letters, 462:76-85.
Wei Z G, Chen L, Xu W W. 2011. Crustal thickness and V_P/V_S ratio of the central and western North China Craton and its tectonic implications［J］. Geophysical Journal International, 186(2):385-389.
Yao H J, Beghein C, van der Hilst R D. 2008. Surface wave array tomography in SE Tibet from ambient seismic noise and two-station analysis Ⅱ. Crustal and upper-mantle structure［J］. Geophysical Journal International, 173(1):205-219.
Yao H J, Gouedard P, McGuire J, et al. 2011. Structure of young East Pacific Rise lithosphere from ambient noise correlation analysis of fundamental- and higher-mode Scholte-Rayleigh waves［J］. Comptes Rendus Geoscience, 343(8-9):571-583.
Yao H J, van der Hilst R D, de Hoop M V. 2006. Surface-wave array tomography in SE Tibet from ambient seismic noise and two-station analysis:I. Phase velocity maps［J］. Geophysical Journal International, 166(2):732-744.
Zhai M, Liu W J. 2003. Palaeoproterozoic tectonic history of the North China Craton:A review［J］. Precambrian Research, 122(1-4):183-199.
Zheng T, Zhao L, Zhu R. 2009. New evidence from seismic imaging for subduction during assembly of the North China Craton［J］. Geology, 37(5):395-398.
Zheng Y, Yang Y J, Ritzwoller M H, et al. 2010. Crustal structure of the northeastern Tibetan plateau, the Ordos block and the Sichuan Basin from ambient noise tomography［J］. Earthquake Science, 23(5):465-476.

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