THE FINE CRUSTAL STRUCTURE OF THE SOUTHERN MARGIN OF NORTH CHINA BLOCK REVEALED BY DEEP SEISMIC REFLECTION PROFILE

doi:10.3969/j.issn.0253-4967.2020.03.003

Abstract

Abstract: The study area is located at the junction of the northern margin of the Qinling orogenic belt and the southern margin of the North China Block. In order to study the fine crustal structure and the deep-shallow structural features of faults in this area, we conducted deep seismic reflection profiling with the seismic profile of 100km long, directing NE-SW in Zhumadian City, Henan Province, and got clear lithospheric structure images along the profile. As regards the data acquisition, we applied the geometry of 25m group interval, 1000 recording channels and more than 60 folds. Seismic wave exploding applies the 30kg shots of dynamite source with the borehole depth of 25m. The shot interval is 200m. In data processing, we focused on improving the signal-to-noise ratio. Data processing methods mainly include first break removal, tomographic static correction, abnormal amplitude elimination, amplitude compensation, pre-stack denoising, surface consistent deconvolution, velocity analysis, several iterations of the residual static correction, dip moveout, post-stack time migration and post-stack denoising, etc. The profile with high signal-to-noise ratio was obtained. The reflection wave group characteristics is obvious in the crust, which reflects abundant information about geological structure. Along the profile, the crust is characterized by double-layer reflection structure, and the Moho surface is composed of a series of laminated arc-shaped strong reflections. The thickness of the upper crust is about 14.8~20.7km, and the total thickness of the crust is about 32.0~35.1km. The upper crust is dominated by the inclined, densely stratified or arc-shaped reflections. The lower crust is dominated by arc-shaped and inclined reflection, and there is a reflective transparent zone under the Moho surface. The reflection sequences with different directions and shapes in the upper crust constitute the nappe structure in southwest segment and the structural model of two concaves with one uplift in NE segment, which correspond to the north Qinling nappe, Zhumadian-Huaibin depression, Pingyu-Xiping uplift and a secondary depression, respectively. There are abundant arc-shaped reflection sequences in the lower crust, which may represent multi-stage magmatic activities. The deep seismic reflection profile shows that faults in the upper crust are well developed. According to the characteristics of reflected wave field in the profile, four groups of fault structure which contain ten faults with different scales are interpreted. Among them, faults F_P1, F_P2 and F_P3 constitute the thrust fault system in the northern margin of Qinling Mountains, and F_P5 and F_P7 are boundary faults of Zhumadian-Huaibin depression. These faults are all developed within the upper crust. In addition, the Fault F_PM is a large fault that cuts through the lower crust and Moho surface. The deep seismic reflection profile reveals the crustal structure and deep-shallow structural features of faults at the junction of the northern margin of the Qinling orogenic belt and the southern margin of the North China block, which provides seismological evidence for the analysis of structural differences, the deep earth's interior processes and deep-shallow structural relationships between the Qinling-Dabie orogenic belt and the southern margin of the North China block. The lower crust of the study area is divided into two parts by deep faults that dislocate the Moho surface. These two parts have distinct reflective structures, suggesting that the area has experienced intense complex tectonic movements. The faults in the upper crust control the formation of basin-mountain structure and stratigraphic deposition of this area. And deep faults in the crust that disrupt Moho surface create conditions for the upwelling and energy exchange of deep materials. All of these have regulated the composition of material and the distribution of energy in the crust. The deep faults cutting through the lower crust and Moho surface and the south-dipping arc-shaped and inclined strong reflection sequences developed in the lower crust should indicate the large-scale subduction of the southern margin of the North China block towards the south-trending Qinling orogenic belt.

Key words: deep seismic reflection profiling, Qinling orogenic belt, the southern margin of North China block, overthrust structure

摘要： 文中基于长100km的深地震反射剖面, 揭示了秦岭造山带北缘和华北地块南缘交接部位的地壳精细结构和断裂的深、浅构造特征。结果显示, 研究区地壳具有双层反射结构特征, 莫霍面由一系列叠层状的弧形强反射构成, 地壳厚约32~35km。上地壳内一系列方向不同、形态各异的反射波组分别对应秦岭北缘的逆冲推覆体及伸展构造环境下形成的沉积盆地。下地壳以错断莫霍面的地壳深断裂为界, 具有南、北2段明显不同的反射结构。剖面南段以弧状强反射为主, 北段由产状近水平或S倾的叠层状反射构成, 暗示该区曾经历强烈、复杂的构造运动。剖面揭示的上地壳断裂控制了该区盆山构造的形成和地层沉积, 错断莫霍面的地壳深断裂为深部物质的上涌和能量交换创造了条件, 从而调节了地壳内部的物质构成和能量分配。

关键词: 深地震反射剖面, 秦岭造山带, 华北地块南缘, 莫霍面

CLC Number:

P315.2

FENG Shao-ying, LIU Bao-jin, LI Qian, YUAN Hong-ke, ZHU Guo-jun, TIAN Yi-ming, WANG Hong-wei, HOU Li-hua, DENG Xiao-juan, TAN Ya-li. THE FINE CRUSTAL STRUCTURE OF THE SOUTHERN MARGIN OF NORTH CHINA BLOCK REVEALED BY DEEP SEISMIC REFLECTION PROFILE[J]. SEISMOLOGY AND GEOLOGY, 2020, 42(3): 581-594.

酆少英, 刘保金, 李倩, 袁洪克, 朱国军, 田一鸣, 王宏伟, 侯黎华, 邓小娟, 谭雅丽. 深地震反射剖面揭示的华北地块南缘地壳的精细结构[J]. 地震地质, 2020, 42(3): 581-594.

References

[1] 陈睿, 闫俊岗, 郁军建. 2016. 利用接收函数研究河南及邻区的地壳深部构造特征[J]. 中国地震, 32(4): 618-626.
CHEN Rui, YAN Jun-gang, YU Jun-jian.2016. Study on the structural characteristics of the deep crust in Henan Province and its adjacent areas by using the receiver function[J]. Earthquake Research in China, 32(4): 618-626(in Chinese).
[2] 高锐, 王海燕, 马永生, 等. 2006. 松潘地块若尔盖盆地与西秦岭造山带岩石圈尺度的构造关系: 深地震反射剖面探测成果[J]. 地球学报, 27(5): 411-418.
GAO Rui, WANG Hai-yan, MA Yong-sheng, et al.2006. Tectonic relationships between the Ziog Basin of the Songpan block and the west Qinling orogen at lithosphere scale: Results of deep seismic reflection profiling[J]. Acta Geoscientica Sinica, 27(5): 411-418(in Chinese).
[3] 何建坤, 刘福田, 刘建华, 等. 1998. 东秦岭造山带莫霍面展布与碰撞造山带深部过程的关系[J]. 地球物理学报, 41(S1): 64-76.
HE Jian-kun, LIU Fu-tian, LIU Jian-hua, et al.1998. The morphology of Moho discontinuity and its evolution geodynamics in the eastern Qinling collisional orogenic belt[J]. Chinese Journal of Geophysics, 41(S1): 64-76(in Chinese).
[4] 黄兴富, 酆少英, 高锐, 等. 2016. 银川盆地构造发展: 深地震反射剖面揭示浅部地质与深部构造的联系[J]. 地质科学, 51(1): 53-66.
HUANG Xing-fu, FENG Shao-ying, GAO Rui, et al.2016. Development of the Yinchuan Basin: Deep seismic reflection profile revealed the linkages between shallow geology and deep structures[J]. Chinese Journal of Geology, 51(1): 53-66(in Chinese).
[5] 黄泽光, 高长林. 2007. 秦岭-大别造山带北侧盆地序列及油气前景[J]. 石油实验地质, 29(1): 25-31.
HUANG Ze-guang, GAO Chang-lin.2007. Basin sequence and oil-gas potential in near northern Qinling-Dabie Mountains[J]. Petroleum Geology and Experiment, 29(1): 25-31(in Chinese).
[6] 嘉世旭, 张先康. 2005. 华北不同构造块体地壳结构及其对比研究[J]. 地球物理学报, 48(3): 611-620.
JIA Shi-xu, ZHANG Xian-kang.2005. Crustal structure and comparison of different tectonic blocks in North China[J]. Chinese Journal of Geophysics, 48(3): 611-620(in Chinese).
[7] 赖绍聪, 张国伟, 杨永成, 等. 1997. 南秦岭勉县-略阳结合带变质火山岩岩石地球化学特征[J]. 岩石学报, 13(4): 563-573.
LAI Shao-cong, ZHANG Guo-wei, YANG Yong-cheng, et al.1997. Petrology and geochemistry features of the metamorphic volcanic rocks in Mianxian-Lueyang suture zone, south Qinling[J]. Acta Petrologica Sinica, 13(4): 563-573(in Chinese).
[8] 李春昱, 刘仰文, 朱宝清, 等. 1978. 秦岭及祁连山构造发展史 [C]∥国际交流地质学术论文集(1). 北京: 地质出版社: 174-187.
LI Chun-yu, LIU Yang-wen, ZHU Bao-qing, et al.1978. Tectonic evolution of Qinling and Qilian Mountains [C]∥ International Collected Geological Research Works. Geological Publishing House, Beijing: 174-187(in Chinese).
[9] 李春昱, 王荃, 刘雪亚, 等. 1982. 亚洲大地构造图及说明书 [M]. 北京: 地图出版社: 1-49.
LI Chun-yu, WANG Quan, LIU Xue-ya, et al.1982. Explanatory Notes to the Tectonic Map of Asia [M]. Geological Publishing House, Beijing: 1-49(in Chinese).
[10] 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).
[11] 卢占武, 高锐, 王海燕, 等. 2014. 深地震反射剖面上的“亮点”构造[J]. 地球物理学进展, 29(6): 2518-2525.
LU Zhan-wu, GAO Rui, WANG Hai-yan, et al.2014. Bright spots in deep seismic reflection profiles[J]. Progress in Geophysics, 29(6): 2518-2525(in Chinese).
[12] 孟庆任. 2017. 秦岭的由来[J]. 中国科学(D辑), 47(4): 412-420.
MENG Qing-ren.2017. Origin of the Qinling Mountains[J]. Science in China(Ser D), 47(4): 412-420(in Chinese).
[13] 宋秀青, 朱元清. 2015. 中国大陆地壳速度模型发展综述[J]. 地震地磁观测与研究, 36(5): 149-152.
SONG Xiu-qing, ZHU Yuan-qing.2015. A survey of the crustal velocity models in mainland China[J]. Seismological and Geomagnetic Observation and Research, 36(5): 149-152(in Chinese).
[14] 宋子堂. 1994. 华北板块南缘壳内拆离及对大别山北麓逆冲断层系形成的影响[J]. 石油实验地质, 16(3): 250-255.
SONG Zi-tang.1994. Intracrustal detachment in the southern margin of the North China plate and its influence over the formation of overthrust system in northern Dabieshan[J]. Experimental Petroleum Geology, 16(3): 250-255(in Chinese).
[15] 孙晓猛, 张梅生, 龙胜祥, 等. 2004. 秦岭-大别造山带北部逆冲推覆构造与合肥盆地、周口坳陷控盆断裂[J]. 石油与天然气地质, 25(2): 191-198.
SUN Xiao-meng, ZHANG Mei-sheng, LONG Sheng-xiang, et al.2004. Overthrust tectonic in northern Qinling-Dabie orogenic belt and basin-controlling faults in Zhoukou depression and Hefei Basin[J]. Oil & Gas Geology, 25(2): 191-198(in Chinese).
[16] 孙自明, 熊保贤. 1999. 周口坳陷的逆冲推覆构造特征[J]. 石油勘探与开发, 26(3): 22-24.
SUN Zi-ming, XIONG Bao-xian.1999. The overthrust tectonic characteristics in Zhoukou depression[J]. Petroleum Exploration and Development, 26(3): 22-24(in Chinese).
[17] 滕吉文, 李松岭, 张永谦, 等. 2014. 秦岭造山带与沉积盆地和结晶基底地震波场及动力学响应[J]. 地球物理学报, 57(3): 770-788.
TENG Ji-wen, LI Song-ling, ZHANG Yong-qian, et al.2014. Seismic wave fields and dynamical response for Qinling orogen and sedimentary basins and crystalline basement[J]. Chinese Journal of Geophysics, 57(3): 770-788(in Chinese).
[18] 王海燕, 高锐, 卢占武, 等. 2010. 深地震反射剖面揭露大陆岩石圈精细结构[J]. 地质学报, 84(6): 818-839.
WANG Hai-yan, GAO Rui, LU Zhan-wu, et al.2010. Fine structure of the continental lithosphere circle reflection profile[J]. Acta Geologica Sinica, 84(6): 818-839(in Chinese).
[19] 王清晨, 孙枢, 李继亮, 等. 1989. 秦岭的大地构造演化[J]. 地质科学, 24(2): 129-142.
WANG Qing-chen, SUN Shu, LI Ji-liang, et al.1989. The tectonic evolution of Qinling Mountain belt[J]. Chinese Journal of Geology, 24(2): 129-142(in Chinese).
[20] 吴海中, 吴珍汉, 万景林, 等. 2003. 华山新生代隆升-剥蚀历史的裂变径迹热年代学分析[J]. 地质科技情报, 22(3): 27-32.
WU Hai-zhong, WU Zhen-han, WAN Jing-lin, et al.2003. Cenezoic uplift and denudation history of Huashan Mountains: Evidence from fission track thermochronology of Huashan Granite[J]. Geological Science and Technology Information, 22(3): 27-32(in Chinese).
[21] 解东宁, 何明喜, 周立发, 等. 2006. 东秦岭-大别造山带北缘逆冲推覆构造特征及油气前景[J]. 石油与天然气地质, 27(1): 48-55.
XIE Dong-ning, HE Ming-xi, ZHOU Li-fa, et al.2006. Characteristics of overthrust structures on northern edge of East Qinling-Dabie orogenic belt and hydrocarbon potentials[J]. Oil & Gas Geology, 27(1): 48-55(in Chinese).
[22] 谢石文, 黄显良, 袁勇, 等. 2019. 不同地壳速度结构对安徽地区地震定位深度的影响[J]. 地震地磁观测与研究, 40(1): 53-58.
XIE Shi-wen, HUANG Xian-liang, YUAN Yong, et al.2019. The influence research of different velocity models on seismic location depth in Anhui area[J]. Seismological and Geomagnetic Observation and Research, 40(1): 53-58(in Chinese).
[23] 徐泰然, 卢占武, 王海燕, 等. 2018. 深地震反射剖面揭示的西藏娘热矿集区上地壳结构[J]. 吉林大学学报(地球科学版), 48(2): 556-565.
XU Tai-ran, LU Zhan-wu, WANG Hai-yan, et al.2018. Upper crustal structure of Tibetan Niangre ore concentration area revealed by deep seismic reflection profile[J]. Journal of Jilin University(Earth Science Edition), 48(2): 556-565(in Chinese).
[24] 袁学诚, 李善芳, 华九如. 2008. 秦岭陆内造山带岩石圈结构[J]. 中国地质, 35(1): 1-17.
YUAN Xue-cheng, LI Shan-fang, HUA Jiu-ru.2008. Lithospheric structure of the Qinling intra continental orogen[J]. Geology in China, 35(1): 1-17(in Chinese).
[25] 袁学诚, 任纪舜, 徐明才, 等. 2002. 东秦岭邓县-南漳反射地震剖面及其构造意义[J]. 中国地质, 29(1): 14-19.
YUAN Xue-cheng, REN Ji-shun, XU Ming-cai, et al.2002. Reflection seismic profile from Dengxian to Nanzhang, eastern Qinling, and its tectonic implication[J]. Geology in China, 29(1): 14-19(in Chinese).
[26] 袁学诚, 徐明才, 唐文榜, 等. 1994. 东秦岭陆壳反射地震剖面[J]. 地球物理学报, 37(6): 749-758.
YUAN Xue-cheng, XU Ming-cai, TANG Wen-bang, et al.1994. Eastern Qinling seismic reflection profile[J]. Chinese Journal of Geophysics, 37(6): 749-758(in Chinese).
[27] 曾融生, 孙为国, 毛桐恩, 等. 1995. 中国大陆莫霍界面深度图[J]. 地震学报, 17(3): 322-327.
ZENG Rong-sheng, SUN Wei-guo, MAO Tong-en, et al.1995. Moho depth map of Chinese mainland[J]. Acta Seismologica Sinica, 17(3): 322-327(in Chinese).
[28] 张功成, 吕锡敏, 王定一. 1998. 南华北中、新生代盆地构造特征及其石油地质意义[J]. 断块油气田, 5(6): 1-9.
ZHANG Gong-cheng, LÜ Xi-min, WANG Ding-yi.1998. Structural features of basins in southern area of North China and their influence to petroleum exploration[J]. Fault-Block Oil and Gas Field, 5(6): 1-9(in Chinese).
[29] 张国伟, 孟庆任, 赖绍聪, 等. 1995. 秦岭造山带的结构构造[J]. 中国科学(B辑), 25(19): 994-1003.
ZHANG Guo-wei, MENG Qing-ren, LAI Shao-cong, et al.1995. Tectonic and structure of Qinling orogenic belt[J]. Science in China(Ser B), 25(19): 994-1003(in Chinese).
[30] 张国伟, 孟庆任, 刘少峰, 等. 1997. 华北地块南部巨型陆内俯冲带与秦岭造山带岩石圈现今三维结构[J]. 高校地质学报, 3(2): 129-143.
ZHANG Guo-wei, MENG Qing-ren, LIU Shao-feng, et al.1997. Huge intracontinental subduction zone at south margin of North China block and present 3-D lithospheric framework of the Qinling orogenic belt[J]. Geological Journal of China Universities, 3(2): 129-143(in Chinese).
[31] 张国伟, 孟庆任, 于在平, 等. 1996. 秦岭造山带的造山过程及其动力学特征[J]. 中国科学(D辑), 26(3): 193-200.
ZHANG Guo-wei, MENG Qing-ren, YU Zai-ping, et al.1996. Orogenic and dynamics of the Qinling orogen[J]. Science in China(Ser D), 26(3): 193-200(in Chinese).
[32] 张国伟, 张本仁, 袁学诚, 等. 2001. 秦岭造山带与大陆动力学 [M]. 北京: 科学出版社: 1-855.
ZHANG Guo-wei, ZHANG Ben-ren, YUAN Xue-cheng, et al.2001. Qinling Orogenic Belt and Continental Dynamics [M]. Science Press, Beijing: 1-855(in Chinese).
[33] 张梦婷, 李红, 李文厚, 等. 2018. 渭河盆地新生代沉积速率特征与主控因素分析[J]. 地质科技情报, 37(4): 74-82.
ZHANG Meng-ting, LI Hong, LI Wen-hou, et al.2018. Characteristics and main controlling factors of sedimention rate of Cenozoic in Weihe Basin[J]. Geological Science and Technology Information, 37(4): 74-82(in Chinese).
[34] 朱赖民, 张国伟, 郭波, 等. 2009. 华北地块南缘钼矿床黄铁矿流体包裹体氦、氩同位素体系及其对成矿动力学背景的示踪[J]. 科学通报, 54(12): 1725-1735.
ZHU Lai-min, ZHANG Guo-wei, GUO Bo, et al.2009. He-Ar isotopic system of fluid inclusions in pyrite from the molybdenum deposits in south margin of North China block and its trace to metallogenetic and geodynamic background[J]. Chinese Science Bulletin, 54(12): 1725-1735(in Chinese).
[35] Brown L D.1991. A new map of crustal 'terranes' in the United States from COCORP deep seismic reflection profiling[J]. Geophysical Journal of the Royal Astronomical Society, 105(1): 3-13.
[36] De Voogd B, Serpa L, Brown L, et al.1986. Death Valley bright spot: A midcrustal magma body in the southern Great Basin, Califonia[J]. Geology, 14(1): 64-67.
[37] De Voogd B, Serpa L, Brown L, et al.1988. Crustal extension and magmatic processes: COCORP profiles from Death Valley and the Rio Grande rift[J]. Geological Society of America Bulletin, 100(10): 1550-1567.
[38] Hsü K J, Wang Q C, Li J L, et al.1987. Tectonic evolution of Qinling Mountains, China[J]. Eclogae Geologicae Helvetiae, 80(3): 735-752.
[39] Meng Q R, Zhang G W.2000. Geologic framework and tectonic evolution of the Qinling orogen, central China[J]. Tectonophysics, 323(3-4): 183-196.