深地震反射剖面揭示的华北地块南缘地壳的精细结构

doi:10.3969/j.issn.0253-4967.2020.03.003

摘要/Abstract

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

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

中图分类号:

P315.2

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.

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.

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