RESEARCH ON SHALLOW STRUCTURAL CHARACTERISTICS OF THE ZHUMADIAN-HUAIBIN DEPRESSION IN THE SOUTHERN MARGIN OF THE NORTH CHINA BLOCK BY USING REFLECTION SEISMIC DATA

doi:10.3969/j.issn.0253-4967.2023.06.010

Abstract

Abstract:

The Zhumadian-Huaibin depression, which is located in the southern margin of the North China block, is a NW trending faulted basin between the thrust nappe belt on the northern margin of Qinling Mountains and Xiping-Pingyu uplift and controlled by the NW trending Zhumadian-Xixian Fault and Suyahu Fault. To find out the risk base of earthquake disasters and identify the characteristics of seismotectonic in Zhumadian City, based on the analysis of deep seismic exploration results, we used high-resolution shallow seismic reflection imaging technology to complete a shallow seismic profile, about 22km long, and obtain the fine near-surface structure image and fault characteristics of Zhumadian-Huaibin depression.

As regards seismic data acquisition, we used an observation system with 3m channel spacing, 15m shot spacing, 180 recording traces and 18 folds. The seismic wave is generated by a M18-612 vibrator, with a scanning frequency band of 20-160Hz and a scanning length of 12s. The data processing adopts the common center point stacking method, with a focus on improving the signal-to-noise ratio. The processing process mainly includes the elimination of waste traces, static correction, pre-stack filtering, predictive deconvolution, velocity analysis and NMO correction, residual static correction, common center point stacking, post-stack denoising, etc. The resulting shallow seismic profile has a high signal-to-noise ratio, clearly reflecting the near-surface structural changes and fault characteristics of the Zhumadian-Huaibin depression. Similar to the characteristics of deep seismic reflection profiles, the Zhumadian-Huaibin depression on the shallow seismic profile also exhibits a fault-controlled fault basin.

The shallow seismic profile reveals multiple sets of distinct stratigraphic interface reflections, which are characterized by continuous horizontal and dense vertical layering on the profile, with typical sedimentary stratigraphic reflection characteristics. Taking the bottom interface of the Neogene and Paleogene as the boundary, there are three distinct sets of reflection characteristics in the upper, middle, and lower layers, reflecting the sedimentary differences of different tectonic periods. The lateral continuity of the reflection waves in the Neogene and Quaternary strata is good, and the overall performance is a tilted layer with high west and low east, reflecting the overall subsidence of the Southern North China region since the Neogene, and forming relatively stable Neogene and Quaternary systems; The bottom interface of the Neogene and the overlying Paleogene show obvious angular unconformity, reflecting the sedimentary discontinuity between the Neogene and Paleogene formed by the overall uplift and erosion of the Southern North China region in the late Oligocene; The lateral fluctuation of reflected waves in the Paleogene strata reflects that during the Paleogene period, the southern margin of the North China block entered a stage of fault basin development with the Southern North China region, and the the Paleogene strata was controlled by tectonic movements and fault activities; Under the Paleogene bottom interface, at both ends of the profile the reflected wave energy is weak and the continuity of the same phase axis is poor, it is speculated that it is early Paleozoic sedimentary rock and Archean dense metamorphic rock mass.

The results show that the Zhumadian-Huaibin depression was formed during the development stage of the fault basin in the Southern North China Basin in the Paleogene; The Zhumadian-Xixian Fault, which controls the western boundary of the depression, is composed of four east-dipping normal faults, manifested as a set of fault step belts that fall down layer by layer from west to east, and has not staggered the bottom interface of the Neogene, is speculated to be an active fault in the late Paleogene period; The Suyahu Fault, which controls the eastern boundary of the depression, is composed of three west-dipping normal faults, and has staggered upward to the middle-upper part of the Neogene, and is speculated to be an active fault in the middle-late Neogene period.

Suyahu Fault has a significant impact on the local changes in the near-surface strata and the trend of modern rivers and lakes, it is recommended to focus on earthquake prevention and disaster reduction work in the Zhumadian City. This study provides a geophysical basis for further understanding the near-surface structural characteristics and basin-controlling fault activity of Zhumadian-Huaibin depression, which has important scientific value and social benefits for earthquake disaster mitigation and urban planning of the Zhumadian City.

Key words: Southern margin of North China block, Zhumadian-Huaibin depression, Zhumadian-Xixian Fault, Suyahu Fault, Seismic profile

摘要：

为摸清驻马店市地震灾害风险底数、查明地震构造特征, 文中在分析深地震探测成果的基础上, 采用高分辨率浅层地震反射成像技术跨驻马店-淮滨凹陷完成了1条长约22km的浅层地震剖面, 获得了驻马店-淮滨凹陷的近地表精细结构图像和断裂特征。结果表明, 驻马店-淮滨凹陷形成于古近纪南华北盆地断陷盆地发育阶段; 控制凹陷西边界的驻马店-息县断裂由4条E倾的正断层组成, 表现为一组由西向东层层下掉的断阶带, 推测为古近纪末期活动断裂; 控制凹陷东边界的宿鸭湖断裂由3条W倾的正断层组成, 控制着现代河流的走向, 推测为新近纪中晚期活动断裂。研究结果为进一步认识驻马店-淮滨凹陷近地表构造特征和控盆断裂活动性提供了地球物理学依据, 对驻马店市的防震减灾和城市规划具有重要的科学价值和社会效益。

关键词: 华北地块南缘, 驻马店-淮滨凹陷, 驻马店-息县断裂, 宿鸭湖断裂, 地震剖面

ZHU Guo-jun, FENG Shao-ying, YUAN Hong-ke, HOU Li-hua, QIN Jing-jing, HAN Jian, WU Quan, ZUO Ying. RESEARCH ON SHALLOW STRUCTURAL CHARACTERISTICS OF THE ZHUMADIAN-HUAIBIN DEPRESSION IN THE SOUTHERN MARGIN OF THE NORTH CHINA BLOCK BY USING REFLECTION SEISMIC DATA[J]. SEISMOLOGY AND GEOLOGY, 2023, 45(6): 1419-1431.

朱国军, 酆少英, 袁洪克, 侯黎华, 秦晶晶, 韩健, 武泉, 左莹. 利用反射地震资料研究华北地块南缘驻马店-淮滨凹陷的浅部构造特征[J]. 地震地质, 2023, 45(6): 1419-1431.

Figures/Tables 6

References 20

[1]	酆少英, 刘保金, 李倩, 等. 2020. 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, 42(3): 581—594. doi: 10.3969/j.issn.0253-4967.2020.03.003.
	FENG Shao-ying, LIU Bao-jin, LI Qian, et al. 2020. The fine crustal structure of the southern margin of north China block revealed by deep seismic reflection profile[J]. Seismology and Geology, 42(3): 581—594 (in Chinese).
[2]	何正勤, 叶太兰, 丁志峰, 等. 2001. 城市活断层探测中的浅层地震勘探方法[J]. 国际地震动态, (3): 1—6.
	HE Zheng-qin, YE Tai-lan, DING Zhi-feng, et al. 2001. The application of shallow seismic prospecting methods to active fault dectection in cities[J]. Recent Developments in World Seismology, (3): 1—6 (in Chinese).
[3]	黄光寿, 黄凯, 李宏凯, 等. 2011. 河南省驻马店市地质灾害特征及防治[C]. 第六届河南省科学技术协会学术年会: 528—537.
	HUANG Guang-shou, HUANG Kai, LI Hong-kai, et al. 2011. Characteristics and prevention of geological hazards in Zhumadian City, Henan Province[C]. The 6th Academic Annual Meeting of Henan Association for Science and Technology:528—537 (in Chinese).
[4]	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 Mountain[J]. Petroleum Geology and Experiment, 29(1): 25—31 (in Chinese).
[5]	刘保金, 胡平, 陈颙, 等. 2009. 北京平原西北部地壳浅部结构和隐伏活动断裂: 由地震反射剖面揭示[J]. 地球物理学报, 52(8): 2015—2025.
	LIU Bao-jin, HU Ping, CHEN Yong, et al. 2009. The crustal shallow structures and buried active faults revealed by seismic reflection profiles in northwestern area of Beijing plain[J]. Chinese Journal of Geophysics, 52(8): 2015—2025 (in Chinese).
[6]	刘保金, 张先康, 方盛明, 等. 2002. 城市活断层探测的高分辨率浅层地震数据采集技术[J]. 地震地质, 24(4): 524—532.
	LIU Bao-jin, ZHANG Xian-kang, FANG Sheng-ming, et al. 2002. Acquisition technique of high resolution shallow seismic data for surveying of urban active faults[J]. Seismology and Geology, 24(4): 524—532 (in Chinese).
[7]	刘华平, 彭森博, 李扬. 2014. 驻马店—遂平一带地热资源赋存规律研究[J]. 华北水利水电大学学报(自然科学版), 35(6): 37—41.
	LIU Hua-ping, PENG Sen-bo, LI Yang. 2014. Research on the occurrence regularities of geothermal resources in the area of Zhumadian to Suiping[J]. Journal of North China University of Water Resources and Electric Power(Natural Science Edition), 35(6): 37—41 (in Chinese).
[8]	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). DOI URL
[9]	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 Geolgy, 25(2): 191—198 (in Chinese).
[10]	孙自明. 1998. 周口坳陷的反转构造与构造演化[J]. 石油地球物理勘探, 33(2): 251—257.
	SUN Zi-ming. 1998. Inversion structure and structural evolution in Zhoukou depression[J]. Oil Geophysical Prospecting., 33(2): 251—257 (in Chinese).
[11]	王志铄, 孙杰, 马兴全, 等. 2017. 河南省地震构造特征[M]. 北京: 地震出版社.
	WANG Zhi-shuo, SUN Jie, MA Xing-quan, et al. 2017. Seismic Tectonic Characteristics of Henan Province[M]. Seismological Press, Beijing (in Chinese).
[12]	徐汉林, 赵宗举, 杨以宁, 等. 2003. 南华北盆地构造格局及构造样式[J]. 地球学报, 24(1): 27—33.
	XU Han-lin, ZHAO Zong-ju, YANG Yi-ning, et al. 2003. Structural pattern and structural style of the Southern North China Basin[J]. Acta Geoscientia Sinica, 24(1): 27—33 (in Chinese).
[13]	徐锡伟. 2006. 活动断层、地震灾害与减灾对策问题[J]. 震灾防御技术, 1(1): 7—14.
	XU Xi-wei. 2006. Active faults, associated earthquake disaster distribution and policy for disaster reduction[J]. Technology for Earthquake Disaster Prevention, 1(1): 7—14 (in Chinese).
[14]	徐锡伟, 于贵华, 马文涛, 等. 2002. 活断层地震地表破裂“避让带”宽度确定的依据与方法[J]. 地震地质, 24(4): 470—483.
	XU Xi-wei, YU Gui-hua, MA Wen-tao, et al. 2002. Evidence and methods for determining the safety distance from the potential earthquake surface rupture on active fault[J]. Seismology and Geology, 24(4): 470—483 (in Chinese).
[15]	徐志萍, 张扬, 杨利普, 等. 2022. 河南省及邻区主要活动断裂的深部构造特征[J]. 地震地质, 44(6): 1521—1538. doi: 10.3969/j.issn.0253-4967.2022.06.010.
	XU Zhi-ping, ZHANG Yang, YANG Li-pu, et al. 2022. Study on the deep structural characteristic of main active faults in Henan Province and adjacent areas[J]. Seismology and Geology, 44(6): 1521—1538 (in Chinese).
[16]	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).
[17]	张建毅, 薄景山, 袁一凡, 等. 2012. 活动断层及其避让距离综述研究[J]. 自然灾害学报, 21(2): 9—18.
	ZHANG Jian-yi, BO Jing-shan, YUAN Yi-fan, et al. 2012. Review of research on active fault and its setback[J]. Journal of Natural Disasters, 21(2): 9—18 (in Chinese).
[18]	周称称, 杨博, 王丹. 2021. 河南省驻马店-遂平地热田地球化学特征及其指示意义[J]. 中国资源综合利用, 39(8): 69—72.
	ZHOU Cheng-cheng, YANG Bo, WANG Dan. 2021. Geochemical characteristics and indicative significance of Zhumadian-Suiping Geothermal Field in Henan Province[J]. China Resources Comprehensive Utilization, 39(8): 69—72 (in Chinese).
[19]	朱国军, 杨卓欣, 王志铄, 等. 2018. 太康 M_S4.7 地震构造初步分析[J]. 大地测量与地球动力学, 38(2): 151—156.
	ZHU Guo-jun, YANG Zhuo-xin, WANG Zhi-shuo, et al. 2018. Preliminary seismotectonic analysis of the Taikang M_S4.7 earthquake[J]. Journal of Geodesy and Geodynamics, 38(2): 151—156 (in Chinese).
[20]	朱国军, 袁洪克, 侯黎华, 等. 2020. 浅层地震资料揭示的驻马店地区上蔡岗断裂浅部构造特征[J]. 震灾防御技术, 15(1): 123—131.
	ZHU Guo-jun, YUAN Hong-ke, HOU Li-hua, et al. 2020. The shallow structural characteristics of Shangcaigang Fault in Zhumadian area revealed by shallow seismic data[J]. Technology for Earthquake Disaster Prevention, 15(1): 123—131 (in Chinese).

测线编号	探测方向	地震波激发参数
		最大出力 /kN	扫描频率 /Hz	扫描长度 /s	采样间隔 /ms	记录长度 /s	道间距 /m	炮间距 /m	偏移距 /m	接收方式	接收道数	覆盖次数
L1W	W—E	229	20~160	12	1	2	3	15	18	单边	180	18
L1E	E—W	229	20~160	12	1	2	3	15	30	单边	180	18

测线编号	探测方向	地震波激发参数
		最大出力 /kN	扫描频率 /Hz	扫描长度 /s	采样间隔 /ms	记录长度 /s	道间距 /m	炮间距 /m	偏移距 /m	接收方式	接收道数	覆盖次数
L1W	W—E	229	20~160	12	1	2	3	15	18	单边	180	18
L1E	E—W	229	20~160	12	1	2	3	15	30	单边	180	18

测线编号	断层编号	可分辨上断点位置 /m	可分辨上断点埋深 /m	T_N界面断距 /m	T_E界面断距 /m	视倾向	解释断层可靠性	归属断裂
L1W	Fp1	1082	260		6	E	较可靠	驻马店- 息县断裂
	Fp2	5218	368		64	E	可靠
	Fp3	6326	410		246	E	可靠
	Fp4	8830	408		>250	E	一般
L1E	Fp5	6000	610			W	一般	宿鸭湖断裂
	Fp6	2848	374	7	48	W	可靠
	Fp7	1517	382	12	30	W	可靠

测线编号	断层编号	可分辨上断点位置 /m	可分辨上断点埋深 /m	T_N界面断距 /m	T_E界面断距 /m	视倾向	解释断层可靠性	归属断裂
L1W	Fp1	1082	260		6	E	较可靠	驻马店- 息县断裂
	Fp2	5218	368		64	E	可靠
	Fp3	6326	410		246	E	可靠
	Fp4	8830	408		>250	E	一般
L1E	Fp5	6000	610			W	一般	宿鸭湖断裂
	Fp6	2848	374	7	48	W	可靠
	Fp7	1517	382	12	30	W	可靠