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地震勘探资料揭示郑州老鸦陈断层特征 总被引:2,自引:1,他引:1
断层活动性的探测研究是城市地震预测和防震减灾的基础性工作。为了查明郑州老鸦陈断层的位置、性质及其活动性,2006年底,在郑州市北郊横跨老鸦陈断层进行了不同探测深度的浅层地震勘探,通过采用爆破震源和可控震源相结合、不同观测系统参数相结合的工作方法,获得了探测深度30—6000m范围内的地下结构与构造图像。结果表明,老鸦陈断层为一条倾向NE、走向NW的正断层,该断层错断了新第三纪(N)以前的地层,在Q N地层内部没有发现断层引起的地层错断现象。 相似文献
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通过浅层地震勘探、钻孔联合剖面分析、野外地貌调查以及新地质年代测定等技术方法,对原先认定的郑州老鸦陈断裂的活动性开展调查. 其中,浅层地震勘探结果表明,该断裂仅存在于新近纪以前的地层,而在新近纪地层内均未发现该断层错断和活动迹象. 同时,地表的地质地貌调查亦发现ldquo;地貌陡坎rdquo;与老鸦陈断裂的位置不一致. 另外钻探和钻孔联合剖面的分析也表明,地表的陡坎仅发育在马兰黄土中, 其下地层平缓,没有错断现象,认为该陡坎的形成与老鸦陈断层没有关系,但可能与黄河改道变迁的侵蚀作用有关. 因此,老鸦陈断裂不属于活动断裂. 相似文献
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浅层人工地震P波和S波资料揭示的郑州老鸦陈断层特征 总被引:1,自引:1,他引:0
断层活动性的探测研究是城市防震减灾的基础性工作。为了查明郑州老鸦陈断层的位置、性质及其活动性,2006年底跨老鸦陈断层进行了高分辨率的浅层地震P波和S波探测,通过采用不同的地震波激发源、不同的观测系统参数相结合的工作方法,获得了沿剖面不同深度的地下细结构图像,揭示了老鸦陈断层的形态和特征。结果表明,老鸦陈断层为一条倾向NE、走向NW的正断层,该断层错断了新近系(N)以前的地层,在Q+N地层内部没有发现断层引起的地层错断现象 相似文献
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乌兰巴托以西断裂活动时代的光释光年代学研究 总被引:1,自引:0,他引:1
蒙古乌兰巴托周边发育了多条活动断裂.以乌兰巴托以西的Emeeh和Hustai断裂为例,对相关断层开挖探槽,进行年代学研究.结果表明,Emeeh断裂以走滑运动为主,根据剖面错断地层和其上覆、下伏地层的光释光年代学研究结果,推断出该断层最新活动时间介于距今(9.6±1.0)ka和(11.3±1.3)ka之间;对Hustai断裂开挖的新鲜剖面显示其为正断层,通过分析错断地层和其上覆堆积物的光释光定年结果,推断该断裂最新活动时间介于距今(0.87±0.08) ka和(24.2±4.9) ka之间,且可能更接近距今(0.87±0.08)ka. 相似文献
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在前人对福州盆地及其周缘活动断裂 1/ 1万填图研究的基础上 ,通过室内航卫片判读、野外详细调查等方法 ,经过详细论证 ,在福州盆地及周缘 6条活动断裂上选择了 11个认为可能是断层通过的位置 ,进行了探槽开挖。大部分探槽只揭露到了基岩中的断层 ,有些探槽在开挖深度内既没有揭露到基岩 ,在第四系中也没有揭露到断层。对于没有揭露到断层的探槽 ,认为断层没有错断开挖深度内的第四纪地层 ,以探槽最底部的地层年代作为断层最新活动时代的上限。有些探槽揭露到了基岩中的断层 ,这些断层向上没有错断第四系 ,就以上覆第四系底部的时代作为断层最新活动时代的上限。只有在沿桐口 -洪山桥断裂开挖的探槽中 ,揭露出 2条断层 ,它们向上都错断了相同层位的第四纪地层 ,并被更新的第四系所覆盖。根据测年结果 ,这些断裂不是全新世活动断裂 ,其中 ,闽侯 -南屿断裂可能为晚更新世活动断裂 ,其它断裂晚更新世以来都已不活动 相似文献
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地质和地球物理资料表明 ,沧东断裂为发育于上地壳的上陡下缓的铲状断裂 ,断面于 10km深处的上地壳底部变为近水平的拆离滑脱面。沧东断裂经历了中、新生代两个裂陷旋回 ,开始形成于晚侏罗世 ,此时为正断裂性质 ,早白垩世末期的燕山运动使断裂反转为逆断裂 ,并有一定的左旋走滑 ,形成正花状构造。早第三纪始新世时在中生代断裂的基础上改造成为正断裂 ,控制了黄骅坳陷下第三系的分布。早第三纪为断裂主要活动时期 ,塑造了现今沧东断裂的主要形态 ,断裂不同区段的产状、发育历史和活动强度表现出鲜明的分段性。晚第三纪以来断裂活动微弱。从浅层地震勘探结果看 ,沧东断裂晚更新世以来基本不活动 ,不是活动断裂 相似文献
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临潼-长安断裂带晚第四纪以来的活动性 总被引:1,自引:0,他引:1
对临潼-长安断裂带进行了详细的野外调查,以期掌握其最新活动年代和第四纪以来的活动特征。该断裂总体走向NE,以张性垂直运动为主,断面明显错断了黄土中的第1层古土壤S1,说明其晚更新世以来仍在活动,并且北段和中段的活动性比南段强,但是错距大多<2m,滑动速率较小,考虑到临潼-长安断裂带由多条次级断层组成,其整体活动性应该比我们计算得到的局部断层滑动速率大得多。断层错距自上而下成递增趋势,并且根据不同地层年代计算出的滑动速率基本一致,因此该断裂带自中更新世晚期以来极可能以垂向蠕滑活动为主 相似文献
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对位于安徽南部的头坡断裂的野外调查表明,沿头坡断裂没有明显的水平或垂向错动的地貌现象;在取得的剖面中,上覆第四纪地层均未被断裂断错,表明断裂在中、晚更新世以来没有活动。对本区地貌、第四纪地层和断裂活动历史的调查分析表明,该断裂在燕山运动晚期(侏罗纪末—早白垩世)和喜马拉雅运动早期(晚白垩世—古近纪)有过2次强烈活动,前者表现为左旋走滑运动,后者以拉张活动为特征。新近纪以来全区处于长期隆升剥蚀状态,缺失新近系,第四系厚度不大,残坡积地层广泛发育,构造运动微弱。头坡断裂的活动历史及新活动性与其相邻的郯庐断裂带南段相似,前者可能受后者的控制 相似文献
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作者通过对区域地质调查资料的分析研究和实地考察,对金沙江断裂带的展布范围进行了划分,认为金沙江断裂带是川西规模巨大的断裂带,从地震活动、断裂地貌特征、水系扭曲、第四纪地层形变和温泉沿断裂分布等表明它是一个活动断裂带。通过对历史地震实地访问调查,获得了1923年巴塘6.5级地震的震害情况,并发现了这次地震在地表所产生的地裂缝,从而确定了这次地震的宏观震中位置,探讨了地震与断裂的关系。无疑对金沙江断裂带活动性的认识、地震预报和地震烈度区划工作具有现实意义。 相似文献
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STUDY ON THE LATEST ACTIVITY OF WUYUNSHAN-HEFEI FAULT IN HEFEI BASIN,THE WESTERN BRANCH OF THE TANLU FAULT ZONE 下载免费PDF全文
ZHENG Ying-ping YANG Xiao-ping SHU Peng LU Shuo FANG Liang-hao SHI Jin-hu HUANG Xiong-nan LIU Chun-ru 《地震地质》1979,42(1):50-64
Tanlu fault zone is the largest strike-slip fault system in eastern China. Since it was discovered by aeromagnetics in 1960s, it has been widely concerned by scholars at home and abroad, and a lot of research has been done on its formation and evolution. At the same time, the Tanlu fault zone is also the main seismic structural zone in China, with an obvious characteristic of segmentation of seismicity. Major earthquakes are mostly concentrated in the Bohai section and Weifang-Jiashan section. For example, the largest earthquake occurring in the Bohai section is M7.4 earthquake, and the largest earthquake occurring in the Weifang-Jiashan section is M8.5 earthquake. Therefore, the research on the active structure of the Tanlu fault zone is mainly concentrated in these two sections. With the deepening of research, some scholars carried out a lot of research on the middle section of Tanlu fault zone, which is distributed in Shandong and northern Jiangsu Province, including five nearly parallel fault systems, i.e. Changyi-Dadian Fault(F1), Baifenzi-Fulaishan Fault(F2), Yishui-Tangtou Fault(F3), Tangwu-Gegou Fault(F4) and Anqiu-Juxian Fault(F5). They find that the faults F3 and F5 are still active since the late Quaternary. In recent years, we have got a further understanding of the geometric distribution, active age and active nature of Fault F5, and found that it is still active in Holocene. At the same time, the latest research on the extension of F5 into Anhui suggests that there is a late Pleistocene-Holocene fault existing near the Huaihe River in Anhui Province.
The Tanlu fault zone extends into Anhui Province and the extension section is completely buried, especially in the Hefei Basin south of Dingyuan. At present, there is little research on the activity of this fault segment, and it is very difficult to study its geometric structure and active nature, and even whether the fault exists has not been clear. Precisely determining the distribution, active properties and the latest active time of the hidden faults under urban areas is of great significance not only for studying the rupture behavior and segmentation characteristics of the southern section of the Tanlu fault zone, but also for providing important basis for urban seismic fortification. By using the method of shallow seismic prospecting and the combined drilling geological section, this paper carries out a detailed exploration and research on the Wuyunshan-Hefei Fault, the west branch fault of Tanlu fault zone buried in Hefei Basin. Four shallow seismic prospecting lines and two rows of joint borehole profiles are laid across the fault in Hefei urban area from north to south. Using 14C, OSL and ESR dating methods, ages of 34 samples of borehole stratigraphic profiles are obtained. The results show that the youngest stratum dislocated by the Wuyunshan-Hefei Fault is the Mesopleistocene blue-gray clay layer, and its activity is characterized by reverse faulting, with a maximum vertical offset of 2.4m. The latest active age is late Mesopleistocene, and the depth of the shallowest upper breaking point is 17m. This study confirms that the west branch of Tanlu fault zone cuts through Hefei Basin and is still active since Quaternary. Its latest activity age in Hefei Basin is late of Middle Pleistocene, and the latest activity is characterized by thrusting. The research results enrich the understanding of the overall activity of Tanlu fault zone in the buried section of Hefei Basin and provide reliable basic data for earthquake monitoring, prediction and earthquake damage prevention in Anhui Province. 相似文献
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中国不少城市位于较厚的第四纪松散沉积物覆盖区,在这些松散层内,发育了许多具有相当规模的隐伏断裂,用地震方法能够探测到它们的存在。但用地震方法探测到的这些隐伏断裂的上断点是否代表了真正意义的断裂上断点?文中在讨论地震记录分辨率的基础上,探讨了影响地震勘探效果的记录信噪比、地质构造条件以及资料处理和解释方法:为提高地震记录的信噪比和分辨率,需要采取相应的技术措施,如在数据采集过程中,使敷设的地震剖面垂直断裂走向,在保证地震记录具有较高信噪比的条件下,采用合适的覆盖次数和小道间距接收的工作方法有助于获取更浅波阻抗界面的反射波;在数据处理和解释的过程中,准确求取反射波的速度,采用一些提高地震记录分辨率和信噪比的处理技术,摒弃一些混波处理手段,有助于改善利用地震方法探测隐伏断裂上断点的效果。而对于没有波阻抗差异的地层界面,包括隐伏断裂已经错断的那些地层界面,地震方法则难以对其进行探测。即使地震方法探测到的不一定是真正意义上的隐伏断层上断点,其结果依然可为今后钻孔剖面位置的布设、钻孔深度的设计以及断层活动性的判定提供科学依据。 相似文献
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The neotectonics in Zhanjiang Bay area is almost the inferred faults and there are not any active faults seen on the ground surface. So it is difficult for research on the seismogenic structure. This paper analyzes and interpretes the gravity data that can reflect the feature of deep faults and then discusses the seismogenic structure of Zhanjiang Bay area in combination with its geology and earthquake activity. There is a huge NEE-trending high gravity gradient belt lying in the coastal region among Guangdong, Guangxi, and Hainan, and Zhanjiang Bay is located in this gravity gradient belt. We analyzed and interpreted more than eighty images obtained with many different methods one by one, then, got the result that Zhanjiang Bay area is embraced by two giant fault belts trending in the NEE and NW direction respectively, and its interior is crossed over by the NE-trending fault belt. These three fault belts are well shown in the gravity images, especially the NEE-trending fault belt and NW one. The gravity isolines and gradient belts or the thick black stripes of the NEE-and NW-trending fault belts are displayed apparently. Also, these gravity structures are good in continuity, extend vastly and cut deeply. What is more, the NEE-trending fault belt plays a leading and region-controlling part. It shows good continuity, and cuts off the NW-and NE-trending faults frequently and intensively. The NW-trending fault belt also is good in continuity and cuts the NEE-and NE-trending faults relatively frequently and strongly, but it is restricted by the NEE-trending one. Last, the continuity of the NE-trending fault is worse and the strength cutting off NE-and NW-trending faults is significantly weak, just in some segments and in the shallow positions. According to the characteristics above and combined with the analyses of geological structure and earthquake activity, the conclusion can be drawn that the NEE-trending fault is the controlling structure and the main seismogenic structure in Zhanjiang Bay area, and the NW-trending fault is the second one. They conjugate and act together. Therefore, Zhanjiang Bay has the tectonic condition for generating MS=6.5 earthquakes. 相似文献