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已有资料显示上蔡岗断裂为隐伏逆断层,为研究上蔡岗断裂浅部构造特征,笔者跨断裂开展高分辨率浅层地震探测,获得4条高分辨率浅层地震剖面。本文根据高分辨率浅层地震剖面,并结合已有地质资料,对上蔡岗断裂浅部特征进行分析和讨论。研究结果表明:上蔡岗断裂为1条走向北北西、倾向北东东的逆断层,在岗地中部存在1条次级断层,与主断层呈反y形构造,与岗地地表形态基本一致。研究结果可为驻马店市地震危险性评价及城市规划提供地质和地球物理学依据。 相似文献
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本文利用唐山地震台1978—2016年跨断层定点形变资料探究唐山地震台所跨断层的浅层倾向和倾角。首先,对形变资料进行数字滤波处理,消除原始观测数据中的非构造信息;其次,对数据精度进行评价,得出1997—2016年滤波后的形变数据年累计残差普遍较小、精度较高;最后,采用精度较高的形变数据计算SE和NW两倾向不同倾角下基线与水准和的累计残差分布,进而获取断层的浅层倾向和倾角。结果显示,依据跨断层定点形变资料获得唐山地震台所跨断层的浅层倾向为SE,倾角为89°,该结果与前人探槽剖面中断层产状相一致,反映出本文提出的基于长期跨断层定点形变资料通过数字滤波、数据精度评价来获取断裂浅层倾向和倾角的方法具有可行性,但本文所得反演结果与唐山地震台目前采用的断层倾向NW、倾角72°存在一定偏差。 相似文献
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通过对天山北麓 190 6年玛纳斯 7 7级地震区的浅层地震探测资料、石油地震反射剖面、二维电性结构剖面、深地震反射剖面的研究 ,发现玛纳斯地震区多层次活动构造系统的根带 ,它通过脆 -韧转换带与天山活动构造块体内上地壳中的低速、高导层连为一体。低速、高导层可能是天山地壳内正在活动的韧性剪切带 ,而齐古逆断裂 -褶皱带下的脆 -韧转换带是连接深部活动韧性剪切带与地壳浅部脆性破裂的枢纽 ,也是现今孕育和发生大地震的重要构造部位。 190 6年玛纳斯地震发生在脆韧转换带的底部 ,地震区的活动逆断裂和褶皱只是部分记录了深部韧性剪切带活动的信息 相似文献
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长86km、南北向横跨乌鲁木齐坳陷的深地震反射剖面,揭示了北天山山前地壳的薄皮构造特征.共深度点叠加剖面的石河子以南部分显示了天山北缘平行山体的第一和第二排背斜构造.与双程时间分别为2.5~3.0s和5.5~6.0s的反射事件对应的滑脱构造,将地壳深部构造与地表逆断裂 褶皱构造联系在一起.玛纳斯断裂以铲形方式向下延伸,在2.5s左右深度归并于第一滑脱面,向南与清水河断裂汇合.在5.5~6.0s深度上为与玛纳斯下背斜相连的主滑脱面.它们最终汇集到准噶尔南缘断裂.石河子以北的坳陷沉积深度达12~14km.沿剖面的莫霍界面深度在准噶尔盆地为45km 左右,往南加深至50km.对该区域内的深地震测深剖面和布格重力异常资料的分析结果,与深反射剖面的地壳结构图象具有一致性.深地震反射剖面通过1906年玛纳斯7.7级地震宏观震中区,共深度点叠加剖面用于推断玛纳斯7.7级地震与北天山山前地壳构造之间的关系:玛纳斯地震属于一类褶皱地震,其发震构造是由准噶尔南缘断裂、清水河逆冲断裂、滑脱面和玛纳斯浅部断坡组成的断层系. 相似文献
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通过对盐城、泰州地区浅层地震勘探工作,对盐城、泰州地区主要NE向断裂的第四纪活动性进行了研究,获得了以下认识:盐城-南洋岸断裂、南阳断裂展布于新构造强烈坳陷区,控制了新近系及第四系沉积;主断层倾向北,在浅部同时发育反向断层构成“Y”字型断层组合,为晚更新世活动断层,地震危险性较大,具有发生6.5级左右地震的构造背景;陈家堡-小海断裂和泰州断裂与本线路相交段最新活动时代为中更新世,在浅部各由2条北倾的正断层组成,分别组成高邮凹陷和溱潼凹陷南缘的铲式断阶带,对晚第四纪地层无明显影响。综合浅层地震勘探成果及新建盐泰锡常宜铁路周边地质资料分析,在工程线路范围内未发现活动断裂存在,可不考虑活动断裂地表错动对工程线路的影响。 相似文献
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针对城市活断层浅层地震探测的一些技术问题,在兰州盆地的金城关断层和刘家堡断层沿线开展活断层浅层(50 m以内)地震勘探技术研究.主要采用纵波和横波多次覆盖共CMP点地震反射方法,获得了目标场地地震图像资料,尤其横波地震剖面更加清晰地反映出超浅层构造空间特征.以红艺村测线(HYC)和师范学校西测线(SFXX)为例,分析总结了数据采集、资料处理、剖面解释三方面浅层活断层地震探测的技术要点.结果可以为兰州市及类似复杂构造地区活断层地震调查提供技术参考. 相似文献
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浅层地震勘探资料揭示汤东断裂特征 总被引:2,自引:2,他引:0
汤东断裂是汤阴地堑的东界断裂,也是太行山山前一条重要的隐伏活动断裂。为了查明汤东断裂的产状、性质及其浅部构造特征,跨断裂开展了高分辨率浅层地震剖面探测,获得了高信噪比的浅层地震反射波叠加剖面。本文根据浅层地震剖面结果并结合研究区地质资料和已有深地震探测成果,对汤东断裂的浅部构造特征进行了分析和讨论。结果表明:汤东断裂为1条走向NNE、倾向NWW的铲型正断层,其浅部表现为由2—3条断层组成的Y字形构造,并错断了埋深约30—50m第四纪地层,断裂向下延伸至上地壳底部,属晚第四纪以来的隐伏活动断裂。汤东断裂两侧新生代沉积差异明显,断裂上升盘内黄隆起一侧,新生代沉积层较薄,其底界埋深约480m,下降盘汤阴地堑一侧,沉积了巨厚的新生代地层。研究结果为确定汤东断裂位置、评价断裂的活动性提供了基础资料。 相似文献
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大庆石油物探资料结果表明,大庆长垣西缘断裂的上盘,即东侧的北西向断裂可能存在第四纪活动断裂。为了确定大庆长垣西缘断裂的空间展布以及该区的地壳浅部地质构造特征,本项研究布设了2条跨大庆长垣西缘断裂的浅层地震探测剖面。结果表明,大庆长垣西缘断裂表现为走向北东、倾向南东的逆断层,为一条中生代晚期活动断裂。断裂的上盘,即东侧发育有一系列次级断裂,断裂的断层性质以及断层倾向多样化,两条测线东部均发育错断第四纪地层的断层,使得该区浅部地层形成地堑与地垒构造。本项研究不仅可进一步提高对大庆长垣地区浅部构造特征的认识,而且为大庆市地震危险性评价提供依据。 相似文献
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对玛纳斯大震区新近观测的大地电磁测深数据进行了处理,得到视电阻率曲线、阻抗相位曲线、二维偏离度、主轴方位角和地磁实感应矢量。然后对所有测点的资料进行了二维自动反演解释。结果表明,沿剖面的地壳浅部可划分为5个区段,沿剖面的深部可划分为3个区段,各区段的接触边界由断层或深断裂带组成。沿测线沉积盖层最大深度达12km左右;测线南段存在壳内低阻体。这些解释结果与地质及其它资料吻合较好。玛纳斯7.7级地震发生在地壳电性结构发生明显变化的接触带附近 相似文献
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Crustal structure in northern margin of Tianshan mountains and seismotectonics of the 1906 Manas earthquake 总被引:2,自引:0,他引:2
Introduction The Tianshan orogenic belt between the Tarim and Junggar basins has re-uplifted in Cenozoic due to the collision and the northwards push-compression of Asia-India plate. The special active tectonic zones have been formed along both south and north margins of the Tianshan mountains (FENG, et al, 1991). The Tianshan seismic belt is one of the major seismic belts in China. A se-ries of strong earthquakes occurred in two flanks of the Tianshan mountains in 20th century, such as … 相似文献
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Zhao Guoze Zhan Yan Tang Ji Zhao Junmeng Jin Guangwen Deng Qianhui and Wang Jijun 《中国地震研究》2000,14(1):75-85
Magnetotelluric sounding data obtalned recently in Manas earthquake area were processed. Inthe result, curves of apparent resistivity, impedance Phase, skewness and optimum rotationangle versus period and the real magnetic induction vectors were obtained. Then the data ofall measuring points were interpreted by 2D automatic inversion. The result indicates thatalong the sounding profile the shallow crust can be divided into 5 segments and the deep crustcan be divided into 3 segments, with faults or deep-seated fault zones as the contactboundaries between them. The sedimentary cover along the profile extents down to depthabout 12 km in maximum and a low-resistivity body exists in the crust in southern section ofthe profile. The interpretation results are well consistent with geological and othergeophysical data. The Manas M7. 7 earthquake occurred near a contact zone where theelectrical structure of the crust sharply changes. 相似文献
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北京时间2019年6月17日22时55分,四川省宜宾市长宁县发生了MS6.0地震(28.34°N,104.90°E),四川盆地内部及边缘地带的深部孕震环境和潜在地震危险性再次引起了国内外地震专家和学者们的密切关注.为了揭示长宁MS6.0震区的深部介质结构特征和孕震环境,综合解译地震活动的构造背景和展布特征,本文充分收集川东南宜宾长宁地震震区及其周边范围内由四川省数字测震台网、宜宾市地方测震台网以及2016年以后宜宾长宁地区新增小孔径流动地震台阵等共计35套观测地震设备2013年1月—2019年7月记录到的17305次地震的P波到时资料的数据,应用双差地震层析成像方法,反演得到了长宁震区及周边上地壳三维P波速度结构特征,并结合此次震后科考组在震区获取的三维大地电磁阵列测深和重力密集测量等最新观测资料,综合分析讨论了长宁震区速度结构特征与地震活动关系、孕震环境及其地震危险性等科学问题.研究结果表明:长宁震区及周边上地壳P波速度结构呈现出明显的横向不均匀性,震区沉积盖层的物性特征分异明显,双河场背斜褶皱北西侧的波速结构与其东部存在明显的差异性且浅层P波速度结构分布特征与地表地质构造和地层岩性密切相关.重新定位后的长宁MS6.0地震序列空间分布特征与震区上地壳介质速度结构存在密切关系,序列大体上沿着高低速异常分界线呈NW-SE向展布,并终止于白象岩—狮子滩背斜构造东段附近,长宁震区及周边介质速度结构的非均匀变化是控制主震及其序列空间展布的深部构造因素.三维P波速度结构还表明了长宁MS6.0震区双河场褶皱附近存在不一样的深浅构造背景,震区褶皱构造伴生断裂的复杂性可能破坏了盖层地层成层性,造成了介质物性界面的变化多样,从而导致深浅构造耦合存在明显的差异.长宁MS6.0地震震中位于速度结构发生变化的边界带附近,这种介质物性变化的边界带可能是中强地震孕育和发生的有利部位.长宁MS6.0地震及其序列绝大部分发生在基底滑脱带之上,由于受到区域NE-SW向主压应力和经华蓥山构造带传递而来的NW-SE向的现今应力场的共同作用,导致了此次长宁6.0级地震的发生,而随后发生的珙县MS5.1、长宁MS5.3、珙县MS5.4和MS5.6地震以及大量中小地震事件均为长宁6.0级地震触发作用所致.P波速度结构还揭示了震区双河场褶皱以及该褶皱构造地表出露伴生的大地湾断层和NW向大佛崖断层两侧浅层速度结构特征各异,结合长宁—双河背斜与轴线方向一致的NW向伴生断裂构造比较发育,而褶皱东侧的伴生断裂走向表现出多样性和复杂性,由此推断除了受区域性构造运动的影响之外,长宁震区局部构造的差异性活动也较为突出,长宁—双河背斜构造区轴部构造及其伴生的断裂具备一定的发震能力和深部孕震背景,这可能也是长宁地震余震强度较大、活动持续时间较长的主要原因,川东南地区地震活动趋势和潜在地震危险性仍值得进一步关注. 相似文献
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WU Chuan-yong LI Jin LIU Jian-ming HU Wei-hua WU Guo-dong CHANG Xiang-de YAO Yuan XIANG Zhi-yong 《地震地质》2017,39(2):342-355
The Pishan MS6.5 earthquake occurred in the west Kunlun piedmont area. According to the surface deformation data obtained by the Pishan MS6.5 earthquake emergency field investigation team, combined with the positioning accuracy of spatial distribution of aftershocks information, the focal mechanism solutions and deep oil profile data, we think the Pishan MS6.5 earthquake is a typical thrust faulting event, and the seismogenic structure is the Pishan reverse fault-anticline, which did not produced obvious surface fault zone on the surface. In the vicinity of the core of the Pishan anticline, we found some tensional ground fissures whose strikes are all basically consistent with the anticline. We propose that the surface deformation is caused by the folding and uplift of the anticline. The Pishan earthquake is a typical folding earthquake. The tectonic deformation of the west Kunlun piedmont is dominated by the thickening and shortening of the upper crust which is the typical thin-skinned nappe tectonic. The Pishan earthquake occurred in the frontal tectonic belt, the root fault of the nappe structure has not been broken, and we should pay attention to the seismic risk of the Tekilik Fault. 相似文献
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FOCAL MECHANISM SOLUTIONS AND STRESS FIELD OF THE 2019 CHANGNING,SICHUAN MAINSHOCK AND ITS MODERATE-STRONG AFTERSHOCKS(MS≥4.0) 
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下载免费PDF全文 LIANG Shan-shan XU Zhi-guo SHENG Shu-zhong ZHANG Guang-wei ZHAO-Bo ZOU Li-ye 《地震地质》1979,42(3):547-561
A MS6.0 earthquake with shallow focal depth of 16km struck Changning County, Yibin City, Sichuan Province at 22:55: 43(Beijing Time)on 17 June 2019. Although the magnitude of the earthquake is moderate, it caused heavy casualties and property losses to Changning County and its surrounding areas. In the following week, a series of aftershocks with MS≥4.0 occurred in the epicentral area successively. In order to better understand and analyze the seismotectonic structure and generation mechanism of these earthquakes, in this paper, absolute earthquake location by HYPOINVERSE 2000 method is conducted to relocate the main shock of MS6.0 in Changning using the seismic phase observation data provided by Sichuan Earthquake Administration, and focal mechanism solutions for Changning MS6.0 main shock and MS≥4.0 aftershocks are inferred using the gCAP method with the local and regional broadband station waveforms recorded by the regional seismic networks of Sichuan Province, Yunnan Province, Chongqing Municipality, and Guizhou Province. The absolute relocation results show that the epicenter of the main shock is located at 28.35°N, 104.88°E, and it occurred at an unusual shallow depth about only 6.98km, which could be one of the most significant reasons for the heavier damage in the Changning and adjoining areas. The focal plane solution of the Changning MS6.0 earthquake indicates that the main shock occurred at a thrust fault with a left-lateral strike-slip component. The full moment tensor solution provided by gCAP shows that it contains a certain percentage of non-double couple components. After the occurrence of the main shock, a series of medium and strong aftershocks with MS≥4.0 occurred continuously along the northwestern direction, the fault plane solutions for those aftershocks show mostly strike-slip and thrust fault-type. It is found that the mode of focal mechanism has an obvious characteristic of segmentation in space, which reflects the complexity of the dislocation process of the seismogenic fault. It also shows that the Changning earthquake sequences occurred in the shallow part of the upper crust. Combining with the results from the seismic sounding profile in Changning anticline, which is the main structure in the focal area, this study finds that the existence of several steep secondary faults in the core of Changning anticline is an important reason for the diversity of focal mechanism of aftershock sequences. The characteristics of regional stress field is estimated using the STRESSINVERSE method by the information of focal mechanism solutions from our study, and the results show that the Changning area is subject to a NEE oriented maximum principal stress field with a very shallow dipping and near-vertical minimum principal stress, which is not associated with the results derived from other stress indicators. Compared with the direction of the maximum principal compressive stress axis in the whole region, the direction of the stress field in the focal area rotates from the NWW direction to the NEE direction. The Changning MS6.0 earthquake locates in the area with complex geological structure, where there are a large number of small staggered fault zones with unstable geological structure. Combining with the direction of aftershocks distribution in Changning area, we infer that the Changning MS6.0 earthquake is generated by rupturing of the pre-existing fault in the Changning anticline under the action of the overall large stress field, and the seismogenic fault is a high dip-angle thrust fault with left-lateral strike-slip component, trending NW. 相似文献
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南天山及塔里木北缘构造带位于帕米尔地区东北侧,地震活动强烈。文中通过地质构造剖面、深部探测资料和地震震源机制解资料,综合研究了该区的地震构造模型。结果认为,该区的构造活动主要表现为天山地块逆冲于塔里木地块之上。天山构造系统包括迈丹断裂及其前缘推覆构造;塔里木构造系统包括深部的塔里木北缘断裂、基底共轭断层和浅部的推覆构造。塔里木北缘断裂是发育于塔里木地壳内部的高角度断裂,其形成原因在于塔里木和天山构造变形方向的差异。塔里木北缘断裂为研究区大地震的主要发震构造,天山推覆构造和塔里木基底断裂系统均具有不同性质的中强地震发震能力 相似文献
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USING DEFORMED FLUVIALTERRACES OF THE QINGYIJIANG RIVER TO STUDY THE TECTONIC ACTIVITY OF THE SOUTHERN SEGMENT OF LONGMENSHAN FAULT ZONE 下载免费PDF全文
下载免费PDF全文 On 20 April 2013, a destructive earthquake, the Lushan MS7.0 earthquake, occurred in the southern segment of the Longmenshan Fault zone, the eastern margin of the Tibetan plateau in Sichuan, China. This earthquake did not produce surface rupture zone, and its seismogenic structure is not clear. Due to the lack of Quaternary sediment in the southern segment of the Longmenshan fault zone and the fact that fault outcrops are not obvious, there is a shortage of data concerning the tectonic activity of this region. This paper takes the upper reaches of the Qingyijiang River as the research target, which runs through the Yanjing-Wulong Fault, Dachuan-Shuangshi Fault and Lushan Basin, with an attempt to improve the understanding of the tectonic activity of the southern segment of the Longmenshan fault zone and explore the seismogenic structure of Lushan earthquake.
In the paper, the important morphological features and tectonic evolution of this area were reviewed. Then, field sites were selected to provide profiles of different parts of the Qingyijiang River terraces, and the longitudinal profile of the terraces of the Qingyijiang River in the south segment of the Longmenshan fault zone was reconstructed based on geological interpretation of high-resolution remote sensing images, continuous differential GPS surveying along the terrace surfaces, geomorphic field evidence, and correlation of the fluvial terraces.
The deformed longitudinal profile reveals that the most active tectonics during the late Quaternary in the south segment of the Longmenshan Fault zone are the Yanjing-Wulong Fault and the Longmenshan range front anticline. The vertical thrust rate of the Yanjing-Wulong Fault is nearly 0.6~1.2mm/a in the late Quaternary. The tectonic activity of the Longmenshan range front anticline may be higher than the Yanjing-Wulong Fault. Combined with the relocations of aftershocks and other geophysical data about the Lushan earthquake, we found that the seismogenic structure of the Lushan earthquake is the range front blind thrust and the back thrust fault, and the pop-up structure between the two faults controls the surface deformation of the range front anticline. 相似文献