北京黄庄—高丽营断层,八宝山断层中段活动性综合研究

在黄庄－高丽营断层及八宝山断层中段布设了监测断层活动性的水淮、短边测距、重力、地磁等的共点同步观测网，分析了各观测量的时空分布及相互关系。研究认为，黄庄－高丽营断层处于应变能积累的闭锁状态；八宝山断层处于蠕动或旷动的状态；应用形变及重磁手段共点同步综合监测断层活动性，可以获得断层活动的微动态的丰富信息。     

北京八宝山断裂和黄庄—高丽营断裂构造活动性的初步分析

本文根据近期取得的一些新资料并结合前人的工作结果,分析了八宝山断裂和黄庄-高丽营断裂的构造活动性。新生代时期,黄庄-高丽营断裂是北京拗陷的主要西界断裂,八宝山断裂的活动远不及它强烈,前一条断裂活动强烈的部分随时间具有自南而北转移的特点。两条断裂第四纪均有活动,但八宝山断裂活动主要在早更新世,此后活动甚弱;黄庄一高丽营断裂中更新世仍显著活动,其北段活动持续到晚更新世甚至全新世。黄庄-高丽营断裂的活动强度,总体表现南弱北强;活动时间南部早而北部延续到很晚;活动性质,中段和南段右旋水平剪切显著,北段的垂直差异活动占优势。     

北京黄庄-高丽营断层、八宝山断层现今活动追踪研究

综合分析了控制黄庄—高丽营断层、八宝山断层活动性的形变、重力及地磁资料，认为断层的活动以永定河断层与良乡断层之间最为显著；其活动与强震的发生密切相关；断层所在地段是地震活动引起应力场变化的敏感地区。是大同及张北地震后应力转移集中的地区。转移集中的部分应力可能以断层蠕动的形式得到缓慢释放。     

塔院断层土壤气异常及其映震能力与机制初探

塔院断层土壤气异常及其映震能力与机制初探孔令昌，李秋珍（国家地震局地质研究所北京１０００２９）１概述塔院断层土壤气测点位于北京海淀区塔院，距水位观测井约３０ｍ（图１）。测点处在八宝山断裂与黄庄－高丽营断裂之间的楔形断块上，东南距黄庄－高丽营断裂仅１０     

北京黄庄断裂新活动的地质证据

黄庄断裂(亦称黄庄-高丽营断裂或衙门口-北苑断裂)是北京地堑的西部边界断裂。它南起涿县,北至怀柔以东,呈北东方向延伸,全长110余公里。由于大部分被第四系掩盖,以往主要根据物探和钻探资料确定为一条中生代形成的高倾角、大断距的活动断裂。由于无断裂新活动的资料,人们往往只注意位于其西北侧一公里左右的八宝山断裂。其实,从地层分布和构造分析看,黄庄断裂的形成应晚于八宝山断裂,由于后者     

首都圈断层活动性研究

本文分析了首都圈47处监测断层活动性的大地形变测点资料,给出了各处断层现今活动情况及速率。研究认为,首都圈现今应力场受华北区域应力场的支配,活动剧烈的断层主要有:沿河城—南口山前断层、八宝山—黄庄—高丽营断层、南口—孙河断层;1987年之后断层活动平均速率上升到0.40mm/年,应力场处于加强过程;应力集中地段在黄庄—高丽营断层北端、沿河城—南口山前断层北端,狼山断层、怀来—涿鹿北缘断层近年活动剧烈,其北端也是应力加强地区;构造运动的活跃与地震活动同步,目前构造运动继续处于活跃状态。上述应力集中地段的地震危险性应予以重视。     

北京断陷黄庄—高丽营断层伪随机可控震源地震剖面

位于北京断陷西北边界的黄庄—高丽营断层是区域新构造运动中的一条重要的隐伏断层,本研究利用伪随机可控震源及其高精度反射地震方法,调查了该断层在北京奥林匹克公园段的特征.研究工作首先从理论上分析了可控震源解码原理和抗噪声能力,然后利用三分量波动方程正演指导了黄庄—高丽营断层的野外地震观测,在城市强噪声环境下采集了高精度的地震数据,经过数据处理在该地区第一次得到地震偏移深度剖面.获得的地震偏移深度剖面清晰地显示了黄庄—高丽营断层的位置,地质解释结果为进一步明确剖面上断层两侧新生代地层的厚度提供了依据.     

依据地热井资料探讨北京八宝山断裂北段的基本特点

根据地热井的地层资料,绘制了横穿八宝山断裂带北段的地质剖面图,对八宝山断裂带的深部构造特点进行了探讨,并对几个地热钻孔的地层进行了横向对比。研究结果显示:剖面中存在众多倾角不同、规模不一且相互错断的逆断层,反映出八宝山断裂受逆冲作用非常强烈,同时具有多期性;剖面中存在两条较大的断层,一条是八宝山断裂带的主断层,另一条是雾迷山组小断块被顶托至上部后所形成的次断层,在八宝山一带,次断层的上盘被推覆至主断层线之上将其掩盖,地表仅显示一条断层,即平常所说的八宝山断层,由此可见这并非八宝山断裂带的主断层,在研究及监测中应注意加以区分。此外,根据钻孔地层厚度资料估算,本段主断层倾角约为40°,最大切割深度约为5 000 m。根据地层切割与沉积关系,认为八宝山断裂带最终形成于中生代晚期。      

北京南口-孙河断裂与黄庄-高丽营断裂交会区沉积速率差异对断裂活动性的响应

通过对北京地区南口-孙河断裂与黄庄-高丽营断裂交会处钻孔剖面开展磁性地层学研究,结合沉积物岩石组合特征以及浅部测年数据进行分析,建立了钻孔剖面的第四纪地层格架,由于地层沉积速率对控盆断裂的活动具有较好的响应,对比钻孔沉积速率的变化特征能够对目标断裂的第四纪活动性进行探讨。研究表明,南口-孙河断裂与黄庄-高丽营断裂交会处所控制的断块在第四纪时期存在明显的差异性沉降。早更新世至全新世,南口-孙河断裂活动性表现为强弱交替的特点,黄庄-高丽营断裂则表现为逐渐减弱的特点。早更新世,黄庄-高丽营断裂活动强度大于南口-孙河断裂,之后南口-孙河断裂的活动强度大于黄庄-高丽营断裂的活动强度,直至全新世,2条断裂的活动性趋于一致。     

郯庐断裂带江苏段东地堑边界断层第四纪活动性

郯庐断裂带东地堑边界断层在断裂带演化过程和现今构造格局中都是重要断层,对该边界断层的第四纪活动性研究有助于了解郯庐断裂带的演化历史和地震活动性,而有关该边界断层第四纪活动性研究较少且至今尚无定论。本文通过浅层地震勘探和钻孔联合剖面相结合的方法,针对郯庐断裂带江苏段东地堑两边界断层开展系统的断层第四纪活动性研究,结果显示,昌邑-大店断裂(F_1)第四纪以来未见构造运动证据,白芬子-浮来山断裂(F_2)在第四纪早期曾发生有关活动,晚更新世以来未见活动迹象。     

THE CENOZOIC TECTONICS AND SEISMIC ACTIVITY OF XINZHENG-TAIKANG FAULT IN THE SOUTHERN EDGE OF TAIKANG AREA

On the basis of dividing and comparison of the Neogene strata and their bottoms revealed by 7 drill holes in Taikang area, we completed 101 seismic profiles with a total length of 4991km. Seismic data were compared and interpreted. The results indicate that Xinzheng-Taikang Fault, as a blind fault extending from Xinzheng to Taikang, which was considered as an EW striking fault from Xuchang to Taikang before, is the boundary of Taikang uplift and Zhoukou depression, controlling the sedimentation since Neogene Period. So we named the fault the Xinzheng-Taikang Fault, which is composed of two branches, mainly, the east and west branches. The west branch strikes northwest, dipping northeast with steep angles, and the fault plane extending more than 140km in length. As revealed on the seismic profiles, the eastern segment of the west branch is normal fault, while the west segment of the branch shows characteristics of strike-slip fault. The east branch trends NW-NEE, dipping SW-SSE with the length of about 50km. Two branches form a minus flower structure, indicating the strike slip-extension tectonic background. The bottom of Neogene strata is offset about 120m by the east branch, 20m by the west branch, and the bottom of Quaternary is probably offset too. Meanwhile, latest studies suggest that the composite strip of the two branches of Xinzheng-Taikang Fault, which is a tectonic transfer zone, is the subduction zone between the two strike-slip faults. The tectonic stress tends to be released by the east-west branch fault, and the zone should be the seismogenic structure for the recent seismicity in Taikang area. In 2010, the latest earthquake ofM_S4.7 occurred in this area, causing 12 people wounded. The seismogenic structure was considered to be the Xinzheng-Taikang Fault. So locating the fault exactly is of great importance to disaster prevention.     

FAULT ACTIVITY OF THE SOUTHWESTERN SEGMENT OF THE EASTERN BRANCH OF XINYI-LIANJIANG FAULT ZONE IN GUANGDONG PROVINCE

The NE-trending Xinyi-Lianjiang fault zone is a tectonic belt, located in the interior of the Yunkai uplift in the west of Guangdong Province, clamping the Lianjiang synclinorium and consisting of the eastern branch and the western branch. The southwestern segment of the eastern branch of Xinyi-Lianjiang fault zone, about 34km long, extends from the north of Guanqiao, through Lianjiang, to the north of Hengshan. However, it is still unclear about whether the segment extends to Jiuzhoujiang alluvial plain or not, which is in the southwest of Hengshan. If it does, what is about its fault activity? According to ‘Catalogue of the Modern Earthquakes of China’, two moderately strong earthquakes with magnitude 6.0 and 6.5 struck the Lianjiang region in 1605 AD. So it is necessary to acquire the knowledge about the activity of the segment fault, which is probably the corresponding seismogenic structure of the two destructive earthquakes. And the study on the fault activity of the segment can boost the research on seismotectonics of moderately strong earthquakes in Southeast China. In order to obtain the understanding of the existence of the buried fault of the southwestern segment, shallow seismic exploration profiles and composite borehole sections have been conducted. The results indicate its existence. Two shallow seismic exploration profiles show that buried depth of the upper breakpoints and vertical throw of the buried fault are 60m and 4~7m(L5-1 and L5-2 segment, the Hengshan section), 85m and 5~8m(L5-3 segment), 73m and 3~5m(Tiantouzai section), respectively and all of them suggest the buried fault has offset the base of the Quaternary strata. Two composite borehole sections reveal that the depth of the upper breakpoints and vertical throws of the buried segment are about 66m and 7.5m(Hengshan section) and 75m and 5m(Tiantouzai section), respectively. The drilling geological section in Hengshan reveals that the width of the fault could be up to 27m. Chronology data of Quaternary strata in the two drilling sections, obtained by means of electron spin resonance(ESR), suggest that the latest activity age of the buried fault of the southwestern segment is from late of early Pleistocene(Tiantouzai section) to early stage of middle Pleistocene(Hengshan section). Slip rates, obtained by Hengshan section and Tiantouzai section, are 0.1mm/a and 0.013mm/a, respectively. As shown by the fault profile located in a bedrock exposed region in Shajing, there are at least two stages of fault gouge and near-horizontal striation on the fault surface, indicating that the latest activity of the southwestern segment is characterized by strike-slip movement. Chronology data suggest that the age of the gouge formed in the later stage is(348±49) ka.     

A NEW DISCOVERY OF ACTIVITY OF FUSHAN SECTION OF THE TAN-LU FAULT ZONE IN THE LATE QUATERNARY

The east branch fault of Tan-Lu fault zone extends from Fengshan Town of Sihong County on the north shore of the Huaihe River in Jiangsu Province, into Fushan Town of Mingguang City on the south shore of Huaihe River in Anhui Province. The landform changes from Subei plain on the north of Huaihe River to Zhangbaling uplift area on the south of Huaihe River. The terrain rises gradually with larger relief amplitude. The Fushan section of the Tan-Lu fault zone is located in Ziyang to Fushan area of Mingguang City. The fault is shown in the satellite image as a clear linear image, and the fault extends along the east side of a NNE-trending hillock. In this section the Quaternary strata are unevenly distributed, which causes some difficulties in the study of recent fault activity.In recent years, the author has found that the fault of the Fushan section of the Tan-Lu fault zone on the south of the Huaihe River still has a certain control effect on the landform and the Quaternary strata. Based on satellite imagery and geological data, we select the appropriate location in the Fushan section to excavate the Santang trench Tc1 and Fushannan trench Tc2, and clean up the Fushannan profile Pm, which reveals rich phenomena of recent fault activity. Santang trench reveals three faults, and the faulting phenomenon is obvious. One of the faults shows the characteristic of right-lateral strike-slip normal faulting; Fushannan profile reveals one fault, with the same faulting behavior of right-lateral strike-slip normal fault. Comprehensive stratigraphic sample dating results indicate that the fault dislocated the middle Pleistocene strata, late Quaternary strata and early Holocene strata. All our work shows that the fault of Fushan section has intensive activity since late Pleistocene, and the latest active age can reach early Holocene. The latest earthquake occurred at(10.6±0.8)~(7.6±0.5)ka BP. The faults exposed by trenches and profiles show the characteristics of right-lateral strike-slip normal faulting, which reflects the complexity of the tectonic stress field in the area where the fault locates.     

ACTIVE CHARACTERISTICS OF THE SANWEISHAN FAULT IN THE NORTHERN MARGIN OF THE TIBETAN PLATEAU DURING LATE PLEISTOCENE

The Sanweishan fault is located in the northern margin of the Tibetan plateau. It is a branch of the Altyn Tagh fault zone which extends to the northwest. A detailed study on Late Quaternary activity characteristics of the Sanwei Shan Fault can help understanding the strain distribution of the Altyn Tagh fault zone and regional seismic activity and northward growth of the Tibetan plateau. Previous research on this fault is insufficient and its activity is a controversial issue. Based on satellite images interpretation, field investigations and geological mapping, this study attempts to characterize this feature, especially its activity during Late Quaternary. Trench excavation and sample dating permit to address this issue, including determination of paleoseismic events along this fault. The results show that the Sanweishan fault is a large-scale active structure. It starts from the Shuangta reservoir in the east, extending southward by Shigongkouzi, Lucaogou, and Shugouzi, terminates south of Xishuigou, with a length of 175km. The fault trends in NEE, dipping SE at angles 50°~70°. It is characterized by left-lateral strike-slip with a component of thrust and local normal faulting. According to the geometry, the fault can be divided into three segments, i.e. Shuangta-Shigongkouzi, Shigongkouzi-Shugouzi and Shugouzi-Xishuigou from east to west, looking like a left-or right-step pattern. Plenty of offset fault landforms appear along the Sanweishan Fault, including ridges, left-lateral strike-slip gullies, fault scarps, and fault grooves. The trench study at the middle and eastern segments of the fault shows its activity during Late Pleistocene, evidenced by displaced strata of this epoch. Identification marks of the paleoearthquakes and sample dating reveal one paleoearthquake that occurred at(40.3±5.2)~(42.1±3.9) ka.     

乌鲁木齐地区N倾断层系的构造特征

乌鲁木齐地区发育有5条N倾的断层,这些断层晚更新世以来均有较为明显的活动迹象,并在地表形成了较为显著的构造标志。通过沿断层大比例尺地质地貌填图、探槽开挖和年代测定,较为准确地获得了断层的最新活动时代、运动性质和特征等问题,并确定出这些断层都是在距今20万年~30万年以来快速翘升形成的。结合深地震反射资料,对乌鲁木齐地区的深部结构进行了分析讨论,从而对N倾断层系的深部构造特征也有了更加清晰的认识,为准确评价这些断层的孕震模式和发震能力提供了可靠的依据。     

1830年河北磁县强震区活动构造初步研究

根据航片判读及野外调查，提出河北磁县存在北西西向全新世隆起，该性起北缘的北西西向南山村断裂带是本区的活动断裂。断裂活动为正倾滑。活动依据有错断山体的基岩陡崖，河床中晚全新世地层的陡坡沉积及沿断裂带展布的线性黄土，碎石楔。该断裂带被认为是１８３０年磁县地震的地震断层。     

华北地壳应力场的基本特征

地壳应力场的研究是地震学中的一个基本课题。本文根据对四个方面资料的分析得到了华北地区（φ30°-41°N,λ105°-124°E）地壳应力场的基本特征。这些资料是:1.地震机制,包括1937年至1979年地震的断层面解和最近十多年中的小地震综合断层面解;2.地震时的地面裂缝;3.公元143年至1976年41次M≥6地震的等震线的长轴方位;4.某些大地震地区的大地测量结果。这是一个一致性相当好的应力场,其最大压应力轴为北东东向,最小压应力轴为北北西向,并且都近于水平向。 从一些大地震的观测事实来看,具有这种一致性应力场的范围要比华北地区大,在远离华北的地方,仍表现出同华北以内相似的地壳应力场。这个事实表明,上述地壳应力场的来源,不限于华北地壳内部,而同更大规模的构造运动有关。欧亚板块、印度洋板块同太平洋板块三者之间的相互作用,以及华北所处远离板块边缘的特殊位置,可能是造成该应力场特征的主要原因。     

河北省怀安盆地北缘断裂活动性研究

本文以野外地质调查为主，讨论了怀安盆地北缘断裂的几何展布和活动特征，并进行了断裂的活动性分段，对断裂的运动学特片也进行了探讨，研究认为，该断裂是一条第四纪活动断裂，以东段活动性最强，Ｑ３＾２以来平均垂滑动速率达０．２１－０．２２ｍｍ／ａ；中段活动次之，西段活动较弱，整个断裂活动年代有自西南向东北迁移的趋势。最后，文章对１６２６年２５／４级地震的震中位置作了讨论。     

关于郯庐断裂和东北南部主要断裂的关系

利用东北地区航磁资料的新近编图和数据处理结果,结合重力和地质资料,本文探讨了郯庐断裂带的北延和依兰-伊通等东北南部主要断裂的关系。在晚太古代至早元古代郯庐断裂形成时,它向北延伸过渤海就止于鞍山,为另一东西向断裂所截。郯庐断裂由于后期的活动才使它越过东西向断裂继续向北伸展,形成了依兰-伊通断裂。依兰-伊通断裂切割地壳的深度和对两侧基底的控制作用都不如郯庐断裂中段强烈     

STUDY ON THE LATEST ACTIVITY OF WUYUNSHAN-HEFEI FAULT IN HEFEI BASIN,THE WESTERN BRANCH OF THE TANLU FAULT ZONE

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.