高密度电法在乌鲁木齐西山断裂探测中的应用

西山断裂是乌鲁木齐河以西一条颇具规模的断裂构造,控制着西山岭南麓,断裂从永光煤矿到红光山南长约37 km。断裂形成于中更新世期间,但整条断裂的形成过程可能并非同步,具有西老东新的特点,最新活动时代为晚更新世中晚期,为逆冲运动性质,断面北倾。该断裂在四道岔附近主断层及发育的一部分次级断层被第四系覆盖,研究该隐伏段对于以后城市土层合理利用和断层基本特征判断具有一定意义。目前高密度电法是探测隐伏断层的一种重要的物探方法,通过高密度电法对乌鲁木齐西山断裂隐伏段的探测,确定该断层隐伏段的位置及地层构造形态,为西山断裂深入研究提供一定依据。     

延怀盆地隐伏断裂第四纪活动性研究

依据盆地第四系沉积特点,结合高密度、CSAMT(可控源音频大地电磁)、浅层地震及钻孔磁化率探测结果,剖析隐伏断裂在盆地的几何形态特征及活动性。结果表明:延矾盆地北缘断裂南段(隐伏端)沿窑湾村-桑园南堡村展布,由2条SE倾的阶梯状正断层组成,切割第四系上更新统泥河湾组地层,上断点埋深40m,断距约35m;断裂在早-中更新世有过活动,晚更新世断裂活动性较强,全新世以后断裂活动性具逐渐减弱趋势;施庄断裂北隐伏段经施庄向SE145°方向展布,切割第四系泥河湾组地层,上断点埋深70m,断裂早-中更新世有过活动,晚更新世断裂活动性较强。综合分析认为,延怀盆地隐伏断裂在晚更新世时期活动性强,而全新世以来,各断裂活动性减弱。     

天津汉沽断裂准确位置及活动性的综合探测研究

天津汉沽隐伏断裂属于滨海平原区隐伏断裂。本文采用化探、浅层地震勘探和联合钻孔剖面探测等方法,并结合年代样品测试对汉沽断裂进行了综合探测研究,首次查明了汉沽断裂的准确空间位置和晚第四纪活动性。探测结果表明,汉沽隐伏断裂最新上断点埋深25. 8m,断距为2. 15m。结合光释光年代样品测试结果,推断其最新活动时代为49. 3ka ～ 65kaBP,属晚更新世中期活动断裂。由于该断层是与主断层倾向相反的次级断层,可能并不是震源断层错动在地表的直接反映,同时汉沽断裂晚更新世早期以来的平均滑动速率为0. 063mm / a,明显低于海河断裂东段晚更新世以来0. 141mm / a 的平均滑动速率,这都表明汉沽隐伏断裂的活动强度并不是很大,应是一具有中等活动强度的活动断裂。     

口泉断裂郊城段断裂展布特征及其活动性研究

通过地质调查、联合钻孔勘察、断层露头剖面实测、光释光年龄测试等综合手段,对口泉断裂郊城段准确位置、断裂展布特征和活动性进行详细研究。结果表明,断裂在该地段由2条断裂组成,呈平行阶梯状,间距30 m,山区侧断裂断距1.4 m,盆地侧断裂断距1.9 m,两断裂断至地表属全新世活动断裂,为同期黏滑所致。晚更新世晚期(20.3~27.8 ka)地层平均沉积速率约为0.17 mm/a。沿断裂无明显的地貌陡坎,基岩山体剥蚀后退400~600 m。研究得出的断裂准确位置、展布特征及活动性结果,对口泉断裂形成历史、盆地的形成演化及对沿线工程规划和灾害评估有较大的参考意义。     

北京东北旺-小汤山断裂存在的证据

对位于北京市西北侧的东北旺-小汤山断裂是否存在、走向与活动性的认识长期以来一直存在较大差异。通过新近开展的北京城市活断层探测工作中的物探数据与钻孔联合剖面分析,认为东北旺-小汤山断裂是存在的,为一条隐伏断裂,长约40km,走向NNE,倾向SE。以南口-孙河断裂为界,该断裂东北段称之为小汤山断裂,西南段称之为东北旺断裂。小汤山断裂的最新活动时代为早更新世或中更新世早期,中更新世中期以来不活动。东北旺断裂的最新活动时代为中更新世末期,晚更新世以来不活动     

维西—乔后断裂南段正断层活动特征

根据野外调查结果,重点阐述了维西—乔后断裂南段的活动特征。研究表明,维西—乔后断裂南段在第四纪表现出明显的活动特征,运动性质以正断层作用为主。维西—乔后断裂南段对巍山第四纪盆地有着明显的控制作用,因受其影响盆地内阶地不对称发育。箐门口、佛堂村、洗澡塘探槽揭示该断裂断错了晚更新世堆积,被错最新地层14C年龄(15 430±60)a B.P.,OSL年龄为(11.6±1.6)ka,表明其最新活动时代在晚更新世末期。洗澡塘村断层地貌清晰,西河Ⅱ级阶地上发育高2 m左右的断层陡坎。根据阶地断层陡坎高度和阶地面形成年龄估算,晚更新世以来该断裂段垂直滑动速率约为0.18~0.32 mm/a。     

临漳-大名断裂活动特征

临漳-大名断裂位于覆盖层较厚的平原地区,处于隐伏状态,为获得断裂的浅部构造特征以及活动特征,在断裂上采用高分辨浅层地震探测方法,获得了两条高质量叠加时间剖面图以及深度剖面图,这些图像清晰地显示了断裂的浅部构造以及活动特征。探测结果表明,临漳-大名断裂活动时代具有分段性,临漳段断裂上断点埋深120m,最新活动时代为中更新世早期;大名段断裂上断点埋深105m,最新活动时代为晚更新世中期。     

河西务断裂活动性的综合探测研究

河西务断裂为河西务构造带的东缘断裂,总体走向北东,倾向南东,向北延伸与廊固凹陷内的横向断层（桐柏断裂）小角度相接,向南延伸与牛东断裂相接,为廊固凹陷与武清凹陷的分界断裂,隐伏于冀中凹陷覆盖层之下。本文通过浅层地震勘探和钻孔联合剖面探测,结合年代样品测试,对河西务断裂的活动性和滑动速率进行了综合研究,揭示断裂上断点埋深约150m或以浅,第四系底界面的垂直错距为20—45m,断裂的最新活动时代为晚更新世早期,晚更新世以来的平均垂直滑动速率为0.03mm/a,中更新世晚期以来的平均垂直滑动速率为0.11mm/a。     

渭河断裂杨家村—窑店段展布及晚第四纪活动特征

渭河断裂杨家村—窑店段西起杨家村,经魏家泉、金家庄、东耳村、陈家台,到达窑店,走向NE,倾向S,长约33km,为同生正断层,沿渭河北岸I级、Ⅱ级、Ⅲ级阶地前、后缘展布。遥感解译、浅层地震探测、探槽、钻孔联合剖面结果表明,渭河断裂杨家村—窑店段在咸阳附近的渭河北岸阶地表现为断层陡坎,与NE向阶地坎重合;断裂在晚更新世晚期至全新世可能仍有活动。渭河断裂杨家村—窑店段自(46.0±3.3)ka以来断距较大,在11.0~16.5m之间;垂直滑动速率在0.34~0.45mm/a之间;断裂最新活动时间约为2.0ka BP。金家庄左阶斜裂区将渭河断裂杨家村—窑店段划分为杨家村—金家庄段和东耳村—窑店段。     

太原盆地田庄断裂东段探测和活动性初步研究

田庄断裂为太原盆地内一条较大的隐伏断裂,采用地质调查、浅层地震勘探等方法对该断裂东段(西温庄—滨河东路)开展研究。地质调查结果显示:田庄断裂对太原断陷盆地的地貌形态有明显的控制作用,并且控制着太原盆地的沉降;浅层地震勘探结果揭示:该断裂空间位置比原来认定的位置向北偏移了约250~600 m,并且在其上盘发育有与主断裂倾向相反的次级断裂。结合TZ2测线北侧附近"太原市活断层探测与地震危险性分析"项目中小店区钻孔联合剖面地层测年资料,认为该断裂错断了上更新统下部地层,并且上断点埋深有向浅部延展的趋势,初步认为田庄断裂的最新活动时代为晚更新世。     

银川市活断层探测进展概述

本文介绍了对银川市城区两条隐伏断层所做的多层次、多手段综合探测,包括在同一个试验场点进行的三个层次的浅层人工地震勘探、钻孔联合剖面探测和槽探,从深到浅,逐层捕获隐伏目标,直到明确锁定目标断层在试验场点的准确位置、产状和上断点埋深等情况。通过对银川市活断层探测中目标断层的追踪探测,查明了市区银川隐伏断层和芦花台隐伏断层的平面展布,特别是在市区的延伸位置。通过岩芯样品的绝对年龄测定,得到了银川隐伏断层北段晚全新世活动,南段晚更新世活动,芦花台断层晚更新世以来不活动的结论。     

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.     

基于钻探的芦花台隐伏断层晚第四纪活动特征

The Luhuatai fault is one of the important buried tectonics in the Yinchuan basin. Based on the results of shallow seismic exploration, we conducted composite drilling section exploration and dating of the samples from boreholes. Some useful data was obtained, such as the depth of the upper breaking point, the latest activity age, displacement in the late Quaternary, and slip rates, etc. This study shows that the activity is different between the north and south segment along the Luhuatai fault. The north segment is a Holocene fault, while the south segment is a late mid-Pleistocene fault. From north to south along the north segment of Luhuatai fault, the activity has been enhanced, and the faulting is stronger in late Pleistocene than Holocene.     

滨北地区埕南断层晚更新世活动证据及其地震危险性意义

埕南断层是埕宁隆起与济阳凹陷的边界断层,也是滨北地区1条规模最大的重要断层,采用浅层地震勘探和钻孔联合剖面探测相结合的方法,确定了埕南断层准确位置,探明了断层的产状,揭露了上断点深度。钻探结果显示,埕南断层为正断特征,倾向南或南东,倾角70°～80°,断层上断点埋深44.3～46.4 m,断距1.0～1.3 m。通过年代学测试确定了错断地层的年代,获得埕南断层错断晚更新世地层的证据,埕南断层晚更新世活动证据的发现对滨北地区地震危险性再认识具有重要意义和价值。     

滇池盆地东缘白邑-横冲断裂南段的浅层地震勘探研究

本文用浅层地震反射波法对可能穿越昆明新城区东部第四系覆盖区的白邑-横冲断裂南段进行了探测,结果表明:采用浅层地震反射波法探测隐伏断层是有效的,在滇池盆地东缘,白邑-横冲断裂南段东支在隐伏区存在,断面接近直立,视倾角约80°,具有高倾角张性正断性质,基岩垂直错距为10—13m,断裂规模由北向南减小;同时,没有发现西支次级断层存在迹象。据土层测龄结果,东支断裂最新活动时代为第四纪中更新世晚期。     

纵横波联合勘探应用于栟茶河断裂活动性的调查与研究

栟茶河断裂自20世纪50年代石油部门勘探发现以来,由于缺乏确凿的证据,地学家们对其活动性一直存在争议。目标断裂所在测区基岩顶面埋深约在800~1 600m,单一的地震勘探方法难以深浅兼顾且单波勘探经常存在局限性。为了调查栟茶河断裂的空间位置、产状及性质,重新厘定其活动性,在同一条测线上同时进行高分辨率的浅层地震P波和SH波勘探,通过采用不同的地震波激发震源和观测系统参数,获得沿测线不同埋藏深度的地下细结构图像,揭示栟茶河断裂的形态和特征,尤其SH波地震剖面更加清晰地反映出超浅层地层和构造空间特征。结果表明,测线控制范围内的栟茶河断裂为近东西走向、视倾角约为60~75°、倾向N的正断层,该断层错断了新近纪和早第四纪地层,有可能断错了晚更新世地层。本文的纵、横波联合勘探实例证实了多波勘探的优越性。     

唐山地震发震构造的浅层地震探测

利用浅层地震探测方法,研究了唐山地震区１年前出现在卫星图像上的异常现象与发震构造的关系,探讨地震中长期预测的途径。结果表明：唐山地震断层是一条倾向ＮＷ的右旋走滑第四纪同生断裂,它错断了全新统,晚更新统,中更新统,和早更新统地层。     

第四纪沉积区断层及其上断点探测的地震方法技术——以银川隐伏活动断层为例

地震勘探方法是隐伏断层探测的一种有效的地球物理探测手段,而地震勘探的探测参数是影响探测效果和断层定位精度的主要因素.本文以银川市活断层探测的浅层地震勘探资料为例,并结合石油地震勘探剖面结果和钻孔地质资料,阐述了在第四纪覆盖层较厚的地区,由深至浅追踪目标断层形态和确定断层上断点空间位置的方法技术.结果表明,采用高分辨率地震勘探和钻孔地质剖面相结合的探测方法是确定隐伏断层位置、判定断层活动性的有效方法.     

RESEARCH ON THE CHARACTERISTICS OF QUATERNARY ACTIVITIES OF SU-XI-CHANG FAULT

Running across the urban areas of Changzhou, Wuxi and Suzhou, the NW-trending Su-Xi-Chang Fault is an important buried fault in Yangtze River Delta. In the respect of structural geomorphology, hilly landform is developed along the southwest side of the Su-Xi-Chang Fault, and a series of lakes and relatively low-lying depressions are developed on its northeast side, which is an important landform and neotectonic boundary line. The fault controlled the Jurassic and Cretaceous stratigraphic sedimentary and Cenozoic volcanic activities, and also has obvious control effects on the modern geomorphology and Quaternary stratigraphic distribution. Su-Xi-Chang Fault is one of the target faults of the project "Urban active fault exploration and seismic risk assessment in Changzhou City" and "Urban active fault exploration and seismic risk assessment in Suzhou City". Hidden in the ground with thick cover layer, few researches have been done on this fault in the past. The study on the activity characteristics and the latest activity era of the Su-Xi-Chang Fault is of great significance for the prevention and reduction of earthquake disaster losses caused by the destructive earthquakes to the cities of Changzhou, Wuxi and Suzhou. Based on shallow seismic exploration and drilling joint profiling method, Quaternary activities and distribution characteristics of the Su-Xi-Chang Fault are analyzed systematically. Shallow seismic exploration results show that the south branch of the Su-Xi-Chang Fault in Suzhou area is dominated by normal faulting, dipping to the north-east, with a dip angle of about 60° and a displacement of 3~5m on the bedrock surface. The north branch of the Su-Xi-Chang Fault in Changzhou area is dominated by normal faulting, dipping to the south, with a dip angle of about 55°~70° and a displacement of 4~12m on the bedrock surface. All breakpoints of Su-Xi-Chang Fault on the seismic exploration profiles show that only the bedrock surface was dislocated, not the interior strata of the Quaternary. On the drilling joint profile in the Dongqiao site of Suzhou, the latest activity of the south branch of Su-Xi-Chang Fault is manifested as reverse faulting, with maximum displacement of 2.9m in the upper part of Lower Pleistocene, and the Middle Pleistocene has not been dislocated by the fault. The fault acts as normal fault in the Pre-Quaternary strata, with a displacement of 3.7m in the Neogene stratum. On the drilling joint profile in the Chaoyang Road site of Changzhou, the latest activity of the north branch of Su-Xi-Chang Fault is manifested as reverse faulting too, with maximum displacement of 2.8m in the bottom layer of the Middle Pleistocene. The fault acts as normal fault in the Pre-Quaternary strata, with a displacement of 10.2m in the bedrock surface. Combining the above results, we conclude that the latest activity era of Su-Xi-Chang Fault is early Middle Pleistocene. The Su-Xi-Chang Fault was dominated by the sinistral normal faulting in the pre-Quaternary period, and turned into sinistral reverse faulting after the early Pleistocene, with displacement of about 3m in the Quaternary strata. The maximum magnitude of potential earthquake on the Su-Xi-Chang Fault is estimated to be 6.0.     

Tectonic activity and earthquake risk in the Cheng-nanhe fault zone in Weihai city,Shandong province,China, obtained by using an integrated prospecting technique in geophysics and geology

For city planning and reducing potential earthquake risk, it's necessary to detect the information of the buried faults in an urban area especially, including the location and activities. An integrated technique with geophysical and geological methods, including the shallow seismic reflection profile, electrical resistivity measurement, geologic borehole section, and exploration trench, was used to detect the Chengnanhe fault, which is one of the two main faults passing through the Weihai urban area in Shandong province, China. The results show that it is a normal fault striking with E-W direction, and it is relatively inactive and stable. By using the thermoluminescence (TL) dating, we found that the Chengnanhe fault initiated in mid-Pleistocene and there was no offset after late Pleistocene. Such an integrated technique with multiple geological and geophysical methods provides a significant assessment of earthquake risk for city planning in urban areas.