共查询到19条相似文献,搜索用时 167 毫秒
1.
断层的活动时代是活动构造、古地震和新构造等研究中的重要内容 ,也是目前的难点所在。确定断层最新一次活动事件的年代通常有两种途径 :一是通过测定断层活动产物 (如断层泥、断层破碎物、崩积楔等 )的年龄来确定断层事件的年代 ;二是通过测定断层错动的最新地层及其上覆未错动的最老地层的年龄 ,来获得活动年代的上下限年龄。根据沿高丽营断层在房山坨里至永定河一带所观察到的活动断层的具体特征 ,分别采用了上述两种途径和相应的测年技术 ,给出了芦井、晓右营、辛开口和长辛店等地断层的最后一次活动的大致年代。高丽营断层至少有过 3次活动 ,分别发生在距今 2 70~ 36 0 ,130~ 140和 1.8~ 4 .2ka 相似文献
2.
对能动断层概念史的研究,可以揭示出能动断层的核心意义以及与活动断层的区别和联系。能动断层的鉴定以确定未来地表或近地表断层错断可能性为目的,与地震地面运动相比是一种不可设计的厂址评价要素。因此,在厂址适宜性评价中意义重大。 相似文献
3.
本文论述了剖面逆断层束的特点和形成机制,提出了用剖面逆断层束研究古地震事件的准则。通过一些典型的实例证明了这一认识的正确性和可行性,它对活断层和古地震的深入研究有一定指导意义。 相似文献
4.
通过对地震断层陡坎演为过程的分析,应用均匀物质扩散理论建立地震断层陡坎的形态方程,推断古地震断层陡坎的年龄,从而确定古地震事件的期次及年代。用该方法对二台活断层古地震断层陡坎进行计算,所得结果与用其它方法确定的古地震事件的期次及年代对应较好。 相似文献
5.
通过室内航片判读和野外调查 ,在酒西盆地发现 3条全新世活动逆掩断层 ,它们全新世以来的垂直活动速率都很接近 ,为 0 18~ 0 2 5mm/a。通过探槽揭露出的 3条断层全新世以来各发生两次古地震事件。根据探槽揭露的古地震年代及断层活动所形成的微地貌特征分析 ,阴洼山断层是独立活动的 ;北大河断层和新民堡断层上的古地震事件在时间上可能非常接近 ,具有丛集特征 ,或者是一次地震事件分别破裂这两条断层 ,但目前的测年手段还无法区别它们是一次破裂事件形成还是时间上非常接近的两次事件所形成的 相似文献
6.
活动断层周期性粘滑变形的宏观和微观证据 总被引:3,自引:1,他引:2
收集和归纳了活动断层周期性破裂(高速)变形的宏观和微观证据。这些对于我们识别断层上的过去发生的粘滑(古地震)事件遗迹,研究断层活动习性,以更有效地进行地震预测预报是有益的。 相似文献
7.
提出并研究了能动断层与地表断层这两个概念的形成与基本含意,强调了在实际核工程厂址选择时所必须进行的调查内容与要求,并进一步研究了能动断层的鉴别标准问题 相似文献
8.
以银川活动断层试验探测为例,介绍了第四纪巨厚沉积区隐伏断层多手段、多层次探测的步骤与方法。在对前人资料综合分析的基础上,选择银川市兴庆区新渠梢村为综合探测试验场。首先,分层次布施道间距10m、5m和1m的浅层人工地震勘探,由深至浅将银川隐伏断层主断层逐步控制在可以布施浅钻勘探的程度。然后,实施钻孔联合剖面探测,确定了断层的准确位置和倾角,获得了由钻探资料可分辨的断层上断点埋深8.3m的信息。最后,通过大型探槽开挖,查明了断层实际上断点埋深1.5m和5期古地震活动事件。结合地层年龄的初步测定,得出了银川隐伏断层主断层中—晚全新世活动的结论 相似文献
9.
10.
我们研究了加州几个地区古地震记录的时间分布,时间的尺度从数十年至数十万年。分析时使用了断层泥的电子自旋共振坪的定龄方法所获的年龄数据,断层带~(14)C定龄的沉积物及历史地震的记录。在加州中部的圣安德烈斯断层中历史记录和圣加布里埃尔断层带的古地震记录都具有自相似特性,分维为0.43~0.46。在历史地震和古地震时间尺度上,加州南部的圣安德烈斯断层带的分维是0.67,表明比加州中部更为均匀的断层活动。在小于一年的时间尺度上,很大程度的分布是随机的。 相似文献
11.
断层活动是地壳应力释放等的一种表现。其主要应力一般通过区域性断层释放,小断层除释放剩余应力外也可是前者活动时的牵动。因此,在一个局部地区内断层活动时间常具有同步性特点。对化稍营地区大、小断层的研究表明,传统法确认油房断层被上更新统复盖,其最后一次活动时间在晚更新世以前;应用热释光、铀系法与显微构造分析结合,研究发育在基岩中的壶流河断层、F_(207)断层、F_(214)断层和F_(213)断层,确定其最后一次较强烈活动为距今20~30万年前。两者结果的吻合,证明了断层活动时间的同步性特点。 相似文献
12.
FAULT ACTIVITY OF THE SOUTHWESTERN SEGMENT OF THE EASTERN BRANCH OF XINYI-LIANJIANG FAULT ZONE IN GUANGDONG PROVINCE 
下载免费PDF全文
下载免费PDF全文 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. 相似文献
13.
断块运动与活断层分段 总被引:3,自引:3,他引:3
断层作为断块的边界,其活动特征和断块运动密切相关。通过分析断块运动类型与断层活动及其分段的关系,以及断块运动与构造障碍的关系,论述了断块运动研究在活断层分段中的作用 相似文献
14.
15.
ANALYSIS OF THE LATE QUATERNARY ACTIVITY ALONG THE WENCHUAN-MAOXIAN FAULT -MIDDLE OF THE BACK-RANGE FAULT AT THE LONGMENSHAN FAULT ZONE 下载免费PDF全文
下载免费PDF全文 The Longmenshan fault zone is located in eastern margin of Tibetan plateau and bounded on the east by Sichuan Basin, and tectonically the location is very important. It has a deep impact on the topography, geomorphology, geological structure and seismicity of southwestern China. It is primarily composed of multiple parallel thrust faults, namely, from northwest to southeast, the back-range, the central, the front-range and the piedmont hidden faults, respectively. The MS8.0 Wenchuan earthquake of 12th May 2008 ruptured the central and the front-range faults. But the earthquake didn't rupture the back-range fault. This shows that these two faults are both active in Holocene. But until now, we don't know exactly the activity of the back-range fault. The back-range fault consists of the Pingwu-Qingchuan Fault, the Wenchuan-Maoxian Fault and the Gengda-Longdong Fault. Through satellite image(Google Earth)interpretation, combining with field investigation, we preliminarily found out that five steps of alluvial platforms or terraces have been developed in Minjiang region along the Wenchuan-Maoxian Fault. T1 and T2 terraces are more continuous than T3, T4 and T5 terraces. Combining with the previous work, we discuss the formation ages of the terraces and conclude, analyze and summarize the existing researches about the terraces of Minjiang River. We constrain the ages of T1, T2, T3, T4 and T5 surfaces to 3~10ka BP,~20ka BP, 40~50ka BP, 60ka BP and 80ka BP, respectively. Combining with geomorphologic structural interpretation, measurements of the cross sections of the terraces by differential GPS and detailed site visits including terraces, gullies and other geologic landforms along the fault, we have reason to consider that the Wenchuan-Maoxian Fault was active between the formation age of T3 and T2 terrace, but inactive since T2 terrace formed. Its latest active period should be the middle and late time of late Pleistocene, and there is no activity since the Holocene. Combining with the knowledge that the central and the front-range faults are both Quaternary active faults, the activity of Longmenshan fault zone should have shifted to the central and the front-range faults which are closer to the basin, this indicates that the Longmenshan thrust belt fits the "Piggyback Type" to some extent. 相似文献
16.
17.
在室内航,卫片解释及野外1:5万大比例尺活断层地质填图等专项研究的基础上,论证了1927年古浪8级大震主发震断裂皇城-双塔断裂带的几何分段及运动学特征。依据断层的几何特征,活动时期,活动强度可将该断裂带分为3段,分别为皇城盆地段(西段)、上寺段(中段)和冬青顶段(东段)。其中东段是古浪地震的发震段,与西段和中段相比,它具有活动时代新、活动强度大等特点,属全新世活动段。1927年古浪地震的发生与其特 相似文献
18.
The quantitative analysis of morphologic characteristics of bedrock fault surface is a useful approach to study faulting history and identify paleo-earthquake. It is an effective complement to trenching technique, specially to identifying paleo-earthquakes in a bedrock area where the trenching technique cannot be applied. This paper focuses on the Luoyunshan piedmont fault, which is an active normal fault extending along the eastern boundary of the Shanxi Graben, China. There are a lot of fault scarps along the fault zone, which supply plentiful samples to be selected to our research, that is, to study faulting history and identify paleo-earthquakes in bedrock area by the quantitative analysis of morphologic characteristics of fault surfaces. In this paper, we calculate the 2D fractal dimension of two bedrock fault surfaces on the Luoyunshan piedmont fault in the Shanxi Graben, China using the isotropic empirical variance function, which is a popular method in fractal geometry. Results indicate that the fractal dimension varies systematically with height above the base of the fault surface exposures, indicating segmentation of the fault surface morphology. The 2D fractal dimension on a fault surface shows a ‘stair-like’ vertical segmentation, which is consistent with the weathering band and suggests that those fault surfaces are outcropped due to periodic faulting earthquakes. However, compared to the results of gneiss obtained by the former researchers, the characteristic fractal value of limestone shows an opposite evolution trend. 1)The paleo-earthquake study of the bedrock fault surface can be used as a supplementary method to study the activity history of faults in specific geomorphological regions. It can be used to fill the gaps in the exploration of the paleo-earthquake method in the bedrock area, and then broaden the study of active faults in space and scope. The quantitative analysis of bedrock fault surface morphology is an effective method to study faulting history and identify paleo-earthquake. The quantitative feature analysis method of the bedrock fault surface is a cost-effective method for the study of paleo-earthquakes in the bedrock fault surface. The number of weathered bands and band height can be identified by the segment number and segment height of the characteristic fractal dimension, and then the paleoearthquake events and the co-seismic displacement can be determined; 2)The exposure of the fault surface of the Luoyunshan bedrock is affected and controlled by both fault activity and erosion. A strong fault activity(ruptured earthquake)forms a segment of fault surface which is equivalent to the vertical co-seismic displacement of the earthquake. After the segment is cropped out, it suffers from the same effect of weathering and erosion, and thus this segment has approximately the same fractal dimension. Multiple severe fault activities(ruptured earthquake)form multiple fault surface topography. The long-term erosion under weak hydrodynamic conditions at the base of the fault cliff between two adjacent fault activities(intermittent period)will form a gradual slow-connect region where the fractal dimension gradually changes with the height of the fault surface. Based on the segmentation of quantitative morphology of the two fault surfaces on the Luoyunshan piedmont fault, we identified four earthquake events. Two sets of co-seismic displacement of about 3m and 1m on the fault are obtained; 3)The relationship between the fault surface morphology parameters and the time is described as follows:The fractal dimension of the limestone area decreases with the increase of the exposure time, which reflects the gradual smoothing characteristics after exposed. The phenomenon is opposite to the evolution of the geological features of gneiss faults acquired by the predecessors on the Huoshan piedmont fault; 4)Lithology plays an important role in morphology evolution of fault surface and the two opposite evolution trends of the characteristic fractal value on limestone and gneiss show that the weathering mechanism of limestone is different from that of the gneiss. 相似文献
19.
Based on the 1︰50000 geological and geomorphologic mapping of active fault, the structural geomorphic features and activity of Hancheng Fault are investigated in detail. In the study, we divide the fault into three sections from north to south: the section between Xiweikou and Panhe River, the section between Panhe River and Xingjiabao and the section between Xingjiabao and Yijing, the three sections show different characters of tectonic landform. The section between Xiweikou and Panhe River is a kind of typical basin-mountain landform, where diluvial fans spread widely. In the north of Yumenkou, the fault deforms the diluvial fans, forming scarps, along which the fault extends. In the south of Yumenkou, the fault extends along the rear edge of the diluvial fans. In the section between Panhe River and Xingjiabao the fault extends along the front of the loess mesa. In the section between Xingjiabao and Yijing the fault forms scarp in the loess and extends as an arc shaped zone, and the landform is formed by the accumulative deformation of the fault. The activity of the fault becomes weak gradually from northeast to southwest. The fault activity of the section between Xiweikou and Panhe River is the strongest, and the latest age of activity is Holocene. The slip rate since the mid-Holocene is bigger than 0.8mm/a at Yumenkou. The fault activity of the section between Panhe River and Xingjiabao is weaker than the north part, the fault's latest active age is identified as the later period of Late Pleistocene and the activity becomes weak gradually from northeast to southwest. At the estuary of the Jushui River the slip rate of the fault is about 0.49mm/a since late Late Pleistocene. The fault activity of the section between Xingjiabao and Yijing is the weakest. There is no evidence of paleosol S1 deformed in fault profiles, and only some phenomena of fracture and sand liquefaction in the earlier Late Pleistocene loess. The activity of the fault is in line with the fault landform feature. At macro level, the relationship between the uplifted side and the thrown side of the fault switches gradually from the Ordos uplifting region and the rifted basin to the interior blocks of the rifted basin, which maybe is the regional reason why the activity of the Hancheng Fault becomes weak from the northeast to the southwest. 相似文献