藏南宁金抗沙西麓断裂晚第四纪活动特征

宁金抗沙西麓断裂位于亚东-谷露裂谷系南部.本文利用15 m分辨率的ETM 遥感影像和20 m分辨率的数字高程模型,结合野外地质考察,重点研究了该断裂的详细结构和晚第四纪以来的活动习性.依据与热隆盆地的关系,该断裂主要分为三段,热隆盆地以北为北段,热隆盆地边界断裂为中段,热隆盆地以南为南段.该断裂在强烈正断的同时兼具有左旋走滑运动,自中更新世以来,主要有三期活动,活动开始时间分别为384 ka1、08 ka和34 ka,累积水平活动速率分别为4.8 mm/a5、.5 mm/a和6.4 mm/a.断裂自中更新中期以来的垂直断错速率为1 mm/a.     

罗云山山前断裂中段土门-贾朱村晚第四纪断错地貌特征

罗云山山前断裂位于山西临汾盆地西侧,控制着盆地的西界。通过对该断裂1∶ 5万地质填图、对河流冲沟阶地及山前断错地貌的调查,介绍了罗云山山前断裂中段土门-贾朱村晚第四纪断错地貌特征。罗云山山前发育D1、D2、D3 等3 级洪积扇,罗云山山前断裂上升盘冲沟发育T1 ～ T5 等5 级阶地。D1 洪积扇与T1、T2 阶地形成于全新世早中期;D2 洪积扇与T3 阶地形成于晚更新世中晚期;D3 洪积扇与T4、T5 阶地形成于中更新世中晚期。罗云山山前断裂中段不同部位断错地貌特征差异较大,D1 洪积扇的断错在席坊沟一带断距约2. 9m;在金殿镇峪口村南西山前断错约3m。D2 洪积扇的断错在土门镇南西堡子村约2. 5m;在杨家庄村西山前断错约4m;在景村西山前断错约6m;在襄陵镇浪泉沟南西侧山前断错约7. 7m。罗云山山前断裂中段山前断错地貌明显,其最新活动时代为全新世。其中,土门段最新活动时代为全新世早期,龙祠段最新活动时代为全新世中晚期。罗云山山前断裂中段晚更新世中晚期以来活动速率为0. 18～ 0. 54mm / a,由北向南活动呈增强趋势;全新世早中期以来活动速率为0. 4 ～ 0. 9mm / a,断裂活动主要集中于席坊沟-峪口一带。罗云山山前断裂中段从晚更新世中晚期到全新世活动速率有增大的趋势,这与该断裂上升盘冲沟阶地从晚更新世中晚期到全新世抬升速率有增大的趋势以及临汾盆地从晚更新世晚期到全新世沉降速率也有增大的趋势具有较好的一致性。     

青海贵南南断裂活动性初步研究

利用Google Earth影像数据,对发育于克日日岗山地与兴海—同德盆地北东边界的NWW走向的贵南南断裂活动性进行研究。通过对该断裂的遥感解译及野外地质调查认为,该断裂性质以逆冲为主,断裂带全长157km,而相关微地貌(水系、冲洪积扇、山脊等)位错研究则表明断裂带最新活动时代为晚更新世,全新世以来未发现断层活动迹象。     

金塔南山断裂中东段古地震特征初步研究

金塔南山断裂位于河西走廊酒泉盆地北侧,是青藏块体与阿拉善块体的边界断裂之一。前人仅对该断裂西段开展过古地震研究。文中基于古地震探槽研究和光释光测年等传统地震地质工作方法,定量研究了金塔南山断裂中东段的古地震特征。通过对断裂进行系统的野外调查,发现沿断裂沿线地层以早更新世至晚更新世洪积物为主,全新世洪积物厚度仅几十cm。选取发育在全新世洪积物相对较厚的洪积扇上的断层陡坎进行工作,获得了一些初步的认识:金塔南山断裂中东段晚第四纪以来持续活动特征明显,全新世洪积扇上发育高0.5~1m的断层陡坎表现出了很新的活动性。多个探槽揭露出晚更新世晚期以来的4次古地震事件,分别发生在(15.16±1.29)ka之前、(9.9±0.5)ka之前、6ka左右、(3.5±0.4)ka之后。全新世中期以来,发生过2次事件,且2次古地震均造成断裂全段破裂。     

忻定盆地晚更新世晚期的一次构造运动

忻定盆地是山西地堑系北部的一个张性断陷盆地,第四纪构造运动活跃。野外调查表明,盆地内晚更新世晚期经历了一次较强的构造运动,它使得断块山地进一步抬升,中止了末次冰期鼎盛期的一次河流加积过程,位于断裂上升盘的洪积扇扇顶部分也被抬升为洪积台地,山前形成了十几米到几十米的断层陡崖;构造运动还导致断层上升盘河流下切,形成了Ⅱ级阶地。黄土-古土壤时间标尺和多种方式的测年结果表明这次构造运动开始于距今2万年左右     

韩城断裂晚第四纪活动性研究

在1:5万活断层地质地貌填图的基础上,对韩城断裂的构造地貌特征及晚第四纪活动性进行了详细研究。依据断裂的构造地貌、活动性及几何展布特征等将断裂自北向南分为3段:西硙口至盘河段、盘河至行家堡段和行家堡至义井段。断裂的活动性自NE向SW是逐渐变弱的。西硙口至盘河段为典型的盆山地貌,全新世活动,全新世中期以来的垂直滑动速率估算0.8mm/a;盘河至行家堡段,断裂沿黄土台地前缘展布,晚更新世晚期活动,晚更新世晚期以来的垂直滑动速率约为0.49mm/a;行家堡至义井段,断裂伸入渭河盆地北部黄土塬中,晚更新世早期黄土中发育裂隙及砂土液化现象。     

中更新世以来北天山的向北扩展

利用深部地球物理结果与浅部地质调查结果进行对比,并基于DEM的地貌分析,研究了中更新世以来北天山向北扩展的造山过程.中更新世以来,北天山地壳中存在南倾的低角度滑脱面,滑脱面之上,逆断裂和褶皱带组成的山前活动构造带整体向北滑脱并缩短变形.中更新世早期,气候暖湿,基岩山脉剥蚀强烈,在山前形成了大规模的洪泛平原.中更新世中期以来,持续的构造活动一方面使山前盆地卷入变形,另一方面使盆地遭受分隔,天山北麓地壳以阶梯式的形式自南向北逐步抬升.中更新世中期约600 ka以来,气候越来越干旱,山前盆地地表仅遭受了轻微剥蚀,地壳抬升全部转换为自南向北的地表隆起,隆起的北部向天山靠拢,隆起的南部逐渐成为山系,与天山相连,北天山得以向北扩展.中更新世以来的掀斜隆起造成山麓至盆地高差达1000多米的坡面,为30 ka以来的河流下切提供了坡度条件,造成了深达300多米的河流强烈下切.     

沈阳长白乡-观音阁断裂、抚顺浑河断裂的定位和活动性研究

本文基于对沈阳长白乡-观音阁断裂,以及抚顺浑河断裂开展的1:10000地质地貌填图工作,获得了这两条断裂在最老第四纪地层热释光的测年结果,它们分别为(112±6.7)ka和(150±9.0)ka。长白乡-观音阁断裂为一沿丘陵山地前缘分布的断裂,由2—3条分支断裂组成,最新的断面活动显示为压扭性正断层性质。断裂在晚更新世坡洪积扇堆积形成以来没有活动显示。3条浅层人工地震测线探测结果表明,其上断点均未错断第四系上更新统底界。断裂为中更新世活动断裂,晚更新世以来没有活动。浑河断裂为一沿丘陵山地前缘分布的断裂,由3—4条分支断裂组成,最新的断面活动显示为压扭性正断层性质。断裂在晚更新世坡洪积扇堆积形成以来没有活动显示。5条浅层人工地震测线探测结果表明,其上断点均在第四系上更新统底界以下。断裂为中更新世活动断裂,晚更新世以来没有活动。     

青藏高原北缘三危山断裂晚第四纪以来的左旋走滑活动

通过对三危山断裂沿线微地貌的实地调查,发现山前主要分布2期冲洪积扇,多呈上叠式排布。对比区域冲洪积扇的分布和形成年龄,结合文中的光释光测年(OSL)结果,认为三危山山前老冲洪积扇形成于晚更新世晚期至全新世早期。发育于冲洪积扇上的纹沟、断裂通过的山脊被同步左旋位错,最大和最小位错量分别为5.5m和1.7m,但大多分布在3.0~4.5m之间。结合光释光测年(OSL)结果,得出三危山断裂在距今1.4万a和2.0万a以来的左旋走滑速率分别为(0.33±0.04)mm/a和(0.28±0.03)mm/a。     

罗云山山前断裂带阶地调查研究及其构造意义

罗云山山前断裂带位于山西临汾盆地西侧,控制着盆地的西界.对罗云山山前断裂带8条冲沟的阶地测量资料的研究表明:该断裂带冲沟发育T1～T5五级阶地.T1 阶地拔沟3m左右,T2 阶地拔沟8～10m,T3 阶地拔沟20m左右,T4 阶地拔沟30m左右,T5 阶地拔沟40～50m.阶地测年数据及断错地貌调查表明:罗云山山前断裂带在晚第四纪以来有过多次活动.晚更新世中晚期以来阶地的抬升速率为0.41 mm/a,全新世以来抬升速率为0.75mm/a.罗云山山前断裂带冲沟阶地从晚更新世中晚期到全新世抬升速率有逐渐增大的趋势,反映该断裂带自晚第四纪以来构造抬升作用逐渐加强,这与临汾盆地从晚更新世晚期到全新世沉降速率也有增大的趋势比较一致.     

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.     

第四纪洞庭盆地临澧凹陷构造-环境演化的水系和重矿物约束

临澧凹陷为第四纪洞庭盆地西部的一个南北向次级构造单元,居于武陵隆起和太阳山隆起之间。前人已通过地貌、沉积和构造特征重塑了凹陷第四纪地质演化过程。本文研究探讨了临澧凹陷水系特征以及凹陷北部ZK 257孔重矿物特征的构造-环境成因,从而进一步为第四纪地质演化过程提供了轮廓。中更新世中期和中后期临澧凹陷处于断陷阶段,凹陷北段为相对封闭的南北向小湖盆,两侧山麓形成EW向水系;南段为相对开放的河流环境,凹陷东、西两侧分别形成NE向和NW向水系,河水向中央入渐水后再向南汇入沅水。中更新世晚期临澧凹陷整体抬升并遭受剥蚀,雷公庙以北降水向北汇入澧水,凹陷西侧形成总体NE走向的次级水系;雷公庙以南继续形成NW向次级水系（渐水西侧）。构造抬升的同时产生向东的倾斜,导致凹陷西侧水系远较东侧发育。ZK 257孔内中更新世洞庭湖组中的重矿物均来源于凹陷及周缘沉积岩而未受沅水影响,表明沅水古河道未经过临澧凹陷。周缘侵蚀作用随临澧凹陷扩张而向两侧扩展,使物源岩性发生变化,从而导致洞庭湖组上部（晚期）重矿物含量高于下部（早期）。     

THE STUDY OF LATE QUATERNARY ACTIVITY OF HANCHENG FAULT

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.     

河西走廊西端花海断裂晚第四纪活动特征

花海断裂是位于河西走廊西端阿尔金断裂系北侧花海盆地内的一条活动断裂,对该断裂活动性的认识不仅有助于评估该区的地震危险性,而且对深入理解青藏高原向北扩展过程中块体相互作用具有重要的科学意义。遥感解译与地震地质调查表明,花海断裂仅局限于花海盆地内,长度约25 km。断裂走向NNW,南端起自花海镇以南,向北经小泉、大泉、双泉子后穿过山水河,向北逐渐消失在北山山前大型冲积扇前。地貌上,花海断裂南部表现为线性延伸的断层陡坎,北段构成了风成砂丘与冲洪积扇的界线。在断裂北段跨断层陡坎进行了探槽开挖,探槽揭露和光释光年代学测试结果表明,该断裂最新一次古地震事件的时间距今约5万年,全新世以来没有明显的活动迹象,为晚更新世活动断裂。结合陡坎位错分析,花海断裂晚第四纪以来垂直滑动速率小于0.03 mm/a。区域大地构造动力学背景分析表明,花海断裂是在青藏高原向北扩展作用下盆地内形成的次一级活动断裂,是高原外围块体对青藏高原向外扩展的响应。     

LATE QUATERNARY SINISTRAL STRIKE-SLIP ACTIVITIES OF SANWEI SHAN FAULT IN THE NORTH OF TIBETAN PLATEAU

Sanwei Shan Fault is located in the north of Tibet, which is a branch of eastern segment of Altyn Tagn fault zone. This fault is distributed along the boundary of fault facet and the Quaternary, with the total length of almost 150km. The fault is a straight-line structure read from the satellite image. Based on the spatial distribution of the fault, three segments are divided, namely, Xishuigou-Dongshuigou segment, Dongshuigou-West Shigongkouzi segment and West Shigongkouzi-Suangta segment, these three segments are distributed by left or right step.Though field microgeomorphology investigation along Sanwei Shan Fault, it has been found that two periods of alluvial-pluvial fans are distributed in front of Sanwei Shan Mountain, most of which are overstepped. Comparing the distribution of alluvial-pluvial fans with their formation age in the surrounding regions, and meanwhile, taking the results of optical stimulated luminescence(OSL) dating, it's considered that the formation age of the older alluvial-pluvial fans, which are distributed in northern Qilian Shan, inside of Hexi Corridor and western Hexi Corridor(including the Sanwei Shan piedmont fans), is between later period of late Quaternary and earlier period of Holocene. The gullies on the older fan and ridges have been cut synchronously. The maximum and minimum sinistral displacement is 5.5m and 1.7m, but majority of the values is between 3.0~4.5m. Taking the results from the OSL dating, we conclude that the minimum sinistral strike-slip rate is(0.33±0.04) mm/a since 14 ka BP and(0.28±0.03) mm/a since 20 ka BP.     

龙陵-瑞丽断裂带附近的构造地貌与断裂活动性

利用ALOS全色、ASTER多光谱遥感影像和SRTM数字高程模型数据解译,并结合野外地质调查和实时差分GPS测量,对龙陵-瑞丽断裂带晚第四纪活动的构造地貌和地质特征进行了研究。综合遥感解译、构造地貌和地震地质调查的结果认为,龙陵-瑞丽断裂带是一条以左旋走滑作用为主的断裂,在晚第四纪具有一定的活动性;并确定了龙陵-瑞丽断裂带各活动段落的空间分布情况。选取朱家寨一带开展了探槽挖掘工作。探槽很好地揭露了基岩中发育的新鲜断层面和晚第四纪冲洪积层,但是未发现断层错动晚第四纪沉积物的迹象。采集了冲洪积层底部的植物化石进行了14C测年,结果为（1150±30）a BP。据此推测,从距今1150年以来,龙陵-瑞丽断裂带活动断层在北段未再发生过破坏性古地震事件。综合分析1976年龙陵地震的发震特点,认为1976年发生在龙陵的大地震未发生在龙陵-瑞丽断裂带上,其震源机制解和余震分布特征表明地震活动与NNW向展布的新生断裂带活动有关,这很有可能造成了NE向龙陵-瑞丽断裂带晚第四纪构造活动性减弱。     

六盘山东麓活动逆断裂构造带晚第四纪以来的活动特征

新的野外调查研究结果表明,六盘山东麓断裂是一条第四纪以来的活动逆断裂构造带。根据断裂走向、活动时代及活动性质的变化,可把该断裂带分为北、中、南３段。北段以左旋走滑运动为主,中、南段以倾向逆冲运动为特征。活动时代北新南老,水平位错北强南弱。晚第四纪以来断裂活动特征的这种变化与西华山 六盘山条形地块东向滑移受阻及断裂走向的改变有关     

ANALYSIS OF EVOLUTION OF THE RIYUESHAN FAULT SINCE LATE PLEISTOCENE USING STRUCTURAL GEOMORPHOLOGY

The northeastern margin of Tibetan plateau is an active block controlled by the eastern Kunlun fault zone, the Qilian Shan-Haiyuan fault zone, and the Altyn Tagh fault zone. It is the frontier and the sensitive area of neotectonic activity since the Cenozoic. There are widespread folds, thrust faults and stike-slip faults in the northeastern Tibetan plateau produced by the intensive tectonic deformation, indicating that this area is suffering the crustal shortening, left-lateral shear and vertical uplift. The Riyueshan Fault is one of the major faults in the dextral strike-slip faults systems, which lies between the two major large-scale left-lateral strike-slip faults, the Qilian-Haiyuan Fault and the eastern Kunlun Fault. In the process of growing and expanding of the entire Tibetan plateau, the dextral strike-slip faults play an important role in regulating the deformation and transformation between the secondary blocks. In the early Quaternary, because of the northeastward expansion of the northeastern Tibetan plateau, tectonic deformations such as NE-direction extrusion shortening, clockwise rotation, and SEE-direction extrusion occurred in the northeastern margin of the Tibetan plateau, which lead to the left-lateral slip movement of the NWW-trending major regional boundary faults. As the result, the NNW-trending faults which lie between these NWW direction faults are developed. The main geomorphic units developed within the research area are controlled by the Riyueshan Fault, formed due to the northeastward motion of the Tibet block. These geomorphic units could be classified as:Qinghai Lake Basin, Haiyan Basin, Datonghe Basin, Dezhou Basin, and the mountains developed between the basins such as the Datongshan and the Riyueshan. Paleo basins, alluvial fans, multiple levels of terraces are developed at mountain fronts. The climate variation caused the formation of the geomorphic units during the expansion period of the lakes within the northeastern Tibetan plateau. There are two levels of alluvial fans and three levels of fluvial terrace developed in the study area, the sediments of the alluvial fans and fluvial terraces formed by different sources are developed in the same period. The Riyueshan Fault connects with the NNW-trending left-lateral strike-slip north marginal Tuoleshan fault in the north, and obliquely connects with the Lajishan thrust fault in the south. The fault extends for about 180km from north to south, passing through Datonghe, Reshui coal mine, Chaka River, Tuole, Ketu and Xicha, and connecting with the Lajishan thrusts near the Kesuer Basin. The Riyueshan Fault consists of five discontinuous right-step en-echelon sub-fault segments, with a spacing of 2~3km, and pull-apart basins are formed in the stepovers. The Riyueshan Fault is a secondary fault located in the Qaidam-Qilian active block which is controlled by the major boundary faults, such as the East Kunlun Fault and the Qilian-Haiyuan Fault. Its activity characteristics provide information of the outward expansion of the northeastern margin of Tibet. Tectonic landforms are developed along the Riyueshan Fault. Focusing on the distinct geomorphic deformation since late Pleistocene, the paper obtains the vertical displacement along the fault strike by RTK measurement method. Based on the fault growth-linkage theory, the evolution of the Riyueshan Fault and the related kinetic background are discussed. The following three conclusions are obtained:1)According to the characteristics of development of the three-stage 200km-long steep fault scarp developed in the landforms of the late Pleistocene alluvial fans and terraces, the Riyueshan Fault is divided into five segments, with the most important segment located in the third stepover(CD-3); 2)The three-stage displacement distribution pattern of the Riyueshan Fault reveals that the fault was formed by the growths and connections of multiple secondary faults and is in the second stage of fault growth and connection. With CD-3 as the boundary, the faults on the NW side continue to grow and connect; the fault activity time on the SE side is shorter, and the activity intensity is weaker; 3)The extreme value of the fault displacement distribution curve indicates the location of strain concentration and stress accumulation. With the stepover CD-3 as the boundary, the stress and strain on NW side are mainly concentrated in the middle and fault stepovers. The long-term accumulation range of stress on the SE side is relatively dispersed. The stress state may be related to the counterclockwise rotation inside the block under the compression of regional tectonic stress.