山西太谷断裂带全新世活动及其与1303年洪洞8级地震的关系

最新调查结果表明，太谷断裂断错山前冲沟Ⅰ级阶地以及在黄土台地前缘形成断坎，在地表及探槽中多处见到断裂断错全新世地层，断裂的最新活动是1303年洪洞8级地震，活动方式为右旋走滑兼正倾滑活动. 在该次地震中，太谷断裂与灵石隆起上的绵山西侧断裂、临汾盆地东边界的霍山山前断裂一起活动，形成长约160 km的地表破裂带. 除此之外，该断裂曾在全新世中期及距今7 700年以后有过活动. 由此得到，在山西断陷系，两个断陷盆地边界断裂的贯通活动发生8级特大大震.      

山西交城断裂带多个大探槽全新世古地震活动对比研究

介绍了沿交城断裂带5个地点开挖探槽揭示的古地震情况.这5个大探槽分别沿交城断裂带北、中、南段分布,其中北段和中段各有2个地点,南段1个地点,探槽之间相距 11～35km.位于该断裂带北段和中段的4个探槽出露了断错全新世地层的断面,在这4个探槽中,位于断裂带北段的西张探槽和位于断裂带中段的新民探槽揭示的全新世3次古地震事件可进行对比,具有活动的同步性.由此显示交城断裂带的中段和北段在距今3 060～3 740a、接近5 910a及8 530～8 560a期间,曾发生3次有地表破裂的古地震事件.位于断裂带北段的冶峪探槽,由于探槽位于台地内冲沟右旋扭曲处,断错的最新地层的年代距今10 730a,其它断面断错晚更新世地层.位于断裂带中段的上固驿探槽地处洪积扇,断层带宽70m,断层走向N58°～74°E,断错的最新地层距今11 570a,揭示了NEE向田庄断层晚更新世时期的活动.位于断裂带南段窑头探槽所在的原始地形受到人工改造影响,探槽剖面揭示全新统覆盖在显示距今 3.0～3.5万年期间受到断裂活动影响的地层之上.交城断裂带5个地点的探槽开挖结果显示,该断裂带全新世时期的活动自南向北迁移.     

金州断裂盖州北—鞍山段古地震破裂的新证据

1975年海城M_S7.3地震是中国第1次成功预报的7级以上破坏型地震,避免了大量人员和财产损失。但在地震后的调查中并没有发现较为连续的地表破裂带,只在零星地点发现了一些地表裂缝和喷砂冒水现象。该地震的等震线表现出较为明显的共轭特征,因此研究者对于海城地震的发震断层一直存在一定争议。文中对与海城河断裂共轭相交的金州断裂盖州北—鞍山段进行了遥感影像解译、微地貌测量和古地震探槽开挖等工作,发现金州断裂自大石桥市沿NE向至鞍山市南,在盆山过渡带的晚更新世和全新世地貌面上存在较为明显的沿NE向展布的断层陡坎。由于人类活动,断层陡坎展布不连续。断层陡坎的高度多为1～2m,最大可达3m;在海城市南葫芦峪村开挖的古地震探槽揭露出盖州北—鞍山段具有宽约20m的基岩破碎带,晚更新世晚期—全新世以来(距今(37.6±2.2) ka)至少发生过2次古地震事件。较新的一次地震发生于全新世(距今(11.7±0.8) ka以后,很可能为距今400～500a)。由于全新世地层太薄所限,无法识别出更多全新世古地震,但可以判断金州断裂盖州北—鞍山段为晚更新世晚期—全新世活动断裂。     

新疆塔城盆地断裂的晚第四纪活动特征

塔城盆地在大地构造上,位于哈萨克斯坦—准噶尔板块内,是西准噶尔山地的一山间盆地。在盆地周边及邻近地区主要分布有塔克台断裂、冬格列克断裂、裕民南断裂、巴尔鲁克山东缘断裂等。这些断裂在晚第四纪以来发生过显著的活动,断错了山前洪积扇和河流阶地及河漫滩,并形成连续分布的地表错动形变带。形变带主要由断层陡坎、断塞塘、挤压鼓包、沟槽等组成。经调查研究,形变带为古地震形变带。通过野外实地调查和大型探槽开挖及光释光年代测定,断裂在晚更新世或全新世时期发生过新活动及古地震。     

郯庐断裂带安徽紫阳山段发现全新世活动证据

安丘-莒县断裂(F_5)为郯庐断裂带中段东地堑内最新活动断裂。近年来,F_5江苏段研究成果丰硕,发现不同地段普遍存在全新世活动性,运动方式以右旋走滑兼挤压逆冲为主。以往研究未讨论过F_5在淮河以南安徽境内的延伸情况以及进一步的活动性问题。文中选取与F_5江苏段线性影像特征延伸一致的淮河南岸郯庐紫阳山段作为突破口,通过遥感影像解译、地质地貌调查和探槽开挖,初步得到以下认识:1)紫阳山段线性构造地貌特征清晰,断层发育于浮山至紫阳山一线的中生代红色砂岩隆起边缘缓坡,为安丘-莒县断裂(F_5)过淮河后的南延部分;2)朱刘探槽开挖揭示,该段错断了晚更新世晚期黏土层,晚更新世晚期—全新世早期黑色黏土层受断层活动影响沿断面灌入、填充,形成黑色断层条带及黑土充填楔,表明断层最新活动时代达全新世早期;3)朱刘探槽开挖揭示,该段第四纪以来存在至少3次古地震事件,第1次古地震事件推测年代为第四纪早、中期,第2次古地震事件年代为20.10~13.46ka BP,第3次古地震事件年代为(10.15±0.05)~(8.16±0.05)ka BP。上述研究成果弥补了对郯庐断裂带安徽段晚第四纪活动性认识的不足,为安徽省的地震监测和震害防御工作提供了基础数据。     

海原古地震的一个剖面

为查明南、西华山北缘大断裂的活动性质、活动量及大地震重复间隔,我局于1983年10月在1920年海原大地震震中区沿干盐池至小山地段挖了12条探槽。在4条探槽的全新世地层中,见到该断裂多次活动的证据,其中以海原城西南约12公里的刺儿沟探槽揭露的古地震剖面最为精彩和典型,现对它简报如下:探槽呈北东—南西向,位于南华山北缘刺儿沟旁Ⅱ级阶地上,由不连续的两截组成。揭露了主断裂面F_3和1920年地震断裂F_2及地表形变带(图1)。南华山北缘断裂主断面F_3出露非常清楚,断裂南西盘为前寒武系浅灰绿色片岩与大理岩,已强烈破碎     

内蒙古色尔腾山山前断裂(乌句蒙口-东风村段)的断层活动与古地震事件

通过对色尔腾山山前断裂乌句蒙口 -东风村段的遥感资料解释、野外地质地貌考察 ,并通过对重点地段的古地震探槽开挖 ,获得了该断裂段晚更新世晚期以来的垂直位移速率是 0 88～ 1 83mm a ,全新世中期以来的垂直位移速率是 0 89mm a。通过 2个大型探槽的开挖、古地震事件分析和相关堆积物的断代研究 ,以及用逐次限定方法分析整个断层段上的古地震事件 ,认定该断裂段上全新世以来发生了 5次古地震事件 :事件 1发生在距今 90 0 0± 130 0年 ,事件2发生在距今 6 5 0 0± 5 0 0年 ,事件 3发生在距今 5 5 70年左右 ,事件 4发生在距今 4 2 0 0± 30 0年 ,事件 5发生在距今 32 5 0± 2 5 0年。晚更新世晚期到距今 1万年之间 ,古地震事件很不完整。全新世以来的 5次古地震事件表现出一定的丛集特征。最早的一丛事件发生在距今 890 0年左右 ,第2丛发生在距今 6 5 0 0～ 5 70 0年之间 ,第 3丛事件发生在距今 32 5 0～ 4 2 0 0年之间。第 1丛与第 2丛古地震事件之间间隔为 2 4 0 0年左右 ,而第 2丛与第 3丛古地震事件之间仅间隔 15 70年左右。距今 32 5 0年以来 ,该断裂段上还没有发生过错断地表的地震事件 ,已经超出了古地震丛之间的重复间隔。因此 ,它是色尔腾山前活动断裂带上具备潜在危险的一个活动断裂段。     

临潼-长安断裂带古地震及地震危险性评价

长安二中探槽是在地面地质调查、浅层地震和钻探的基础上开挖的,探槽中有丰富的砂土液化现象,根据液化砂脉的切割关系,判断有4次古地震事件的发生。根据探槽中地层没有明显错动和临潼-长安断裂带在晚更新世晚期和全新世早期活动较弱,以及历史上无6级以上地震活动记录的特点,本文认为4次古地震事件与临潼-长安断裂带无关,该断裂未来发生强震的危险性不大。     

正倾滑活动断裂垂直位移定量研究中相关问题的讨论

当探槽开挖长度未跨过断层变形带时，得到的断层垂直位移将偏离断层活动的真实情况，在缺少依据帮助确定断层陡坎原始下坡角的具体位置时，通过断层陡坎高度获得的断层垂直位移也将与实际情况有较大的偏离，文中对此进行了讨论。并讨论了应用断层两侧近水平地层累积变位量的分解确定古地震事件期次的方法，以及探槽剖面中断层两侧同层地层厚度差异是断层活动事件的反映等问题。引用了内蒙古大青山山前断裂和狼山山前断裂、北京平原夏垫断裂和南口－孙河断裂及日本丹那断层探槽开挖的实例。     

山西断陷系交城断裂全新世古地震活动初步研究

断错地貌调查及探槽开挖表明,晋中盆地西界分布的黄土台地的前、后缘均存在断层,断层的最新活动位于地表陡坎的前缘,地表见到的断层最新活动断面的上升盘是早全新世地层。同时,新民探槽开挖表明,该断裂在早全新世以后曾发生三次古地震事件,最新一次活动接近距今2748a,另两期古地震事件的时间分别距今4037～5910a及8360～5910a。如果取后两次古地震事件时间跨度的中值,这三次古地震事件的间隔分别是2225a和2162a,平均2193a。     

四川龙泉山断裂带及其活动性与潜在地震危险性讨论

龙泉山构造带是四川盆地内川西强烈断陷区和川中稳定隆起区之间的一条区域性断裂.2008年汶川地震后该断裂带未来的强震潜势备受关注.本文对该断裂带的展布、晚第四纪活动性、深部构造形成机制以及断裂带未来的地震危险潜势进行了讨论.断裂带北段位于德阳东侧龙泉山脉西缘;龙泉山脉中段的山体两翼存在断裂;断裂带的南段以向西倾斜的断裂为主.这些断裂在晚更新世以来曾有活动,前人阶地调查显现该断裂带全新世存在活动.考虑到该断裂带未来的地震潜势评估,值得对该断裂带的活动性及断裂带深部构造和运动方式开展进一步的调查.     

应用布格重力异常研究郯庐断裂构造

使用布格重力资料对郯庐断裂带的中段部分（沂沭断裂带）进行了研究. 结果表明， 郯庐断裂带莫霍面及地壳内界面均发生错断，断裂带两侧地壳各界面起伏平缓. 该结果与前人的郯庐断裂带是切穿地壳的深大断裂的认识相一致. 在郯庐断裂带两侧，地壳结构明显不同，西侧沉积层较薄，平均在5 km以下；东侧多数在6 km以上；在断裂带中央沉积物最薄，大约为3～4 km. 断裂带东侧莫霍面埋深浅，大约为33～34 km；西侧莫霍面埋深明显增加，达到36～38 km．反映了莫霍面深度在断裂带附近整体是向西增加的. 郯庐断裂带在重力场分布中则表现为一条宽度较大的线性布格重力异常梯度带.      

The Late Pleistocene activity of the eastern part of east Kunlun fault zone and its tectonic significance

The nearly EW-trending East Kunlun fault zone is the north boundary of the Bayan Har block.The activity characteristics and the position of the eastern end of its eastward extension are of great significance to probing into the dynamic mechanism of formation of the east edge of the Tibetan Plateau,and also lay the foundation for seismic risk assessment of the fault zone.The following results are obtained by analysis based on satellite image interpretation of landforms,surface rupture survey,terrace scarp deformation survey,and terrace dating data on the eastern part of the East Kunlun fault zone:(1)the Luocha segment is a Holocene active fault,where a reverse L-shape paleoearthquake surface rupture zone of about 50 km long is located;(2)the Luocha segment is characterized by left-lateral slip movement under the compression-shear condition since the later period of the Late Pleistocene,with a rate of 7.68–9.37 mm/a and a vertical slip rate of 0.7–0.9 mm/a,which are basically in accord with the activity rate of segments on its west side.The results indicate that it is a part of eastward extension of the East Kunlun fault zone;(3)the high-speed linear horizontal slip of the nearly EW-trending East Kunlun fault zone is blocked by the South China block at east,and transforms into the vertical movement of the nearly SN-NNE trending Minjiang fault zone and the Longmenshan fault zone,and the uplift of Longmenshan and Minjiang.The area where transform of the two tectonic systems occurred confines the position of the east end;(4)Luocha segment and Maqu segment constitute the"Maqu seismic gap",so,seismic risk at Maqu segment is higher than that at Luocha segment,which should attract more attention.     

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.     

小江断裂带中段的北东向断裂与断块结构

小江断裂带中段东西支断裂间存在的ＮＥ向断裂是在第三纪ＮＥ向断裂的基础上，于第四纪中晚期开始新的活动，并具有左旋走滑运动的特征，有些在全新世仍有活动。它们的活动从属于小江断裂带的整体左旋走滑运动，其运动幅度和速率比近ＳＮ向小江东西支断裂小得多，但是由于它们的运动，使主断裂产生弯曲或阶区，形成有利于应力和应变集中的障碍。夹于东西支断裂之间的断块被ＮＥ向断裂切割为多个次级菱形和梭形断块，这些断块之间的相对运动对断裂分段和地震孕育过程具有不可忽视的影响     

西秦岭临潭-宕昌断裂第四纪最新活动特征

临潭-宕昌断裂是西秦岭造山带内一条重要的分支断裂,其最新活动特征是分析西秦岭构造变形的重要依据。临潭-宕昌断裂的新构造活动强烈,中强地震频繁,但目前对于断裂的新活动特征研究程度较低,未见有其全新世活动地质地貌证据的报道。文中基于遥感解译、宏观地貌分析研究断裂的长期活动表现和分段性;同时通过地质地貌考察、无人机摄影测量、差分GPS和放射性碳测年等方法定量研究断裂的新活动特征;最后基于研究结果探讨了断裂及附近区域的地震危险性和区域构造变形。结果表明:根据断层迹线收敛程度和宏观地貌差异,可将临潭-宕昌断裂分为西、中、东3段;断裂的运动性质以左旋走滑为主,兼具逆冲分量,左旋走滑使洮河及其支流、冲沟和山脊等发生同步左旋拐弯,最大左旋位移可达3km,逆冲分量使新近纪盆地边缘和内部形成300~500m的垂向位移;断裂的最新活动时代为全新世,限定了1次2 090~7 745a BP(置信度为2σ)的全新世古地震事件;全新世早期以来,临潭-宕昌断裂东段主干断裂的左旋走滑速率为0.86~1.65mm/a,垂直滑动速率为0.05~0.10mm/a。临潭-宕昌断裂分配了约2mm/a的左旋走滑分量,是东昆仑-西秦岭阶区变形分配的关键断裂之一。     

东昆仑断裂带东段塔藏断裂几何结构及滑动递减模型讨论

塔藏断裂位于东昆仑断裂带东段, 长约170 km, 与岷山断裂带共同构成巴颜喀拉块体的东北构造边界, 中部与岷江断裂、 荷叶断裂、 虎牙断裂的北延段交会, 构成岷山隆起的地貌边界。 通过卫星影像解译结合构造地貌调查, 确定了断层属于全新世活动断层, 并利用断层走向弯曲和活动性、 阶区等标志将塔藏断裂分为三段。 西段为罗叉段, 总体走向NWW, 西侧与玛曲断裂形成左行左阶拉分区, 东侧在下黄寨村走向顺时针偏转至东北村段。 中段为东北村段, 总体走向NW, 东侧在九寨沟口附近走向逆时针偏转至马家磨段。 东段为马家磨段, 总体走向NWW, 西侧隔荷叶断裂、 虎牙断裂的北延段与中段相接。 东北村段以岷江断裂斜交点为界可分为南北两个次级段, 马家磨段以阶区为界划分为扎如次段、 唐寨次段、 勿角次段。 罗叉段和马家磨段的地震离逝时间较近, 东北村段相对较远。 断裂带整体呈反“S”形, 自西向东滑动速率总体呈减小趋势, 大部分水平变形转化为垂向的岷山隆升。 结合不同段上的滑动速率, 发现东昆仑断裂东段滑动速率呈梯度下降特征与东昆仑断裂带东段断层弯曲的几何特征相对应。     

PRELIMINARY STUDY OF PALEOEARTHQUAKES ON THE MIDDLE-EASTERN SEGMENT OF JINTA NANSHAN FAULT

Hexi Corridor is located at the northeastern margin of the Tibetan plateau. Series of late Quaternary active faults are developed in this area. Numerous strong earthquakes occurred in history and nowadays. Jinta Nanshan fault is one of the boundary faults between the Qinghai-Tibet block and the Alxa block. The fault starts from the northwest of Wutongdun in the west, passes through Changshan, Yuanyangchi reservoir, Dakouzi, and ends in the east of Hongdun. Because the Jinta Nanshan fault is a new active fault in this region, it is important to ascertain its paleoearthquakes since late Pleistocene for the earthquake risk study. Previous studies were carried out on the western part, such as field geomorphic investigation and trench excavation, which shows strong activity in Holocene on the western segment of Jinta Nanshan fault. On the basis of the above research, in this paper, we carried out satellite image interpretation, detailed investigation of faulted landforms and differential GPS survey for the whole fault. Focusing on the middle-eastern part, we studied paleoearthquakes through trench exploration on the Holocene alluvial fan and optical luminescence dating. The main results are as follows:Early Pleistocene to late Pleistocene alluvial strata are widely developed along the fault and Holocene sediment is only about tens of centimeters thick. The Jinta Nanshan fault shows long-lasting activity since late Quaternary and reveals tens of centimeters of the lowest scarp which illustrates new strong activity on the middle-east segment of this fault. Since late Pleistocene, 4 paleoearthquakes happened respectively before(15.16±1.29) ka, before(9.9±0.5) ka, about 6ka and after(3.5±0.4) ka, revealed by 4 trenches, of which 2 are laid on relatively thicker Holocene alluvial fan. Two events occurred since middle Holocene, and both ruptured the whole fault.     

轮台迪那尔河"五一"水库附近活动断裂

对水库近场区内的多条活动断裂研究认为：区域性北轮台断裂具分段性，水库所在的西部断裂全新世以来未活动；全新世活动的东却勒塔格断裂向东延伸至二八台河以西；库区土尸洛克背斜核部有全新世断裂，但对水库影响不大；牙哈背斜北翼发现10km左右的断裂陡坎，隐伏断裂局部出露地表。     

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.