右江断裂带晚更新世活动的若干地质地貌证据及位移速率

右江断裂带地处桂西断块区,有记载以来沿带曾发生40～50级地震15次,属中强地震带。笔者在室内卫片、航片、大比例尺地形图解译和分析的基础上,经野外实地调查,获得了断裂带晚更新世活动的若干地质地貌证据,实测了断裂的左旋位移数据。文中介绍了有关证据,并根据年龄数据,计算了断裂中、晚更新世以来的水平和垂直位移速率。断裂带在平面上分3大段,即百色以西段、百色—思林段、思林—坛洛段,各大段又可进一步分为若干个小段。断裂断错了距今(328±025)×104a～(1016±079)×104a的阶地堆积物和残坡积物,控制着百色—田东晚第四纪盆地的发育,地貌上形成断层谷和槽地、断层崖和陡坎,横穿断裂的水系发生同步左旋位移,其活动性质以左旋走滑为主,兼有张性差异运动。晚更新世不同时段以来断裂的水平位移速率为147～198mm/a,中更新世以来的垂直位移速率为074～076mm/a,晚更新世以来为01～035mm/a。该断裂的位移速率明显低于其西的川滇断块内部断裂,更低于川滇断块周边断裂     

1125年兰州7级地震地表破裂类型及其分布特征

根据马衔山北缘断裂西北段1/10000条带状地质填图和史料考证资料,对兰州1125年7级地震的极震区范围、发震断层、地表破裂类型及分布特征进行了讨论。结果表明,该次地震的极震区范围位于兰州市及其西南,震中在咸水沟一带,发震断层为马衔山北缘断裂西北段咸水沟—马泉沟小段。该次地震形成了长约7km,宽300～1000m的地表破裂,其破裂类型有地震断层、地震陡坎、地震裂缝、地震滑坡、地震陷坑等。其中可细分为2小段,东南小段为麦地湾—咸水沟段,由两条平行的地表破裂组成;西北小段为大马家滩—马泉沟段,由单条地表破裂组成。根据大比例尺平、剖面图实测,该次地震的左旋位移量2.4～2.5m,垂直位移量0.45～0.92m。文章最后,对地震的构造背景进行了讨论     

天桥沟-黄羊川活动断裂带的几何学和运动学特征

依据１ ：５０ ０００ 地质填图资料,对天桥沟—黄羊川活动断裂带晚更新世以来的几何学和运动学特征进行了详细的论述．认为该断裂带可分为逆走滑（ 左旋） 的天桥沟断裂段和正走滑（ 左旋） 的黄羊川断裂段,其主要活动时期是晚更新世,滑动速率为４ ～５ ｍ ｍ／ａ ．全新世早期,该断裂带活动强度逐渐减弱,其最后一次活动的时间为距今０ ．７５９ ×１０４ ～１ ．０２ ×１０４ 年     

香山北缘活动断裂带东段构造特征及活动性分析

在野外实测工作基础上, 对香山北缘活动断裂带东段自晚更新世以来的水平活动强度分时、 分段进行了研究. 结果表明, 该断裂带东段自晚更新世以来, 总体水平活动强度不大: 晚更新世早—中期水平位移速率为1.44 mm/a, 晚期水平位移速率为0.53 mm/a, 全新世水平位移速率为1.01 mm/a. 该断裂带左旋走滑强度在走向上具有不均一性, 而且其活动强度的最大部位(活动中心)随时间向东发生迁移, 碱沟—刘岗井次级断层是现今活动强度最大的次级断层.      

西秦岭北缘断裂带武山—天水段全新世活动的新证据

西秦岭北缘断裂带是青藏高原东缘一条大型左旋走滑活动断裂带和历史强震带。前人对该断裂漳县以西段曾开展过大量研究工作,获得其最新构造活动的地质地貌证据,而中段(武山—天水段)和东段(天水—宝鸡段)最新活动时代一直存在分歧。基于高分辨率卫星影像解译、地质地貌调查与综合分析、探槽开挖和~(14)C测年等方法,对西秦岭北缘断裂带武山—天水段进行详细研究,结果表明:该段断裂晚第四纪以来活动显著,地貌上主要表现为断层垭口、断层沟槽、山脊与水系及阶地同步左旋位错、断层陡坎等;多个探槽剖面及测年结果显示其最新构造活动断错了全新世地层,为该段断裂全新世活动和大震危险性分析提供了新的证据。     

龙陵-瑞丽断裂(南支)北段晚第四纪活动性特征

遥感影像解译和野外地质地貌调查表明,龙陵-瑞丽断裂(南支)北段是以左旋走滑为主兼张性正断的区域性活动断裂。根据一些断错地貌点的大比例尺填图、实地测量及其年代学分析,确定了该断裂为全新世活动断裂,断裂晚更新世以来的平均水平滑动速率为2.2mm/a,平均垂直滑动速率为0.6mm/a;全新世以来的平均水平滑动速率为1.8～3.0mm/a,平均垂直滑动速率为0.5mm/a。断裂晚更新世以来的滑动速率在不同的时间尺度上变化不大,反映了该断裂晚更新世以来的活动强度比较平稳     

西秦岭北缘断裂带黄香沟段晚第四纪水平位移特征及其微地貌响应

西秦岭北缘断裂带是青藏高原东北部一条左旋走滑为主的活动断裂带,其在黄香沟一段活动性较强,活动现象典型。对沿断裂带分布的地貌、地质体等晚第四纪位移量的研究表明,在黄香沟一带,断裂晚更新世晚期以来的水平位移量最大为40~60m;最小为6~8m,可能是一次滑动事件的特征位错量。断裂带上的位移具有分组特征,各组位移值之间具有6~8m的稳定增量。位移值的分组性和增量特征反映了该段断裂具有特征地震的活动特征,而7组位错值则反映了断裂7次特征活动事件。关于黄香沟一带与断裂相关的微地貌分析,也获得了大致相对应的事件次数。并由此初步推测,晚更新世晚期以来,该断裂带有过多次强烈活动,活动期次明显     

小江断裂带中段盆地的发育阶段及其与区域构造运动的关系

小江断裂带中段新生代发育的系列盆地，根据其发育阶段可分为始新世—渐新世、上新世—早更新世、中更新世—晚更新世和晚更新世—全新世４个阶段，并根据发育持续性可分为继承性、阶段性、复活性、新生性４种类型。由大比例尺填图所获资料及前人成果，介绍了各阶段盆地的分布特征和成因机制，讨论了盆地发育与区域构造运动、断裂活动的关系     

山西峨嵋台地北缘断裂晚第四纪活动性

通过1/5万活断层地质填图,对山西峨嵋台地北缘断裂晚第四纪活动性进行了详细研究。以谭家庄、南柳附近的2个阶区为界,将断裂分为西、中、东3段。谭家庄以西该断裂中更新世早期有过活动,之后未见明显活动迹象。谭家庄至南柳之间断裂晚更新世以来活动强烈,全新世仍有活动,最新活动发生在(2.00~1.29)ka BP,晚更新世晚期以来滑动速率≥0.36mm/a。南柳至西彰坡段晚更新世以来活动明显,尚未发现全新世活动的直接证据,晚更新世以来断层滑动速率≥0.1mm/a。     

东秦岭内部铁炉子断裂带的最新走滑活动

通过对东秦岭内部铁炉子断裂错断晚更新世以来形成的水系位移测量和阶地砾石层的年代学研究，得到铁炉子断裂距今10万年以来的左旋位移约为125m，活动速率约为1．25mm／a。距今0．20～0．25Ma的中更新世中期以来的左旋滑动速率为3．0～3．75mm／a。估算出东秦岭地区活动断裂系左旋活动速率约为2．25～4．75mm／a，它大致反映了中晚第四纪华南与鄂尔多斯、华北平原活动地块向东滑动速率的差异。     

合浦-北流断裂带西支合浦盆地段断裂活动性研究

合浦-北流断裂起于北部湾海域,经合浦、博白后继续向NE延伸,断裂总长度为400余千米,断裂总体走向为40°～60°,分东、西2支,其中西支自南流江下游合浦盆地西南段一直向NE延伸。文中主要采用地质地貌、地震探测、钻探以及年代学方法,对合浦-北流断裂西支合浦盆地段的活动性进行判定,结果表明:合浦-北流断裂西支合浦盆地段最后1次活动应发生在早更新世中晚期,错距约为10m,断裂被中更新世中、晚期地层覆盖,即中更新世中、晚期以来,断裂的活动趋于减弱或停止     

六盘山东麓断裂断层泥的组构特征及其意义

本文采用宏观与微观相结合的方法 ,研究六盘山东麓断裂的滑动方式。结果表明 :(1)根据断层泥组构特征 ,六盘山东麓断裂可划分为北、中、南 3段 ,这与前人宏观分段结果相一致 ;(2 )北段断层泥局部强烈变形 ,发育牵引褶皱 ,吕德剪切角 (R1)介于 11°～ 2 6° ,以及伊利石无明显的优选方位组构 ,表明该段断层活动是以粘滑为主的左旋走滑运动 ;(3)中、南段断层泥普遍变形 ,吕德剪切角 (R1)一般小于 11° ,P叶理、带状褶皱和肠状构造发育 ,以及伊利石复杂的优选方位组构 ,显示该断层的活动是以蠕滑为主的多期逆冲滑动     

渤海地球物理场与深部潜在地幔热柱的异常构造背景

渤海是中国东部陆缘的一个裂谷型盆地，通过重力、航磁、古地磁、天然地震、地热、应力场、地壳与上地幔结构及地震层析成像等资料，对渤海湾及其周边地带的深部结构、地球物理场效应和深层物理过程进行了综合研究．这一盆地是由NNE－NE向、近EW向和NW向3组断裂组成，这3组断裂与3组地幔隆起带基本相对应，并在渤中坳陷交汇、渤海内部的现代构造运动以水平构造应力场作用下的走滑运动为主要特征，渤海区内地壳厚度仅28-29km，上地幔向上隆起，等温居里面埋深浅（为12km），并为较高区热流值区（56-77mW／m2）．该区岩石层厚度变化显著，庙岛西部中地壳中有一近似圆形的低速体，在120km深度仍为低速异常区．深大断裂可为深部热物质与气态物质上涌的通道．通过综合研究，提出渤海湾很可能是一个潜在的、尚在发展中的地幔热柱．     

安徽南部头坡断裂的活动性研究

对位于安徽南部的头坡断裂的野外调查表明,沿头坡断裂没有明显的水平或垂向错动的地貌现象;在取得的剖面中,上覆第四纪地层均未被断裂断错,表明断裂在中、晚更新世以来没有活动。对本区地貌、第四纪地层和断裂活动历史的调查分析表明,该断裂在燕山运动晚期(侏罗纪末—早白垩世)和喜马拉雅运动早期(晚白垩世—古近纪)有过2次强烈活动,前者表现为左旋走滑运动,后者以拉张活动为特征。新近纪以来全区处于长期隆升剥蚀状态,缺失新近系,第四系厚度不大,残坡积地层广泛发育,构造运动微弱。头坡断裂的活动历史及新活动性与其相邻的郯庐断裂带南段相似,前者可能受后者的控制     

FIRST REPORT OF BERO ZECO ACTIVE FAULT IN GÊRZÊ, NORTHERN TIBET

In the interior of the Tibetan Plateau, the active tectonics are primarily marked by conjugate strike slip faults and north-trending rifts, which represent the E-W extension since late Cenozoic of the plateau. The conjugate faults are mainly composed of NE-trending left-lateral strike-slip faults in Qiangtang terrane and NW-trending right-lateral strike-slip faults in Lhasa terrane. While, the rifts mainly strike N, NNW and NNE within southern Tibet. However, it is still a debate on the deformational style and specific adjustment mechanism of E-W extension. One of key reasons causing this debate is the lack of detailed investigation of these active faults, especially within the northwestern plateau. Recently, we found a 20km long, NNW-trending active fault at Bero Zeco in northwestern Tibet. This fault is presented as fault sag ponds, channel offsets and fault scarps. Displacement of channels and geomorphic features suggested that the Bero Zeco Fault(BZF)is a dextral strike-slip fault with a small amount of normal slip component, which may result from the E-W extensional deformation in the interior of Tibet. BZF strikes N330°~340°W, as shown on the satellite image. The main Quaternary strata in the studied area are two stages alluvial fans around the Bero Zeco. From the satellite images, the old alluvial fans were cut by the lake shoreline leaving many of lake terraces. And the young fans cut across the lake terraces and the old fans. By contrasting to the "Paleo-Qiangtang Huge Lake" since late Quaternary, these old alluvial fans could be late Pleistocene with age ranging from 40ka to 50ka. And the young fans could be Holocene. The sag ponds along the BZF are distributed in the late Pleistocene alluvial fans. Also, the BZF displaced the late Pleistocene fans without traces within Holocene fans, suggesting that the BZF is a late Pleistocene active fault. The fault scarps are gentler with the slope angle of around 10° and the vertical offset is about 2m by field measurement. Reconstruction of the offset of channels suggested that the accumulated dextral offset could be about 44m on the late Pleistocene alluvial fans. Therefore, we infer that the dextral slip-rate could be around 1mm/a showing a low-rate deformation characteristic. The angle between the strike of BZF and principal compressive stress axis(σ₁)is around 30°, which is significantly different to the other faults within the conjugate strike-slip fault zones that is 60°~75°. Now, the deformation mechanisms on these conjugate faults are mainly proposed in the studies of obtuse angle between the faults and σ₁, which is likely not applicable for the BZF. We infer that the BZF could be the northward prolongation of the north-trending rifts based on the geometry. This difference suggests that the conjugate strike-slip faults may be formed by two different groups:one is obtuse angle, which is related to block extrusion or shear zones in Lhasa and Qiangtang terranes possibly; the other is acute angle, which may represent the characteristics of new-born fractures. And more studies are needed on their deformation mechanisms.     

贺兰山东麓断裂南段套门沟-榆树沟段全新世活动与古地震

贺兰山东麓断裂是银川地堑西侧的重要构造,控制着银川地堑的西侧边界,其最新活动特征是评价未来银川市地震危险性的重要依据。文中在贺兰山东麓断裂南段套门沟—榆树沟段断裂两侧1km范围内1:10000地质填图的基础上,选择在大石头沟两侧进行探槽研究,获得该段断裂在14ka以来共发生了3次古地震事件,分别距今13.8ka、7.9ka和3.0ka,重复周期约为6ka和5ka左右     

山东安丘-莒县断裂小店子-茅埠段新活动及其定量研究

小店子—茅埠段是沂沭断裂带安丘-莒县断裂的组成部分,北起莒县小店子东北,南至莒县茅埠以南,总体走向10°～20°,倾向NW或SE,倾角60°以上,长约30km。可细分为5小段,从北到南依次是小店子—齐家庄、源河、库山—西莲池、青峰岭和三庄—宅科小段。各小段之间为左阶或右阶斜列,平面上呈向北收敛、向南撒开的帚状。断裂在卫片和航片上都显示出清楚的线性影像,地貌上表现为清楚的基岩陡坎。根据野外所获得的天然和探槽剖面以及年龄样品测试结果,确定其最新活动时代为全新世早期,活动性质是以右旋走滑为主兼挤压逆断。距今约70ka以来,断裂的右旋位移量64～73m,位移速率0.91～1.04mm/a。距今约12ka以来,断裂的右旋位移量5.5～7.8m,位移速率0.46～0.65mm/a;垂直位移量2～3.8m,位移速率0.17～0.32mm/a     

MECHANISM OF THE 2016 HUTUBI,XINJIANG, MS6.2 MAINSHOCK AND RELOCATION OF ITS AFTERSHOCK SEQUENCES

A strong earthquake with magnitude M_S6.2 hit Hutubi, Xinjiang at 13:15:03 on December 8th, 2016(Beijing Time). In order to better understand its mechanism, we performed centroid moment tensor inversion using the broadband waveform data recorded at stations from the Xinjiang regional seismic network by employing gCAP method. The best double couple solution of the M_S6.2 mainshock on December 8th, 2016 estimated from local and near-regional waveforms is strike:271°, dip:64ånd rake:90° for nodal plane I, and strike:91°, dip:26ånd rake:90°for nodal plane Ⅱ; the centroid depth is about 21km and the moment magnitude(M_W)is 5.9. ISO, CLVD and DC, the full moment tensor, of the earthquake accounted for 0.049%, 0.156% and 99.795%, respectively. The share of non-double couple component is merely 0.205%. This indicates that the earthquake is of double-couple fault mode, a typical tectonic earthquake featuring a thrust-type earthquake of squeezing property.The double difference(HypoDD)technique provided good opportunities for a comparative study of spatio-temporal properties and evolution of the aftershock sequences, and the earthquake relocation was done using HypoDD method. 486 aftershocks are relocated accurately and 327 events are obtained, whose residual of the RMS is 0.19, and the standard deviations along the direction of longitude, latitude and depth are 0.57km, 0.6km and 1.07km respectively. The result reveals that the aftershocks sequence is mainly distributed along the southern marginal fault of the Junggar Basin, extending about 35km to the NWW direction as a whole; the focal depths are above 20km for most of earthquakes, while the main shock and the biggest aftershock are deeper than others. The depth profile shows a relatively steep dip angle of the seismogenic fault plane, and the aftershocks dipping northward. Based on the spatial and temporal distribution features of the aftershocks, it is considered that the seismogenic fault plane may be the nodal plane I and the dip angle is about 271°. The structure of the Hutubi earthquake area is extremely complicated. The existing geological structure research results show that the combination zone between the northern Tianshan and the Junggar Basin presents typical intracontinental active tectonic features. There are numerous thrust fold structures, which are characterized by anticlines and reverse faults parallel to the mountains formed during the multi-stage Cenozoic period. The structural deformation shows the deformation characteristics of longitudinal zoning, lateral segmentation and vertical stratification. The ground geological survey and the tectonic interpretation of the seismic data show that the recoil faults are developed near the source area of the Hutubi earthquake, and the recoil faults related to the anticline are all blind thrust faults. The deep reflection seismic profile shows that there are several listric reverse faults dipping southward near the study area, corresponding to the active hidden reverse faults; At the leading edge of the nappe, there are complex fault and fold structures, which, in this area, are the compressional triangular zone, tilted structure and northward bedding backthrust formation. Integrating with geological survey and seismic deep soundings, the seismogenic fault of the M_S6.2 earthquake is classified as a typical blind reverse fault with the opposite direction close to the southern marginal fault of the Junggar Basin, which is caused by the fact that the main fault is reversed by a strong push to the front during the process of thrust slip. Moreover, the Manas earthquake in 1906 also occurred near the southern marginal fault in Junggar, and the seismogenic mechanism was a blind fault. This suggests that there are some hidden thrust fault systems in the piedmont area of the northern Tianshan Mountains. These faults are controlled by active faults in the deep and contain multiple sets of active faults.     

利用D-InSAR技术研究西藏改则地震同震形变场

针对2008年1月9日MW6.4西藏改则地震和2008年1月16日的MW5.9余震,通过两通(2-pass)加外部DEM差分干涉处理技术(D-InSAR),提取了地震区域2次地震累积的视线向(LOS)同震形变场。结果表明:发震断层均为正断层,位于依布茶卡-日干配错断裂端点附近。主震发震断层走向为N30°E,余震发震断层走向为N21°E,两断层距离约7km;在影像上主震发震断层有造成地表破裂的痕迹,余震未见地表破裂的痕迹;这次地震造成的同震形变场长约30km,宽约20km,主震断层上盘和下盘视线向最大形变量分别为39.2cm和11.2cm,两盘相对位错达50.4cm,余震造成的视线向形变量为9.4cm     

THE DIFFERENCE OF DEPOSITION RATE IN THE BOREHOLES AT THE JUNCTION BETWEEN NANKOU-SUNHE FAULT AND HUANGZHUANG-GAOLIYING FAULT AND ITS RESPONSE TO FAULT ACTIVITY IN THE BEIJING AREA

Beijing plain area has been always characterized by the tectonic subsidence movement since the Pliocene. Influenced and affected by the extensional tectonic environment, tensional normal faulting occurred on the buried NE-trending faults in this area, forming the "two uplifts and one sag" tectonic pattern. Since Quaternary, the Neocathaysian stress field caused the NW-directed tensional shear faulting, and two groups of active faults are developed. The NE-trending active faults include three major faults, namely, from west to east, the Huangzhuang-Gaoliying Fault, Shunyi Fault and Xiadian Fault. The NW-trending active faults include the Nankou-Sunke Fault, which strikes in the direction of NW320°~330°, with a total length of about 50km in the Beijing area. The northwestern segment of the fault dips SW, forming a NW-directed collapse zone, which controls the NW-directed Machikou Quaternary depression. The thickness of the Quaternary is more than 600 meters; the southeastern segment of the fault dips NE, with a small vertical throw between the two walls of the fault. Huangzhuang-Gaoliying Fault is a discontinuous buried active fault, a boundary line between the Beijing sag and Xishan tectonic uplift. In the Beijing area, it has a total length of 110km, striking NE, dipping SE, with a dip angle of about 50~80 degrees. It is a normal fault, with the maximum fault throw of more than 1 000m since the Tertiary. The fault was formed in the last phase of Yanshan movement and controls the Cretaceous, Paleogene, Neogene and Quaternary sediments.There are four holes drilled at the junction between Nankou-Sunhe Fault and Huangzhuang-Gaoliying Fault in Beijing area. The geographic coordinates of ZK17 is 40°5'51"N, 116°25'40"E, the hole depth is 416.6 meters. The geographic coordinates of ZK18 is 40°5'16"N, 116°25'32"E, the hole depth is 247.6 meters. The geographic coordinates of ZK19 is 40°5'32"N, 116°26'51"E, the hole depth is 500.9 meters. The geographic coordinates of ZK20 is 40°4'27"N, 116°26'30"E, the hole depth is 308.2 meters. The total number of paleomagnetism samples is 687, and 460 of them are selected for thermal demagnetization. Based on the magnetostratigraphic study and analysis on the characteristics of sedimentary rock assemblage and shallow dating data, Quaternary stratigraphic framework of drilling profiles is established. As the sedimentation rate of strata has a good response to the activity of the basin-controlling fault, we discussed the activity of target fault during the Quaternary by studying variations of deposition rate. The results show that the fault block in the junction between the Nankou-Sunhe Fault and the Huangzhuang-Gaoliying Fault is characteristic of obvious differential subsidence. The average deposition rate difference of fault-controlled stratum reflects the control of the neotectonic movement on the sediment distribution of different tectonic units. The activity of Nankou-Sunhe Fault shows the strong-weak alternating pattern from the early Pleistocene to Holocene. In the early Pleistocene the activity intensity of Huangzhuang-Gaoliying Fault is stronger than Nankou-Sunhe Fault. After the early Pleistocene the activity intensity of Nankou-Sunhe Fault is stronger than Huangzhuang-Gaoliying Fault. The activity of the two faults tends to consistent till the Holocene.