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1.
青藏高原湖泊涨缩的新构造运动意义 总被引:2,自引:0,他引:2
青藏高原位于我国的西南部,平均海拔4000—5000m。第四纪以来强烈的新构造运动,引起地壳大幅度的隆起,迫使湖泊出现了大规模的退缩及迁移。新的湖泊不断产生或扩大,古老的湖泊又不断消亡或缩小,形成了湖泊变化与构造活动周期的对应性。本文在分析了青藏高原的地貌、第四纪地质,特别是活断层及地震活动性研究的基础上,对于高原≥4km~2的367个湖泊进行了卫片解译,并取得了较好的效果。 相似文献
2.
岷山断块由岷江断裂和虎牙断裂自西向东的推覆逆掩运动所形成 ,处于我国南北地震带的中段。受区域NWW向主压应力场的控制 ,岷江断裂带第四纪以来表现为明显的推覆逆掩运动并具有一定的左旋走滑分量 ,岷山断块则处于强烈的隆起抬升状态。航片解译及野外地质考察结果表明 ,岷江断裂带由数条次级断裂呈羽列组合而成 ,其中尕米寺 -川盘右阶羽列区的羽列距达3km ,控制了低序次的地震破裂单元。第四纪地貌发育过程及断错地貌研究结果表明 ,岷江断裂晚第四纪以来的平均垂直滑动速率为 0 37~ 0 53mm/a ,水平位错量与垂直位错量大致相当 ;岷山断块第四纪以来的平均隆起速率为 1 5mm/a左右。地震活动特征表明 ,该地区 6级以上强震丛集于强烈活动的断块边界断裂上 ,中强地震及小震发生在新构造隆起区及近东西向断裂带上 ,与断裂的活动性质具有密切的成因联系 相似文献
3.
阿拉善地块南缘地处青藏高原东北缘地壳扩展前锋带的北侧,对该地区活动断裂晚第四纪的运动性质、滑动速率等开展研究,有助于理解阿拉善地块的晚第四纪构造变形特征及其对青藏高原向N扩展的响应。文中结合遥感影像解译与野外地质地貌考察,对阿拉善地块南缘的北大山断裂进行了分段和活动性研究。结果表明,北大山断裂左旋走滑断错晚第四纪洪积扇和阶地等地貌,形成显著的位错阶地坎、冲沟以及断层陡坎。通过对断错地貌线等标志的测量、复原、统计分析等,发现断裂的地貌位移值分布于3~20m,发育新鲜断层自由面的断层陡坎和左旋错动的纹沟指示了断层的最新一次活动。基于同期洪积扇年龄估算得到北大山断裂晚更新世以来的左旋滑动速率为0.3~0.6mm/a。北大山断裂的运动学特征与区域NE向应力场一致,可能受到了青藏高原NE向扩展的影响。 相似文献
4.
本文着重从地震地质、地球物理资料出发,提出展布于松潘,平武地区的北北东向构造带存在的依据和较近时期活动特征。指出该构造带对区内地震孕育、发生及震中分布的控制作用。此外,还讨论了北北东向构造带形成和发展与青藏高原隆起的关系。 相似文献
5.
南海北部陆缘反“S”型构造带及其对地震活动的影响 总被引:3,自引:0,他引:3
通过地形—地貌、断裂构造、地壳结构、中新生代沉积盆地、第四纪地质特征等分析,认为南海北部陆缘存在滨岸岛链、陆坡北缘和陆坡南缘三条反“S”型构造带,它们形成于晚第三纪,较“新华夏系”和“南海系”晚。上新世末期以来,反“S”型构造带的活动方式,对南海北部陆缘第四纪地质特征影响显著,同时控制了这一区域的地震活动方式和地震带展布,其中,“滨海地震带”和“雷琼地震带”同属于滨岸岛链带,“台西滨外地震带”和“东沙—海南地震带”同属于陆坡北缘带。 相似文献
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7.
两郧断裂带是鄂西北地区规模最大、影响最强的断裂之一,位于秦岭断块隆起区,长约200 km,走滑运动性质,第四纪分段活动特征明显,曾于1964年发生过郧西4.9级地震。此前对该断裂郧西段的第四纪活动研究较少,直接影响着对鄂西北地区活动构造变形格局和强震危险性的整体认识和评估。本文基于遥感解译、野外地质调查和高密度电法勘探研究,发现断裂沿线发育有串珠状盆地、负向断层长谷、断层垭口和断层崖等构造地貌形态。两陨断裂在早第四纪活动明显,晚第四纪以来活动微弱,滑动速率低,未来中强地震的危险性不容低估。 相似文献
8.
青藏高原北缘三危山断裂晚更新世活动特征 总被引:1,自引:0,他引:1
三危山断裂位于青藏高原北缘,属于阿尔金断裂带向NW扩展的分支断裂,其最新的构造活动反映了青藏高原北部地区的构造演化及地震活动特征。文中通过遥感影像解译、野外实地调查和地质填图,对该断裂晚第四纪构造活动特征进行了研究。结果表明,三危山断裂发育于三危山西北麓,长约175km,断裂以左旋走滑为主,兼有逆断层性质,局部表现出正断层特征。其构造活动的地貌表现形式主要有:基岩陡坎、断层沟槽以及山包、冲沟左旋等。古地震探槽开挖揭示三危山断裂主要断错晚更新世地层,在距今(40.3±5.2)~(42.1±3.9)ka有过1次古地震活动,为1条晚更新世活动断裂。 相似文献
9.
中国东部中强地震发生的地震地质标志初探 总被引:4,自引:2,他引:2
中国东部地区,尤其是105°~120°E,20°~35°N的中国东南部大陆地区,自有史记载以来,少有7级以上的地震发生,却有不少5~6级左右的中强地震。研究此类中强地震发生的地震地质标志很有必要。对此,经初步分析认为:1)中国东部大多数中强地震发生在早第四纪(早、中更新世)活动断裂带附近;2)中国东部大多数5~6级中强地震都与第四纪断陷盆地的发育、分布有关;3)具有明显第四纪活动的构造地貌特征的地区,如线性断层地貌或地貌面的线性分布区具备孕发中强地震的可能性;4)有历史记载以来4~5级地震活动带的空区或缺震地区,也存在发育5~6级地震的可能性 相似文献
10.
北京拗陷构造活动性分析 总被引:3,自引:0,他引:3
本文据地质历史和构造变形对北京拗陷中、新生代构造演化及新构造运动和断裂活动性作了分析。地质历史分析表明北京拗陷在横向上介于京西隆起和大兴隆起之间的一个中新生代拗陷。在纵向上由几个相间排列的凹陷和凸起组成。中生代沉降中心表现出由北向南迁移,新生代以来则表现出自南向北迁移。从地貌水系所反映的构造运动来看,北京拗陷的中段和南段表现出间歇性均匀抬升性质,北段垂直差异运动明显。断裂活动时间在南段和中段主要为上新世和早更新世;北段活动时间可延续到晚更新世,甚至全新世。北段第四纪时新发育的断陷盆地可能与北西向断层的左旋走滑活动有关。 相似文献
11.
色尔腾山山前断裂得令山以东段属全新世活动断裂。距今约 30ka以来 ,断裂上升盘的平均抬升速率为 :大佘太段 0 19mm/a ,乌兰忽洞段 0 2 0mm/a。探槽揭露 ,大佘太段 ,约 32kaBP以来 ,发生过 4次古地震事件 ,事件发生时间依次为 (316 90± 1770 ) ,(2 30 0 0± 132 0 ) ,(15 42 0± 870 ) ,(74 40± 4 40 )aBP ,相应的位移量分别为 2 6 ,1 6 ,2 2 ,1 4m ;乌兰忽洞段 ,约 2 5kaBP以来 ,也发生过4次古地震事件 ,事件发生时间依次为 (2 5 130± 14 30 ) ,(14 5 70± 82 0 ) ,(116 6 0± 6 5 0 ) ,(72 2 0± 4 0 0 )aBP ,相应的位移量分别为 2 6 ,1 8,1 3,1 2m。根据位移量限定法 ,两个活动段落的古地震活动历史是完整的 相似文献
12.
广东深圳断裂带活动性的第四纪地质和地貌研究 总被引:4,自引:0,他引:4
深圳断裂带分布着一系列第四纪盆地,发育了以晚更新世河流相为主的沉积物,其厚度一般小于10—15米。它们的出现与断裂破碎带、岩溶地层分布及断裂早期活动有关。但是,未见错动了第四纪沉积物的断层。从约180万年以来,断裂带内发育了四级夷平面和三级河流阶地。不同时期地壳相对升降平均速率估计为约0.04毫米/年至0.2毫米/年。 在第四纪地质时期,深圳断裂带总体处于区域性的间歇性抬升过程,断裂活动不明显 相似文献
13.
LATE QUATERNARY ACTIVITY OF THE CENTRAL SEGMENT OF THE DARI FAULT AND RESTUDY OF THE SURFACE RUPTURE ZONE OF THE 1947 M73/4 DARI EARTHQUAKE,QINGHAI PROVINCE 
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下载免费PDF全文 Bayan Hara Block is one of the most representative active blocks resulting from the lateral extrusion of Tibet Plateau since the Cenozoic. Its southern and northern boundary faults are characterized by typical strike-slip shear deformation. Its eastern boundary is blocked by the Yangze block and its horizontal movement is transformed into the vertical movement of the Longmen Shan tectonic belt, leading to the uplift of the Longmen Shan Mountains and forming a grand geomorphic barrier on the eastern margin of the Tibet Plateau. A series of large earthquakes occurred along the boundary faults of the Bayan Hara Block in the past twenty years, which have attracted attention of many scholars. At present, the related studies of active tectonics on Bayan Hara Block are mainly concentrated on the boundary faults, such as Yushu-Ganzi-Xianshuihe Fault, East Kunlun Fault and Longmen Shan Fault. However, there are also some large faults inside the block, which not only have late Quaternary activity, but also have tectonic conditions to produce strong earthquake. These faults divide the Bayan Hara Block into some secondary blocks, and may play important roles in the kinematics and dynamics mechanism of the Bayan Hara Block, or even the eastern margin of the Tibet Plateau. The Dari Fault is one of the left-lateral strike-slip faults in the Bayan Hara Block. The Dari Fault starts at the eastern pass of the Kunlun Mountains, extends eastward through the south of Yalazela, Yeniugou and Keshoutan, the fault strike turns to NNE direction at Angcanggou, then turns to NE direction again at Moba town, Qinghai Province, and the fault ends near Nanmuda town, Sichuan Province, with a total length of more than 500km. The fault has been considered to be a late Quaternary active fault and the 1947 M73/4 Dari earthquake was produced by its middle segment. But studies on the late Quaternary activity of the Dari Fault are still weak. The previous research mainly focused on the investigation of the surface rupture and damages of the 1947 M73/4 Dari earthquake. However, there were different opinions about the scale of the M73/4 earthquake surface rupture zone. Dai Hua-guang(1983)thought that the surface rupture of the earthquake was about 150km long, but Qinghai Earthquake Agency(1984) believed that the length of surface rupture zone was only 58km. Based on interpretation of high-resolution images and field investigations, in this paper, we studied the late Quaternary activity of the Dari Fault and the surface rupture zone of the 1947 Dari earthquake. Late Quaternary activity in the central segment of the Dari Fault is particularly significant. A series of linear tectonic landforms, such as fault trough valley, fault scarps, fault springs and gully offsets, etc. are developed along the Dari Fault. And the surface rupture zone of the 1947 Dari earthquake is still relatively well preserved. We conducted a follow-up field investigation for the surface rupture zone of the 1947 Dari earthquake and found that the surface rupture related to the Dari earthquake starts at Longgen village in Moba town, and ends near the northwest of the Yilonggounao in Jianshe town, with a length of about 70km. The surface rupture is primarily characterized by scarps, compressional ridges, pull-apart basins, landslides, cleavage, and the coseismic offset is about 2~4m determined by a series of offset gullies. The surface rupture zone extends to the northwest of Yilonggounao and becomes ambiguous. It is mainly characterized by a series of linear fault springs along the surface rupture zone. Therefore, we suggest that the surface rupture zone of the 1947 Dari earthquake ends at the northwest of Yilonggounao. In summary, the central segment of the Dari Fault can be characterized by strong late Quaternary activity, and the surface rupture zone of the 1947 Dari earthquake is about 70km long. 相似文献
14.
GEOMORPHOLOGY OF THE GYARING CO FAULT ZONAL DRAINAGE SYSTEM AND ITS STRUCTURAL IMPLICATIONS 下载免费PDF全文
下载免费PDF全文 Strike-slip faults and normal faults are dominant active tectonics in the interior of Tibetan plateau and control a series of basins and lakes showing extension since the Late Cenozoic, by contrast with the thrust faulting along the orogenic belts bordering the plateau. The late Neotectonic movement of those faults is key information to understand the deformation mechanism for Tibetan plateau. The Gyaring Co Fault is a major active right-lateral strike-slip fault striking~300° for a distance of~240km in central Tibet, in south of Bangong-Nujiang suture zone. The Gyaring Co Fault merges with the north-trending Xainza-Dinggye rift near the southern shore of Gyaring Co. From NW to SE, Dongguo Co, Gemang Co-Zhangnai Co, Zigui Co-Gyaring Co form the Gyaring Co fault zonal drainage basin. Some scholars have noticed that the formation of lakes and basins may be related to strike-slip faults and rift, but there is no analysis on the Gyaring Co fault zonal drainage basin and its response to regional tectonics. In recent years, a variety of quantitative geomorphic parameters have been widely used in the neotectonic systems to analyze the characteristics of the basin and its response mechanism to the tectonic movement. In this paper, we applied ASTER GDEM data on the ArcGIS platform, extracted the Gyaring Co fault zonal drainage basin based on Google Earth images (Landsat and GeoEye) and field work. We acquired basic geomorphic parameters of 153 sub-basin (such as grade, relief, average slope, area) and Hypsometric Index (HI) value and curve. Statistical results have indicated significant differences in scale(area and river network grade)in north and south sides of the fault. Southern drainage basins' relief, slope, HI value are higher than the northern basins, and the overall shape of hypsometric curve of northern basins are convex compared with southern concavity. Along the strike of the Gyaring Co Fault, average slope, and HI value are showing generally increasing trending and hypsometric curve become convex from west to east. By comparing and analyzing the lithology and rainfall conditions, we found that they have little influence on the basic parameters and HI value of drainage basins. Therefore, the changes of basin topographic differences between northern and southern side of fault and profile reveal the Gyaring Co Fault has experienced differential uplift since the late Cenozoic, southern side has greater uplift compared to the north side, and the uplift increased from NW to SE, thus indicate that normal faulting of the Gyaring Co Fault may enhanced by the Xainza-Dinggye rift. The early uplift of the Gangdise-Nyainqentanglha Mountain in late Cenozoic might provide northward inclined pre-existing geomorphic surfaces and the later further rapid uplift on the Gangdise-Nyaingentanglha Mountain and Xainza-Dinggye rift might contribute to the asymmetrical development of the Gyaring Co fault zonal drainage basin. 相似文献
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GROWTH STRATA REVEAL THE QUATERNARY TECTONIC FEATURE OF GUDIAN FAULT IN SONGYUAN,SONGLIAO BASIN,CHINA 下载免费PDF全文
下载免费PDF全文 Because of the frequent seismic activity in Songyuan in recent years, the modes of tectonic movement in this area since the Quaternary have attracted increasing consideration. This paper selects the Gudian Fault which locates between the southeast uplift and central depression of Songliao Basin as the research object. We discussed the Quaternary structural characteristics of the Gudian Fault using growth strata. Using the data of deep seismic reflection prospecting for oil, we determined the location, geometry and kinematics characteristics of the Gudian Fault. And using the shallow seismic reflection prospecting data, the combined drilling exploration data and TL data, we determined precisely the inversion tectonics feature of the fault since late Cenozoic. Based on the above data, we believe that the Gudian Fault is dominated mainly by thrust-folding since Quaternary. A set of growth strata is recognized by shallow seismic reflection exploration data. According to the overlap of growth strata and the relationship between deposition rate and uplift rate, we confirm that the uplift rate of Gudian Fault in the early of Early Pleistocene is less than 0.15mm/a. And according to the offlap of growth strata and the relationship between deposition rate and uplift rate, the uplift rate of the Gudian Fault is more than 0.091mm/a in the late of Early Pleistocene and more than 0.052mm/a in middle Pleistocene. According to the chronological data, it is determined that the uplift rate of the Gudian Fault is 0.046mm/y since 205ka. 相似文献
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A NEW DISCOVERY OF ACTIVITY OF FUSHAN SECTION OF THE TAN-LU FAULT ZONE IN THE LATE QUATERNARY 下载免费PDF全文
下载免费PDF全文 ZHAO Peng YAO Da-quan YANG Yuan-yuan ZHENG Hai-gang WANG Xing-zhou XU Hong-tai FANG Zhen 《地震地质》2017,39(5):889-903
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. 相似文献
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USING DEFORMED FLUVIALTERRACES OF THE QINGYIJIANG RIVER TO STUDY THE TECTONIC ACTIVITY OF THE SOUTHERN SEGMENT OF LONGMENSHAN FAULT ZONE 下载免费PDF全文
下载免费PDF全文 On 20 April 2013, a destructive earthquake, the Lushan MS7.0 earthquake, occurred in the southern segment of the Longmenshan Fault zone, the eastern margin of the Tibetan plateau in Sichuan, China. This earthquake did not produce surface rupture zone, and its seismogenic structure is not clear. Due to the lack of Quaternary sediment in the southern segment of the Longmenshan fault zone and the fact that fault outcrops are not obvious, there is a shortage of data concerning the tectonic activity of this region. This paper takes the upper reaches of the Qingyijiang River as the research target, which runs through the Yanjing-Wulong Fault, Dachuan-Shuangshi Fault and Lushan Basin, with an attempt to improve the understanding of the tectonic activity of the southern segment of the Longmenshan fault zone and explore the seismogenic structure of Lushan earthquake.
In the paper, the important morphological features and tectonic evolution of this area were reviewed. Then, field sites were selected to provide profiles of different parts of the Qingyijiang River terraces, and the longitudinal profile of the terraces of the Qingyijiang River in the south segment of the Longmenshan fault zone was reconstructed based on geological interpretation of high-resolution remote sensing images, continuous differential GPS surveying along the terrace surfaces, geomorphic field evidence, and correlation of the fluvial terraces.
The deformed longitudinal profile reveals that the most active tectonics during the late Quaternary in the south segment of the Longmenshan Fault zone are the Yanjing-Wulong Fault and the Longmenshan range front anticline. The vertical thrust rate of the Yanjing-Wulong Fault is nearly 0.6~1.2mm/a in the late Quaternary. The tectonic activity of the Longmenshan range front anticline may be higher than the Yanjing-Wulong Fault. Combined with the relocations of aftershocks and other geophysical data about the Lushan earthquake, we found that the seismogenic structure of the Lushan earthquake is the range front blind thrust and the back thrust fault, and the pop-up structure between the two faults controls the surface deformation of the range front anticline. 相似文献
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龙陵 -澜沧断裂带是一条新生的断裂带 ,由多条斜列式或丛集式次级断层组成 ,以活断层、地震断层、地震成带分布为特征。运动性质为右旋 -拉张。形成时代为早、中更新世 ,晚期继续活动。未来破裂趋势首先将断开那些构造闭锁段、破裂不连续段 ,然后使断裂带完全贯通。新生断裂带的产生与第四纪青藏高原加速隆起有关 ,由北而南滑移的物质流和阿萨姆楔体向东北方向挤入的共同作用 ,使滇缅块体产生反时针旋转 ,并在块体中间地带形成北北西向的新生断裂带 相似文献
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PRELIMINARY STUDY OF PALEOEARTHQUAKES ON THE MIDDLE-EASTERN SEGMENT OF JINTA NANSHAN FAULT 下载免费PDF全文
下载免费PDF全文 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. 相似文献
20.
THRUST OF THE SOUTHERN LONGMENSHAN FAULT IN THE LATE QUATERNARY REVEALED BY RIVER LANDFORMS 下载免费PDF全文
下载免费PDF全文 The Longmenshan fault zone is divided into three sections from south to north in the geometric structure. The middle and northern segments are mainly composed of three thrust faults, where the deformation of foreland is weak. The geometric structure of the southern segment is more complex, which is composed of six fault branches, where the foreland tectonic deformation is very strong. The Wenchuan MS8.0 earthquake occurred in the middle of the Longmenshan in 2008, activating the bifurcation of two branches, the Yingxiu-Beichuan and the Guixian-Jiangyou faults. In 2013, the Lushan MS7.0 earthquake occurred in the southern Longmenshan, whose seismogenic structure was considered to be a blind fault. After the Lushan earthquake, the seismic hazard in the southern Longmenshan has been widely concerned.
At present, the studies on active tectonics in the southern Longmenshan are limited to the Dachuan-Shuangshi and the Yanjing-Wulong faults. The Qingyi River, which flows across the southern Longmenshan, facilitates to study fault slip by the deformation of river terraces. Based on satellite imagery and high-resolution DEM analysis, we measured the fluvial terraces along the Qingyi river in detail. During the measurement, the Sichuan network GPS system (SCGNSS)was employed to achieve a precision of centimeter grade. Besides, the optical luminescence dating (OSL)method was employed to date the terraces' ages. And the late Quaternary activities of the six branch faults in the southern Longmen Shan were further analyzed.
The Gengda-Longdong, Yanjing-Wulong and the Xiao Guanzi faults (west branch of the Dachuan-Shuangshi fault)all show thrust slip and displaced the terrace T2. Their average vertical slip rates in the late Quaternary are 0.21-0.30mm/a, 0.12-0.21mm/a and 0.10-0.12mm/a, respectively. Since the Late Quaternary, vertical slip of the east branch of the Dachuan-Shuangshi fault was not obvious, and the arc-like Jintang tectonic belt was not active. Crustal shortening rate of the southern Longmenshan thrust fault zone in the late Quaternary is 0.48-0.77mm/a, which equals about half of the middle segment of the Longmenshan. Based on the previous study on the tectonic deformation of the foreland, we consider that the foreland fold belt in the southern Longmenshan area has absorbed more than half of the crustal shortening. The three major branch faults in the southern Longmenshan are active in the late Quaternary, which have risk of major earthquakes. 相似文献