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1.
文章详细调查了康西瓦断裂带发育的断层崖、断层陡坎、地震破裂带、错断山脊、拉分盆地、挤压脊、偏心洪积扇、错断水系等新构造运动形迹,这些新构造运动形迹表明了康西瓦断裂带在晚新生代以来发生了强烈的左旋走滑运动,并兼有正滑运动分量。数字地形高程模型(DEM)分析表明康西瓦断裂西端终止于塔什库尔干谷地东部的瓦恰河谷内,东端与著名的阿尔金断裂带相连。如果以喀拉喀什河和玉龙喀什河为参照系,康西瓦断裂晚新生代以来的左旋走滑累积位移量可达 80~85km,根据断裂带 8~12mm/a的长期走滑速率,推测康西瓦断裂带新生代以来的左旋走滑运动开始于约10Ma。结合我们获得的断裂带两侧岩浆岩的年龄,表明康西瓦断裂带左旋走滑运动的开始时代为晚中新世,现今康西瓦地区的构造地貌格局很可能是中新世晚期以来强烈的左旋走滑运动形成的。 相似文献
2.
通过对川滇地体、思茅地体白垩纪、古近纪地层古地磁数据以及新生代地壳构造特征的分析,结合青藏高原东南缘GPS监测研究结果,揭示了新生代时期青藏高原东南缘地壳块体的旋转变形特征.根据古地磁数据模拟计算得出~5Ma以来哀牢山-红河走滑断裂带(ARF)受川滇地体挤压而发生弯曲变形的南北向偏移速率至少为~13.05mm/a,奠边俯左旋走滑断裂带(DBPF)西侧思茅地体内部自~5Ma以来至少存在~2.08mm/a的东西向伸展分量,而DBPF 5Ma以来的南北向平均左旋走滑速度则至少为~1.66mm/a,与现今GPS监测结果基本一致.证明鲜水河-小江左旋走滑断裂带(XXF)的左旋走滑运动虽然没有切断ARF,但是川滇地体的南向顺时针旋转挤压作用导致了断裂带的南向弯曲变形,从而吸收了部分左旋走滑速率,造成左旋走滑运动在跨过ARF传递到DBPF后走滑速率发生了突变,由~10mm/a减小于2~3mm/a.缅泰地块和思茅地体在经历了渐新世-中新世时期以高黎贡山-实楷右旋走滑断裂带和ARF为边界的东南侧向顺时针旋转挤出运动之后,自5Ma开始,至少思茅地体与川滇地体一起,以XXF和DBPF为旋转边界发生了以东喜马拉雅构造节为近似中心的旋转挤出运动. 相似文献
3.
阿尔金断裂系西段——康西瓦断裂的 晚第四纪构造地貌特征研究* 总被引:17,自引:9,他引:17
阿尔金断裂带是青藏高原北部的一条大型左旋走滑断裂带,近EW向延伸2000多公里, 它构成了青藏高原与塔里木盆地之间的重要地质边界。康西瓦断裂位于阿尔金断裂带西段, 呈WNW-ESE向延伸约 700km。文章在高分辨率卫星遥感图像(印度遥感卫星5.8m分辨率)和数字高程地形模型(DEM)数据分析的基础上,并结合野外构造地貌考察观测,对康西瓦断裂的第四纪构造活动及其地貌特征进行了初步研究。沿断裂带发育的系统错断水系、错断冲积扇、挤压脊、走滑拉分盆地等典型构造地貌特征表明,该断裂晚第四纪经历了强烈的左旋走滑活动。同时,研究还揭示沿康西瓦断裂发育了一条长约80km的地表地震破裂带,最大同震左旋水平错位为4m,估算产生该地表破裂带的地震是一矩震级为Mw7.3的大地震。 另外,文章根据不同年代地表地貌特征的左旋错位距离,估算出康西瓦断裂晚第四纪以来的长期走滑速率为8~12mm/a,远低于早期估算的20~30mm/a,但是与阿尔金断裂带中、东段的地质估算结果9±2mm/a及GPS测量结果9±4mm/a接近。 相似文献
4.
青藏高原东南缘晚新生代幕式抬升作用的Ar-Ar热年代学证据 总被引:58,自引:29,他引:58
位于青藏高原东南缘的鲜水河断裂带是一条大型的活动左旋走滑断裂带,对该断裂带进行同位素年代学研究,可以为青藏高原东南部物质迁移和构造隆升历史研究提供时代依据.Ar-Ar热年代学研究表明,鲜水河断裂带在晚新生代持续的左行走滑活动过程中,沿断裂带不同区段发生了显著的差异隆升.以黑云母的Ar同位素体系封闭温度作参照点,鲜水河断裂带北西段、中段、南东段抬升冷却穿过350℃温度点的时间分别为10.39~10.13Ma、5.70~4.42Ma和3.60~3.46Ma.这一研究结果证明青藏高原东南缘在晚新生代以来发生了幕式抬升作用,幕式抬升作用发生的时代分别为~10.1 Ma、5.7~4.4Ma和~3.6Ma. 相似文献
5.
红河断裂带大型右旋走滑运动定量研究的若干问题 总被引:8,自引:0,他引:8
通过卫航片解释、野外地质调查和相关年代学研究与综合前人已有资料分析,阐明了红河断裂带作为一个整体自中新世以来大规模右旋位错的地质依据,论述红河断裂带在几何学、运动学和年代学等方面的基本特征,探讨了红河断裂带后期大规模右旋走滑运动与青藏高原隆升间的某些相关性。研究表明:中新世以来,红河断裂带大规模右旋走滑运动在北段区主要表现为尾端拉张伸展——构成典型的滇西北裂陷盆地区,且自中新世经上新世至第四纪,伸展型盆地由西北向东南扩展;中段区为典型的右旋走滑变形区,燕山晚期花岗岩体、上新世煤盆及礼社江水系均显示为同步右旋位错。上新世以来右旋位错量达30~32km;南段带内由山前水系右旋位错和断裂谷内右旋“撕裂”变形为主要特征。从中新世经上新世至第四纪,与山体快速隆起相伴的断陷盆地有从东南向西北扩展的趋势。根据地质研究结果,并结合区内K-Ar、FT和SEM测年资料分析,可以初步认为,红河断裂带大型右旋走滑运动开始于8~7Ma,强烈活动于5Ma±。 相似文献
6.
西昆仑康西瓦断裂带西延特征及其构造意义 总被引:2,自引:0,他引:2
青藏高原西北部康西瓦走滑断裂带(Karakax fault)为一条经过长期演化且现今仍在活动的重要大型断裂带,该断裂对该地区形成演化起到至关重要的控制作用。目前大多学者们认为该断裂在东段沿喀拉喀什河谷大致呈东西走向延伸,后在其西段麻扎地区向北西方向延伸。然而,通过详细的野外地质调查在该断裂带西段的麻扎地区新发现了一条NEE-SWW向的断裂,将之命名为麻塔断裂。实测地质剖面和显微构造分析发现麻塔断裂与康西瓦断裂具有相似的几何学和运动学特征,同样经历了早期右旋逆冲的韧性走滑变形和后期左旋脆性走滑变形,理应划分为一条断裂,前者是后者自麻扎向西的延伸部分。麻塔-康西瓦断裂共同参与调节了自古生代以来板块碰撞拼合在青藏高原西北部的构造变形,现今西昆仑-帕米尔地区的构造地貌格局正是康西瓦和喀喇昆仑等大型断裂新生代活动而形成的。 相似文献
7.
鲜水河断裂带渐新世至早中新世两期变形相关混合岩的锆石U - Pb年代学及其意义 总被引:1,自引:0,他引:1
鲜水河断裂带是青藏高原东缘重要的走滑断裂带。沿该断裂带发育长约120 km、宽约3~5 km的混合岩。运动学和年代学资料表明其与鲜水河断裂带渐新世至早中新世的两期变形有关。第一期变形发生在32~27 Ma,混合岩显微构造显示强烈压扁机制,反映了沿鲜水河断裂带的挤压变形机制。第二期混合岩中两个淡色体的样品获得了25.06 Ma和20.9 Ma的锆石U Pb年龄,限定混合岩化的时间约为25~20 Ma。这期混合岩以发育左行走滑的矿物生长线理为特征,反映了走滑的应力体制。与这期混合岩密切相关的5块花岗岩样品均获得了20~19 Ma的锆石U Pb年龄,代表了混合岩化作用的结束。两期混合岩的发现限定了鲜水河断裂带新生代由挤压体制到左行走滑体制的转变,也即鲜水河断裂带新生代走滑起始时间27~25 Ma。该发现对于认识青藏高原东缘新生代的构造变形过程具有重要意义。 相似文献
8.
阿尔金断裂带对青藏高原北部生长、隆升的制约 总被引:59,自引:3,他引:59
大量的同位素年代学证据表明(古)阿尔金断裂带可能形成于三叠纪,后又经历了侏罗纪、白垩纪的强烈左旋走滑活动,自印度板块与欧亚大陆碰撞后阿尔金断裂再次活动。主要的走滑活动发生在:(1)245~220Ma;(2)180~140Ma;(3)120~100Ma;(4)90~80Ma;(5)60~45Ma;(6)渐新世至中新世;(7)上新世至更新世以及(8)全新世。沿阿尔金断裂带,伴随左旋走滑活动形成一系列的逆冲断裂和正断裂,反映走滑过程中伴随隆升作用的存在,并且形成自北向南包括祁连山、大雪山、党河南山、柴北缘山、祁漫塔格山和昆仑山,表明阿尔金断裂带制约着青藏高原北部的生长和隆升。阿尔金断裂带东、西两端的白垩纪和新生代火山活动是断裂走滑活动的响应。 相似文献
9.
通过卫航片解释、野外地质调查和相关年代学研究与综合前人已有资料分析,阐明了红河断裂带作为一个整体自中新世以来大规模右旋位错的地质依据,论述红河断裂带在几何学、运动学和年代学等方面的基本特征,探讨了红河断裂带后期大规模右旋走滑运动与青藏高原隆升间的某些相关性。研究表明:中新世以来,红河断裂带大规模右旋走滑运动在北段区主要表现为尾端拉张伸展---构成典型的滇西北裂陷盆地区,且自中新世经上新世至第四纪,伸展型盆地由西北向东南扩展;中段区为典型的右旋走滑变形区,燕山晚期花岗岩体、上新世煤盆及礼社江水系均显示为同步右旋位错。上新世以来右旋位错量达30~32km;南段带内由山前水系右旋位错和断裂谷内右旋"撕裂"变形为主要特征。从中新世经上新世至第四纪,与山体快速隆起相伴的断陷盆地有从东南向西北扩展的趋势。根据地质研究结果,并结合区内 K Ar、FT和SEM测年资料分析,可以初步认为,红河断裂带大型右旋走滑运动开始于 8~7Ma,强烈活动于5Ma±。 相似文献
10.
鲜水河-小江左旋走滑断裂系是调节青藏高原东南部物质向东南挤出的大型边界断裂。云南巧家断裂作为小江断裂带北段,其晚第四纪走滑速率是认识川滇地块东部边界应变调节方式的关键。本文利用无人机航摄和地面激光扫描技术,获取了该断裂段穿过金沙江河谷区红路和蒙姑两处的高分辨率地形数据,恢复出断层错动T2和T3两期阶地陡坎上缘的左旋位错量分别为120±5~128±1 m和193±1~202±1 m。根据T3中次生碳酸盐的AMS-14C法测年结果,结合已有的类似阶地年龄数据,并经气候曲线校正后认为,区域上T2和T3被废弃应分别发生在冰后期和末次盛冰期末期,时间为8.5~11.2 ka BP和18.6~21.4 ka BP。据此估算,小江断裂带巧家段的晚第四纪平均走滑速率为10~13 mm/a。进一步统计分析小江断裂带的晚第四纪走滑速率,发现巧家至宜良以北的段落,总体保持着10~15 mm/a的高走滑速率。但从宜良向南,断裂走滑速率出现了分段递减的特征,至建水以南快速减小到中-北段的近十分之一。小江断裂带中-北段的高走滑速率以及向南的分段式递减现象,反映在宜良以北,小江断裂带的走滑剪切... 相似文献
11.
《International Geology Review》2012,54(9):991-1012
The active kinematics of the eastern Tibetan Plateau are characterized by the southeastward movement of a major tectonic unit, the Chuan-Dian crustal fragment, bounded by the left-lateral Xianshuihe–Xiaojiang fault in the northeast and the right-lateral Red River–Ailao Shan shear zone in the southwest. Our field structural and geomorphic observations define two sets of young, active strike–slip faults within the northern part of the fragment that lie within the SE Tibetan Plateau. One set trends NE–SW with right-lateral displacement and includes the Jiulong, Batang, and Derong faults. The second set trends NW–SE with left-lateral displacement and includes the Xianshuihe, Litang, Xiangcheng, Zhongdian, and Xuebo faults. Strike–slip displacements along these faults were established by the deflection and offset of streams and various lithologic units; these offsets yield an average magnitude of right- and left-lateral displacements of ~15–35 km. Using 5.7–3.5 Ma as the time of onset of the late-stage evolution of the Xianshuihe fault and the regional stream incision within this part of the plateau as a proxy for the initiation age of conjugate strike–slip faulting, we have determined an average slip rate of ~2.6–9.4 mm/year. These two sets of strike–slip faults intersect at an obtuse angle that ranges from 100° to 140° facing east and west; the fault sets define a conjugate strike–slip pattern that expresses internal E–W shortening in the northern part of the Chuan-Dian crustal fragment. These conjugate faults are interpreted to have experienced clockwise and counterclockwise rotations of up to 20°. The presence of this conjugate fault system demonstrates that this part of the Tibetan Plateau is undergoing not only southward movement, but also E–W shortening and N–S lengthening due to convergence between the Sichuan Basin and the eastern Himalayan syntaxis. 相似文献
12.
《Journal of Asian Earth Sciences》2007,29(2-3):253-265
The E-W to WNW-ESE striking Kunlun Fault Zone, extending about 1600 km, is one of the large strike-slip faults in the northern Tibet, China. As a major strike-slip fault, it plays an important role on the extrusion of Tibet Plateau in accommodating northeastward shortening caused by the India-Asia convergence. However, the time of initiation left-lateral faulting of the Kunlun Fault Zone is still largely debated, ranging from the Middle to Late Triassic (240–200 Ma) to early Quaternary (2 Ma). We document displaced basement rocks and geomorphic features along the Kunlun Fault Zone, based on tectono-geomorphic interpretation of satellite remote sensing images and field geologic and geomorphic observations. Our results show that the largest cumulative offset of basement rocks is likely to be 100 ± 20 km. Meanwhile, a series of pull-apart basins (Kusai, Xiugou and Tuosu lake basins) and pressure ridges (East Deshuiwai and Maji Snow Mountains), each 45–70 km long and ∼8–12 km wide, are developed along the Kunlun Fault Zone, which resulted from long-term tectono-geomorphic growth since the Late Miocene or Early Pliocene. Geologic evidence indicates that the Kunlun Fault Zone had a long-term slip rate of ca.10 mm/yr during the late Quaternary. This slip rate is similar to that shown by present-day GPS measurements. Thus, we estimate that the Kunlun Fault Zone probably began left-lateral faulting at 10 ± 2 Ma based on a total displacement of 100 ± 20 km, and assuming a constant long-term slip rate of ca.10 mm/yr for several millions of years. And this timing constraint on initiation of left-lateral faulting of the Kunlun Fault Zone is consistent with widespread tectonic deformation which occurred in the Tibetan Plateau. 相似文献
13.
Active Faulting Pattern,Present‐day Tectonic Stress Field and Block Kinematics in the East Tibetan Plateau 总被引:9,自引:1,他引:8
Abstract: This paper examines major active faults and the present-day tectonic stress field in the East Tibetan Plateau by integrating available data from published literature and proposes a block kinematics model of the region. It shows that the East Tibetan Plateau is dominated by strike-slip and reverse faulting stress regimes and that the maximum horizontal stress is roughly consistent with the contemporary velocity field, except for the west Qinling range where it parallels the striking of the major strike-slip faults. Active tectonics in the East Tibetan Plateau is characterized by three faulting systems. The left-slip Kunlun-Qinling faulting system combines the east Kunlun fault zone, sinistral oblique reverse faults along the Minshan range and two major NEE-striking faults cutting the west Qinling range, which accommodates eastward motion, at 10–14 mm/a, of the Chuan-Qing block. The left-slip Xianshuihe faulting system accommodated clockwise rotation of the Chuan-Dian block. The Longmenshan thrust faulting system forms the eastern margin of the East Tibetan Plateau and has been propagated to the SW of the Sichuan basin. Crustal shortening across the Longmenshan range seems low (2–4 mm/a) and absorbed only a small part of the eastward motion of the Chuan-Qing block. Most of this eastward motion has been transmitted to South China, which is moving SEE-ward at 7–9 mm/a. It is suggested from geophysical data interpretation that the crust and lithosphere of the East Tibetan Plateau is considerably thickened and rheologically layered. The upper crust seems to be decoupled from the lower crust through a décollement zone at a depth of 15–20 km, which involved the Longmenshan fault belt and propagated eastward to the SW of the Sichuan basin. The Wenchuan earthquake was just formed at the bifurcated point of this décollement system. A rheological boundary should exist beneath the Longmenshan fault belt where the lower crust of the East Tibetan Plateau and the lithospheric mantle of the Yangze block are juxtaposed. 相似文献
14.
RESEARCH PROGRESS OF ALTYN FAULT IN WESTERN CHINA 总被引:2,自引:0,他引:2
RESEARCH PROGRESS OF ALTYN FAULT IN WESTERN CHINATheresearchisfundedbyNSFC (No.4 9772 157) 相似文献
15.
Two Phases of Cenozoic Deformation in Northeastern Tibet: Thrusting Followed by Strike-Slip Faulting 总被引:1,自引:0,他引:1
TWO PHASES OF CENOZOIC DEFORMATION IN NORTHEASTERN TIBET: THRUSTING FOLLOWED BY STRIKE-SLIP FAULTING 相似文献
16.
Wang Xiaofeng Yin An Peter Rumelhart Eric Cowgill Chen Xuanhua Chen Zhengle T.Mark Harrison Zhang Yueqiao Zhang Qing Zhou Xianqiang WT ”BX 《地学前缘》2000,(Z1)
THE FORMATION AND EVOLUTION OF ALTYN TAGH FAULT SYSTEM AND ITS RELATIONSHIP TO THE GROWTH OF TIBETAN PLATEAUtheNational(G19980 4 0 80 0 )andthefundofOpeningLaboratoriesofGeomechanics 相似文献
17.
塔里木盆地西部的新生代断裂活动 总被引:1,自引:0,他引:1
研究区以塔里木盆地西部的巴楚隆起为核心,包括其南侧的麦盖提斜坡和北侧的北部坳陷(阿瓦提凹陷)。这里新生代断裂异常发育。以鸟山-古董山地区为重点,通过精细的地震剖面解释,在塔里木盆地西部识别出5期新生代断裂活动,分别发生于:白垩纪末-古近纪初(ca.65Ma)、中新世末-上新世初(ca.5Ma)、上新世末-更新世中期(ca.3~1.5Ma)、更新世中-晚期(ca.1~0.1Ma)和全新世(ca.0.01Ma)。中寒武统和古近系膏盐层构成了研究区的2个主滑脱面。ca.65Ma的冲断受控于基墨里中间大陆与亚洲大陆碰撞的远程效应;ca.5Ma、ca.3~1.5Ma、ca.1~0.1Ma和ca.0.01Ma的断裂活动(包括滑脱断层、冲断层、走滑断层和正断层)均受控于印度-亚洲碰撞的远程效应。晚新生代(中新世以来)的断裂活动以脉动式冲断为特征,两次相邻脉动式冲断之间为时间不等的短暂的构造间歇期;间歇期构造平静,甚至可以形成正断层。 相似文献