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1.
川西及其邻近地区位于青藏高原东缘川滇、巴颜喀拉和华南三大活动块体的交接部位,发育着多组具有发震能力的活动断裂。由于横向次级活动断裂的存在,川滇块体可进一步划分为滇中和川西北2个次级块体,巴颜喀拉块体可划分出东端的龙门山次级块体。深部探测反映出川滇和巴颜喀拉块体地壳中均存在着低速-高导层(体),它们是上地壳多震的原因之一。地质研究和现今GPS观测表明:各级块体均存在着SE向或SSE向平移运动、顺时针转动和隆升运动,但量值存在着一定差异。文中还给出了各主要活动断裂带的地质或GPS滑动速率,讨论了目前存在的主要科学问题 相似文献
2.
川滇地区活动块体最新构造变动样式及其动力来源 总被引:86,自引:6,他引:86
基于“活动块体”的基本概念,综合历史地表破裂型地震的空间分布、主干活动断裂和次级活动断裂的展布特征等,川滇地区可划分出4个一级块体:马尔康块体(Ⅰ)、川滇菱形块体(Ⅱ)、保山-普洱块体(Ⅲ)和密支那-西盟块体(Ⅳ)等;受次级北东向断裂的切割,川滇菱形块体(Ⅱ)可进一步划分为川西北(Ⅱ_1)和滇中(Ⅱ_2)2个次级块体,保山-普洱块体(Ⅲ)包括保山、景谷和勐腊等3个次级块体(Ⅲ_1,Ⅲ_2,Ⅲ_3)。通过断错地貌学的定量研究,厘定了川滇地区各级块体主干边界活动断裂的基本类型和长期滑动速率值;运用矢量分析的方法确定了块体的运动状态,并讨论了变形协调性问题,指出川滇地区各级块体运动是平移、转动和隆升等3种基本运动的复合或叠加,其中马尔康块体、川西北和滇中两个次级块体南东向或南南东向平移速率1~5mm/a,顺时针转动角速率1.4~4°/Ma,隆升速率1mm/a左右;保山-普洱和密支那-西盟两块体也发生过大规模的顺时针转动.它们是印度板块与欧亚板块碰撞、印度板块北移引起板块边缘或内部变形局部化和差异运动的应交响应。由于存在横向活动逆断裂带对东向或南东向平移分量的吸收和转换,青藏高原物质的向东逃逸量或挤出量是有限的,为“叠瓦状道冲转换-有限挤出模型”。 相似文献
3.
通过分析中国地壳运动观测网络的GPS数据得到川滇地区地壳水平运动速度场 ,由此划分活动块体并分析其运动特征。结果表明 :相对欧亚板块 ,滇中、雅江和中甸次级块体的顺时针转动速率分别为 0 37°± 0 16°/Ma ,0 84°± 0 39°/Ma和 0 90°± 0 39°/Ma ,造成块体间跨木里弧形断裂带约 3mm/a的SN向挤压、丽江 -大理断裂带约 4mm/a的EW向拉张和理塘断裂带约 6mm/a的近EW向拉张。鲜水河断裂带左旋走滑速率 8~ 10mm/a ,安宁河 -则木河 -小江断裂带左旋走滑 5~6mm/a。龙门山断裂带没有明显的地壳消减 ,而断裂带西北约 15 0km处有一形变速度阶跃带 ,右旋走滑速率 4~ 5mm/a。阶跃带两侧的岷山块体和阿坝地区逆时针转动速率分别为 0 13°± 0 0 8°/Ma和0 5 3°± 0 19°/Ma。鲜水河 -小江断裂带以南、以西地区 ,青藏高原物质的E向挤出和重力滑塌造成川滇块体东移 ,在东部相对稳定的华南地块的阻挡下 ,川滇块体沿鲜水河 -小江断裂带由东转向南运动 ,从而引起川滇块体内部各次级块体的顺时针转动 相似文献
4.
利用川滇地区1998~2002年间200多GPS点位的多期复测结果, 将川滇地区分为9个次级活动块体, 计算了各个活动块体的欧拉旋转矢量和主要活动断裂的运动速度, 并分析了该地区的应变场特征. 结果表明, 川滇地区的地壳运动速度具有北强南弱、西强东弱、以菱形块体为主顺时针旋转的特征; 菱形块体外各个块体运动速度大幅衰减; 与地质结果的差异表明, 川滇菱形块体的现今地壳运动由北往南逐渐增强; 青藏高原物质的侧东向挤出在滇中块体南部明显下降, 而丽江—小金河断裂带的吸收作用并不明显; 川滇地区以压应变为主,四川石棉和云南新平一带出现的应变集中地区也许具有发生中强地震的可能性. 相似文献
5.
基于川滇地区活动块体划分及断裂构造现有认知,文中构建了包含块体主要边界断裂的二维有限元接触模型,利用1991—2015年长期GPS观测结果,采用"块体加载"方法模拟块体边界带现今的运动,得到了断裂滑动速率和应力分布.结合震源机制解、地震活动性等资料,对川滇地区大型左旋走滑断裂带滑动速率分配、传递与应力转换的关联,局部区域正断型震源机制解的构造机制以及红河断裂南、北段地震活动性差异的可能成因进行了初步探讨.主要结论包括:1)东昆仑断裂带和鲜水河-小江断裂带的左旋走滑由NW向转变为近SN向,断裂强烈转折区吸收了部分走滑分量并转化为应变积累,呈高应力分布特征.2)受小江断裂左旋剪切的影响,红河断裂中南段以右旋走滑兼微弱挤压运动为主,并牵引断裂北段右旋走滑,与金沙江和德钦-中甸断裂共同构成右阶斜列右旋剪切变形带,正断型震源机制解多分布于该变形带的构造拉分区内.3)红河断裂中南段为弱压性,北段呈弱张性,更易破裂,地震活动明显强于中南段. 相似文献
6.
川滇块体北-东边界活动构造带运动学转换与变形分解作用 总被引:7,自引:4,他引:3
青藏高原周缘活动构造带的定量运动学研究对于理解整个高原演化是一项基础性工作。利用数字摄影测量技术和区域气候-地貌-构造对比分析的年代学方法,获取了川滇块体北-东边界活动构造带内主要断裂的运动学定量数据,发现多个断裂段作为走滑活动为主的断裂在局部存在中心对称的倾向滑动分量。据矢量分析方法,将川滇块体北-东边界活动构造带及其相邻块体作为一个区域性构造系统,利用构造带内主要断裂的运动学定量数据,分析了构造带横向上的构造运动学转换关系和纵向上的变形分解作用,确定出贡嘎山隆起区存在6·2mm/a的具有透入分布式的垂直隆升速率、安宁河谷东侧台地内侧存在倾滑速率至少1·45mm/a、以逆冲为主的活动断裂。定量地建立了川滇块体北-东边界构造转折带和东边界构造带的变形分解模式,进而建立了川滇块体北-东边界活动构造带及其相邻块体组成的区域性构造系统的定量运动学模型 相似文献
7.
基于GPS的云南地区活动地块现今运动及应变特征分析 总被引:2,自引:0,他引:2
利用GAMIT/GLOBK软件,对云南境内以及川滇交界区域2009年、2011年、2013年3期陆态网络区域网联测数据进行处理,得到欧亚框架下的测站运动速度场。将云南地区划分为4个活动地块及7个次级构造单元,以GPS速度场为约束,建立块体的整体旋转与均匀应变模型(REHSM),采用最小二乘法,得到华南、滇东、滇中、川滇菱块南段、印支、保山及腾冲地块的运动速度。对活动块体运动进行分析,认为云南地块运动方向由SSE向逐渐至SSW向变化,具有顺时针旋转特征,运动幅度由西向东、由北向南逐渐减弱,菱形块体外各块体运动速度大幅衰减。从应变率参数结果看,华南地块、滇东块体主要受SE向压应力场控制,到滇中地块转为SE—SSE向,滇西北地区应力场方向为SSE向,滇西南印支地块为NNW向,滇西南腾冲—保山地块主要受NE—NNE向应力场控制。 相似文献
8.
基于2009年以来的GPS观测数据,利用块体模型和GPS剖面方法分别计算川滇块体东边界主要断裂带的滑动速度,并结合跨断裂带的区域应变时间序列分析断裂带现今的运动特征。结果表明:从速度场变化来看,2013—2015期的速度场在川滇块体东北部有东向增加的微弱变化;从滑动速率结果来看,鲜水河北段的左旋走滑运动有所增强,拉张运动有所增加;小江断裂带的左旋走滑运动普遍有微弱的增强;从去掉线性的区域应变时间序列结果来看,小江断裂带南段主张应变在2014年底出现了趋势性转折,值得进一步关注。 相似文献
9.
大凉山次级块体内强震发生的构造特征与2014年鲁甸6.5级地震对周边断层的影响 总被引:4,自引:3,他引:1
2014年8月3日,在云南鲁甸发生MS6.5地震.该地震位于巴颜喀拉块体、川滇块体与华南块体三者之间的以挤压和左旋走滑为主要活动特征的大凉山次级块体内部.该次级块体吸收了来自川滇块体和巴颜喀拉块体的挤压作用,主要以各边界断裂带的挤压作用和内部大凉山断裂带、峨边断裂带等NNW向的左旋走滑次级断裂为主要特征;在历史上大凉山次级块体边界上以7级以上强震活动为主要特征,而在次级块体内部则以5级地震频繁活动为主.2014年鲁甸MS6.5地震发生在逆冲走滑断裂带内部的NNW向左旋走滑断裂上,该地震主要受到了发生在小江断裂带上的1733年M73/4和则木河断裂带上的1850年M71/2强震的影响,这两次地震对2014年鲁甸MS6.5地震有促进作用,而2014年鲁甸6.5级地震促进了2014年10月1日越西5.0级地震的发生,此外鲁甸地震对大凉山断裂带北段、峨边断裂带、昭通-鲁甸断裂带东段以及则木河断裂带南段有一定的库仑应力增强作用. 相似文献
10.
基于活动块体的基本概念,综合对研究区内活动断裂带空间展布、地震活动性等资料的分析将巴颜喀拉块体东部及邻区划分为巴颜喀拉块体(I)、华南块体(Ⅱ)、川滇块体(Ⅲ)和西秦岭块体(IV)等4个一级块体.利用GPS形变场、地球物理场等资料结合F检验法,将巴颜喀拉块体划分为阿坝(I1)、马尔康(I2)和龙门山(I3)3个次级块体,将西秦岭块体划分为岷县(IV1)和礼县(IV2) 2个次级块体.利用分布在各个块体内部的GPS测站,计算各活动块体及块体边界断裂带的运动变形特征.结果表明:各活动块体的整体运动包括平移和旋转运动;东昆仑断裂带、甘孜—玉树断裂带和鲜水河断裂带的滑动速率明显高于龙门山断裂带的滑动速率;巴颜喀拉块体东部走向北西或北西西的边界断裂表现出左旋拉张的特性;走向北东的边界断裂带,除成县—太白断裂带外,均表现出右旋走滑兼挤压的活动特征.巴颜喀拉块体的东向运动存在自西向东的速度衰减,衰减主要被龙日坝断裂带和岷江断裂带分解吸收,其中龙日坝断裂带的水平右旋分解非常明显,约为~4.8±1.6 mm/a,岷江断裂带的水平分解较弱.龙门山断裂带被马尔康、龙门山和岷县等次级块体分成南、中、北三段,龙门山断裂带中段上的主压应变率要明显小于龙门山断裂带南段上的应变率,其北西侧变形幅度从远离断裂带较大到靠近断裂带逐渐减小,表明其在震前已经积累了较高的应变能,有利于发生破裂滑动.汶川地震后,地表破裂带和余震分布揭示的断裂带运动性质自南西向北东由以逆冲运动为主,逐渐转为逆冲兼走滑的特征可能与龙门山断裂带中段所受主压应力方向自南西向北东的变化有关.马尔康、龙门山和岷县3个次级块体与华南块体之间较低的相对运动速度以及龙门山断裂带低应变率、强闭锁的特征都决定了汶川地震前龙门山断裂带低滑动速率的运动特征. 相似文献
11.
CHANGES IN FAULT MOVEMENT PROPERTY AND GENETIC MECHANISM ON THE WESTERN SEGMENT OF THE XIANGSHAN-TIANJINGSHAN FAULT ZONE 
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下载免费PDF全文 The Xiangshan-Tianjingshan fault zone is an important part of the arc tectonic zone in northeastern Tibet, whose eastern segment is characterized by primarily left-lateral slip along with thrust component. In contrast, the fault movement property on the western segment of the Xiangshan-Tianjingshan fault zone is more complicated. According to the offset geomorphic features and cross sections revealed by the trenches and outcrops, the western segment is mainly a left-lateral strike-slip fault with normal component, and only accompanied with reverse component at specific positions. To determine the genetic mechanism of fault movement property on the western segment, we obtained three main factors based on the integrated analysis of fault geometry:(1)Step-overs:the left-stepping parallel faults in a sinistral shear zone create extensional step-overs and control the nearby and internal fault movement property; (2)terminal structures:they are conductive to stop rupture propagation and produce compressive deformation at the end of the fault trace; and(3)double bends:strike-slip faults have trace that bends such that slip between two adjacent blocks creates a compressive stress and thrust fault. Additionally, the Tianjingshan sub-block moves to SEE and creates an extensional stress at the end of the sub-block associated with normal faults. It shows that the Xiangshan-Tianjingshan fault zone has a complex evolution history, which is divided into two distinctive periods and characterized by laterally westward propagating. 相似文献
12.
Fault plane solutions in Sichuan-Yunnan rhombic block and their dynamic implications 总被引:1,自引:1,他引:1
Harvard Centroid Moment Tensor (CMT) solutions for earthquakes from 1977 to 2004 showed that the stress fields are obviously different in northwestern Sichuan sub-block (NWSSB), western parts of Central Yunnan sub-block (CYSB) and eastern part of CYSB. The characteristics of the mean stress fields in these three regions are obtained by fitting to CMT solutions. The stress state in NWSSB is characterized by its sub-horizontal tensile principal axis of stress (T axis) in roughly N-S direction and west dipping compressive principal axis of stress (P axis); the one in western part of CYSB is characterized by its ENE dipping T axis and sub-horizontal medium prin-cipal axis of stress (B axis) in roughly N-S direction; the one in eastern part of CYSB is characterized by its sub-horizontal P axis in roughly NNW-SSE direction and sub-horizontal T axis in roughly WSW-ENE direction. Finite element method simulation clearly shows that the Indian Plate imposes great extrusion on Sichuan-Yunnan rhombic block (SYRB) near Assam massif. The value of the simulated compressive principal stress decreases with the distance from Assam massif. The simulated directions of the T axes in SYRB form annular distribution encir-cling Assam. For a homogeneous elastic medium with free boundary conditions on the top and bottom surfaces as well as the displacement boundary conditions derived from the GPS observations on the lateral boundaries, the computation results are consistent with the Harvard CMT solutions in NWSSB and western part of CYSB, while inconsistent with the Harvard CMT solutions in eastern part of CYSB. The inconsistency in eastern part of CYSB can be reduced when it includes inhomogeneous elastic media. The stress states in NWSSB and western part of CYSB revealed by the Harvard CMT solutions are not local, which are mainly controlled by the boundary force on the whole region. On the other hand, the stress state in eastern part of CYSB given by the Harvard CMT solutions is local, which may be affected by local topography, material inhomogeneity, and the drag force underneath. 相似文献
13.
阿尔泰构造带的活动断裂主要为NW—NNW向。按构造位置可分为阿尔泰西缘活动断裂带、阿尔泰中央活动断裂带和阿尔泰东缘活动断裂带。阿尔泰东缘活动构造带由科布多(Hovd)活动断裂带、哈尔乌苏湖(Har Us)活动断裂带2条大型右旋走滑活动断裂和中间的挤压盆地带构成。在2条走滑断裂带上,前人发现多处地震地表破裂带。通过对阿尔泰东缘构造带中南段地区的野外调查,在哈尔乌苏湖断裂带中段的Jargalant断裂、科布多断裂带南段的Tugen gol断裂上新发现地震地表破裂带。其中,沿Jargalant断裂地震地表破裂带长约50km,右旋位错量约4~5m,是一次规模大、活动较新的破裂事件。可见,在阿尔泰东缘活动断裂带的不同断裂段上均有保存较好的地震地表破裂,显示阿尔泰东缘是活动强烈的地震构造带 相似文献
14.
Discovery of the Longriba fault zone in eastern Bayan Har block,China and its tectonic implication 总被引:20,自引:0,他引:20
Re-measured GPS data have recently revealed that a broad NE trending dextral shear zone exists in the eastern Bayan Har block about 200 km northwest of the Longmenshan thrust on the eastern margin of the Qinghai-Tibet Plateau. The strain rate along this shear zone may reach up to 4-6 mm/a. Our interpretation of satellite images and field observations indicate that this dextral shear zone corresponds to a newly generated NE trending Longriba fault zone that has been ignored before. The northeast segment of the Longriba fault zone consists of two subparallel N54°±5°E trending branch faults about 30 km apart, and late Quaternary offset landforms are well developed along the strands of these two branch faults. The northern branch fault, the Longriqu fault, has relatively large reverse component, while the southern branch fault, the Maoergai fault, is a pure right-lateral strike slip fault. According to vector synthesizing principle, the average right-lateral strike slip rate along the Longriba fault zone in the late Quaternary is calculated to be 5.4±2.0 mm/a, the vertical slip rate to be 0.7 mm/a, and the rate of crustal shortening to be 0.55 mm/a. The discovery of the Longriba fault zone may provide a new insight into the tectonics and dynamics of the eastern margin of the Qinghai-Tibet Plateau. Taken the Longriba fault zone as a boundary, the Bayan Har block is divided into two sub-blocks: the Ahba sub-block in the west and the Longmenshan sub-block in the east. The shortening and uplifting of the Longmenshan sub-block as a whole reflects that both the Longmenshan thrust and Longriba fault zone are subordinated to a back propagated nappe tectonic system that was formed during the southeastward motion of the Bayan Har block owing to intense resistance of the South China block. This nappe tectonic system has become a boundary tectonic type of an active block supporting crustal deformation along the eastern margin of the Qinghai-Tibet Plateau from late Cenozoic till now. The Longriba fault zone is just an active fault zone newly-generated in late Quaternary along this tectonic system. 相似文献
15.
美国哈佛大学1977——2004年的矩心矩张量结果显示, 我国川西北次级地块、 滇中次级地块的西部及滇中次级地块的东部的应力场特征有明显的差别. 应用滑动矢量拟合法, 反演了这三个区域的应力场特征: 川西北次级地块以近南北向的水平主张应力轴和西倾的主压应力轴为特征; 滇中次级地块的西部以倾向北东东的主张应力轴以及近南北的水平中等主应力轴为特征; 滇中次级地块的东部以南西西——北东东向的水平主张应力轴以及北北西——南南东向的水平主压应力轴为特征. 有限元模拟结果清楚地显示出, 川滇地块在阿萨姆楔附近受到来自印度板块的强烈挤压, 随着远离阿萨姆楔, 这种挤压应力逐渐衰减; 同时, 该地区的主张应力方向明显地形成了围绕阿萨姆楔的环线. 其中, 内部物质性质均匀、 地表和底部边界自由、 侧部边界采用GPS观测约束的弹性有限元模拟显示, 在川西北次级地块, 模拟结果与震源机制解结果相一致; 在滇中次级地块, 模拟结果所显示的图象与震源机制解观测结果有差别, 不仅没有显示出与大面积的东部地区的震源机制解相一致的特征, 反而显示出与该地区西部震源机制解相一致的特征. 通过调节地块内部物质的弹性常数, 可以实现在滇中次级地块东部部分地区出现与震源机制 相似文献
16.
利用浅地层剖面仪对郯庐断裂带莱州湾段进行了活断层探测,发现郯庐断裂带主干断裂在第四纪晚期以来具有明显的活动,继承了晚第三纪以来的主要构造活动特点,仍是这一区域的主导性构造. 西支KL3断裂由多条高角度正断裂组成,最新活动时代为晚更新世晚期至全新世早期,受到一系列错断晚更新世晚期沉积的北东或近东西向断裂的切割;东支龙口断裂由两段右阶斜列的次级断层组成,沿断裂带不但有明显的晚第四纪断错活动,而且还发育北北东向晚第四纪生长褶皱,表现出明显的晚更新世晚期至全新世活动特征. 在山东陆地区也发现了与龙口断裂相对应的安丘——莒县断裂,安丘段由一系列右阶斜列的次级断层组成. 从安丘向北至莱州湾凹陷,郯庐断裂带东支活断层构成了一条右旋单剪变形带,每一个次级活断层段相当于带内理论上次级压剪面,在第四纪晚期以来仍以右旋走滑活动为主要特征. 相似文献
17.
The definition of active block is given from the angles of crustal deformation and strain. The movement and strain parameters of active blocks are estimated according to the unified velocity field composed of the velocities at 1598 GPS stations obtained from GPS measurements carried out in the past years in the Chinese mainland and the surrounding areas. The movement and strain conditions of the blocks are analyzed. The active blocks in the Chinese mainland have a consistent E-trending movement component, but its N and S components are not consistent. The blocks in the western part have a consistent N-trending movement and the blocks in the eastern part have a consistent S-trending movement. In the area to the east of 90°E, that is the area from Himalayas block towards NE, the movement direction of the blocks rotates clockwisely and the movement rates of the blocks are different. Generally, the movement rate is large in the west and south and small in the east and north with a difference of 3 to 4 times between the rates in the west and east. The distributions of principal compressive strain directions of the blocks are also different. The principal strain of the blocks located to the west of 90oE is basically in the SN direction, the principal compressive strain of the blocks in the northeastern part of Qingzang plateau is roughly in the NE direction and the direction of principal compressive strain of the blocks in the southeastern part of Qingzang plateau rounds clockwisely the east end of Himalayas structure. In addition, the principal strain and shear strain rates of the blocks are also different. The Himalayas and Tianshan blocks have the largest principal compressive strain and the maximum shear strain rate. Then, Lhasa, Qiangtang, Southwest Yunnan (SW Yunnan), Qilian and Sichuan-Yunan (Chuan-Dian) blocks followed. The strain rate of the blocks in the eastern part is smaller. The estimation based on the stain condition indicates that Himalayas block is still the area with the most intensive tectonic activity and it shortens in the NS direction at the rate of 15.2±1.5 mm/a. Tianshan block ranks the second and it shortens in the NS direction at the rate of 10.1±0.9 mm/a. At present, the two blocks are still uprising. It can be seen from superficial strain that the Chinese mainland is predominated by superficial expansion. Almost the total area in the eastern part of the Chinese mainland is expanded, while in the western part, the superficial compression and expansion are alternatively distributed from the south to the north. In the Chinese mainland, most EW-trending or proximate EW-trending faults have the left-lateral or left-lateral strike-slip relative movements along both sides, and most NS-trending faults have the right-lateral or right-lateral strike-slip relative movements along both sides. According to the data from GPS measurements the left-lateral strike-slip rate is 4.8±1.3 mm/a in the central part of Altun fault and 9.8±2.2 mm/a on Xianshuihe fault. The movement of the fault along the block boundary has provided the condition for block movement, so the movements of the block and its boundary are consistent, but the movement levels of the blocks are different. The statistic results indicate that the relative movement between most blocks is quite significant, which proves that active blocks exist. Himalayas, Tianshan, Qiangtang and SW Yunnan blocks have the most intensive movement; China-Mongolia, China-Korea (China-Korea), Alxa and South China blocks are rather stable. The mutual action of India, Pacific and Philippine Sea plates versus Eurasia plate is the principal driving force to the block movement in the Chinese mainland. Under the NNE-trending intensive press from India plate, the crustal matter of Qingzang plateau moves to the NNE and NE directions, then is hindered by the blocks located in the northern, northeastern and eastern parts. The crustal matter moves towards the Indian Ocean by the southeastern part of the plateau. 相似文献
18.
在阿尔金构造系中,阿尔金走滑断裂具有逆冲分量。文中将阿尔金构造系的逆冲活动分为西、中、东3段描述。西段从阿依耐克至车尔臣河河口,阿尔金南缘断裂具有逆冲活动迹象,在山前发育了规模较小的逆冲断层,有较新的地貌面被错动;中段从车尔臣河河口至拉配泉一带,在阿尔金山北缘发育大规模的逆冲断层,有较新的地貌面被错动;东段从拉配泉至宽滩山,逆冲断层有2种形式,此段阿尔金北缘断裂有逆冲分量,同时在阿尔金山北缘及山前冲洪积扇上发育逆冲断裂。自晚更新世中晚期以来,中段及东段逆冲速率<2mm/a。中段西部江尕拉萨依地区自16kaBP以来逆冲速率约为0.33mm/a,中部米兰桥一带自32kaBP以来的逆冲速率约为1.42mm/a。东段最大的逆冲速率在近中部的团结乡,自约5.31kaBP以来达到约1.81mm/a,向东西两端有减小的趋势,在西部柳城子自约72.36kaBP以来的逆冲速率为0.57mm/a,而东端的红柳沟自约8.99kaBP以来仅为0.05mm/a。团结乡地区约自19kaBP以来,逆冲活动有增强的趋势 相似文献
19.
QI Yu-ping ZHANG Zhi-wei LONG Feng XIAO Ben-fu LIANG Ming-jian LU Qian JIANG Peng 《地震地质》2018,40(2):377-395
The Daliangshan sub-block is a boundary region among the Bayan Har block, the Sichuan-Yunnan block and the South China block. It hosts four major fault systems:The southwest to south trending Xianshuihe-Zemuhe Fault zone in the west, the Longmenshan fault zone is the northern boundary, the Zhaotong-Lianfeng fault zone in the south, and the NS-trending Mabian-Yanjin fault zone in the east. This study focused on focal mechanisms and the regional stress field of the Daliangshan sub-block to help understand the earthquake preparation process, tectonic deformation and seismic stress interaction in this area. We collected broadband waveform records from the Sichuan Seismic Network and used multiple 1-D velocity models to determine the focal mechanisms of moderate and large earthquakes(ML ≥ 3.5)in the Daliangshan sub-block by using the CAP method. Results for 276 earthquakes from Jan 2010 to Aug 2016 show that the earthquakes are dominated by strike-slip and trust faulting, very few events have normal faulting and the mixed type. We then derived the regional distribution of the stress field through a damp linear inversion(DRSSI)using the focal mechanisms obtained in this study. Inversion results for the spatial pattern of the stress field in the block suggest that the entire region is predominantly under strike-slip and trust faulting regimes, largely consistent with the focal mechanisms. The direction of maximum compression axes is NW-NWW, and part of the area is slightly rotated, which is consistent with the GPS velocity field. Combining geodynamic background, this work suggests that because the Sichuan-Yunnan block is moving to SE and the Tibetan plateau to SE-E along major strike-slip faults, the stress field of the Daliangshan sub-block and its adjacent regions is controlled jointly by the Bayan Har block, the Sichuan-Yunnan block and the South China block. 相似文献
20.
Pattern of latest tectonic motion and its dynamics for active blocks in Sichuan-Yunnan region, China 总被引:9,自引:0,他引:9
Based on the concept of "active blocks" and spatial distribution of historical earthquakes with surface ruptures as well as major and subordinate active faults. The Sichuan-Yunnan region can be divided into four first-order blocks. They are the Markam block (I), the Sichuan-Yunnan rhombic block (II), Baoshan-Pu'er block (III), and Mizhina-Ximeng block (IV). Cut by sub-ordinate NE-trending active faults, the Sichuan-Yunnan rhombic block (II) can be further divided into two sub-blocks: the northwestern Sichuan sub-block (II1) and the middle Yunnan sub-block (II2), while the Baoshan- Pu'er block (III) can be further divided into three sub-blocks: Baoshan sub-block (III1), Jinggu sub-block (III2), and Mengla sub-block (III3). A quantitative study of offset landforms is carried out and the basic types of active faults and their long-term slip rates along the major boundaries of active blocks of different orders in the Sichuan-Yunnan region are determined, through slip vector analysis, the motion states of the active blocks are clarified and the deformation coordination on the block margins is discussed. It is suggested that the tectonic motion of the blocks in this region is a complex or superimposition of three basic types of motions: southeastward sliding, rotating on vertical axis, and uplifting. The Markam block (I), the northwestern Sichuan sub-block (II1), and middle Yunnan sub-block (II2) have a southeastward horizontal sliding rate of 1-5 mm/a, clockwise rotating angular rate of 1.4-4(/Ma, and uplifting rate of about 1 mm/a. The Baoshan-Pu'er (III) and Mizhina-Ximeng (IV) blocks have also been extensively clockwise rotated. This pattern of motion is a strain response to the collision between the Indian and Eurasian plates and the localized deformation and differential slip on the block margins associated with the northward motion of the Indian Plate. Because a set of transverse thrusts between the blocks absorbs and transforms some components of eastward or southeastward sliding motion, the eastward escape or extrusion of the Tibetan Plateau is limited as "imbricated thrusting transformation-limited extrusion model". 相似文献