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1.
利用多种地震学参数研究中国大陆地壳应变场 总被引:14,自引:0,他引:14
地壳应变场研究是地球动力学研究的一个基础性领域, 以往文献的探索大多集中在地壳形变的测量和研究上, 包括大面积水准测量和GPS观测等。 文中利用多种地震学参数研究中国大陆地壳应变场, 利用哈佛CMT目录和现代中国地震目录得到了中国大陆不同区域面波震级与标量地震矩的统计关系, 进而采用中国大陆历史地震资料研究中国大陆地壳应变场, 给出地震最大剪切应变率场的分布。 研究结果显示, 青藏高原及其周边地区是最大剪切应变率的高值区, 帕米尔和阿萨姆地区的应变率值最大。 与GPS得到的应变场结果进行比较, 两者的结果存在一致趋势。 利用NEIC宽频带地震辐射能量目录研究了中国大陆的地震视应变分布, 显示地震的视应变分布与地壳应变水平存在一定相关关系, 且发生在青藏高原周边地区地震的视应变水平较高。 这些研究结果为地球动力学研究的进一步深入探讨提供了新的科学资料。 相似文献
2.
Min Wang Zhengkang Shen Zhijun Niu Zusheng Zhang Hanrong Sun Weijun Gan Qi Wang Qun Ren 《中国科学D辑(英文版)》2003,46(2):25-40
We obtain the preliminary result of crustal deformation velocity field for the Chinese continent by analyzing GPS data from the Crustal Motion Observation Network of China (CMONOC), particularly the data from the regional networks of CMONOC observed in 1999 and 2001. We delineate 9 technically active blocks and 2 broadly distributed deformation zones out of a dense GPS velocity field, and derive block motion Euler poles for the blocks and their relative motion rates. Our result reveals that there are 3 categories of deformation patterns in the Chinese continent. The first category, associated with the interior of the Tibetan Plateau and the Tianshan orogenic belt, shows broadly distributed deformation within the regions. The third category, associated with the Tarim Basin and the region east of the north-south seismic belt of China, shows block-like motion, with deformation accommodated along the block boundaries only. The second category, mainly associated with the borderland of the Tibetan Plateau, such as the Qaidam, Qilian, Xining (in eastern Qinghai), and the Diamond-shaped (in western Sichuan and Yunnan) blocks, has the deformation pattern between the first and the third, i.e. these regions appear to deform block-like, but with smaller sizes and less strength for the blocks. Based on the analysis of the lithospheric structures and the deformation patterns of the regions above, we come to the inference that the deformation modes of the Chinese continental crust are mainly controlled by the crustal structure. The crust of the eastern China and the Tarim Basin is mechanically strong, and its deformation takes the form of relative motion between rigid blocks. On the other hand, the northward indentation of the Indian plate into the Asia continent has created the uplift of the Tibetan Plateau and the Tianshan Mountains, thickened their crust, and raised the temperature in the crust. The lower crust thus has become ductile, evidenced in low seismic velocity and high electric conductivity observed. The brittle part of the crust, driven by the visco-plastic flow of the lower crust, deforms extensively at all scales. The regions of the second category located at the borderland of the Tibetan Plateau are at the transition zone between the regions of the first and the third categories in terms of the crustal structure. Driven by the lateral boundary forces, their deformation style is also between the two, in the form of block motion and deformation with smaller blocks and less internal strength. 相似文献
3.
许多研究人员利用GPS测量的速度资料计算了地应变率场,但其结果差异较大. 本文将地质统计学中的Kriging方法引入到GPS观测的速度场研究中, 通过Kriging插值得到青藏高原及邻区均匀网格节点上的速度值,然后运用有限单元中形函数(Lagrange插值函数)的求导方法,计算每个网格单元积分点处的地应变率分量,从而获得青藏高原及邻区的地应变率场的分布. 计算结果显示,青藏高原主体处在南北向受挤压、东西向被拉张的应变状态之中,但高原东部地区则正好相反,即南北向拉张、东西向出现挤压. 青藏高原及邻区主应变率的方位与震源机制解中P轴、T轴的方向基本一致;最大主压应变率的高值区分布在喜马拉雅主边界冲断带及附近地区,高原内部出现主张应变率大于压应变率的现象,且高原内部处在拉张应变状态. 面膨胀率结果也表明,喜马拉雅山及附近地区为面收缩区,而高原内部其他地区主要为膨胀区;最大剪应变率分布清晰地显示出青藏高原周边的主要断裂带轮廓. 文中的应变率计算结果预示青藏高原及周边地区现今的地应变与较长期的地质活动之间有一定的继承关系. 相似文献
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Present-day horizontal deformation status of continental China and its driving mechanism 总被引:2,自引:0,他引:2
CHEN XiaoBin Institute of Geology China Earthquake Administration Beijing China 《中国科学D辑(英文版)》2007,50(11):1663-1673
Based on velocity data of 933 GPS sites and using the methods of Ordinary Kriging interpolation and shape function derivation, this study has obtained the strain rate field of continental China in the spherical coordinates. In comparison with previous research results, it is found that such a strain rate field can be described by both the continuous deformation and block motions in the continent. The Tibetan Plateau and Tianshan region are characterized by continuous deformation which is distributed across the whole area. Within the blocks of South China, Tarim, Ordos, and Northeast China, little crustal deformation and deformation occurs primarily on the faults along their boundaries, which can be explained by the model of block motion. In other regions, such as the Yinshan-Yanshan block, North China block, and East Shandong-Yellow Sea, deformation patterns can be explained by both models. Besides, from southwest to northeast of continental China, there are three remarkable extensional zones of NW trending. These results imply that the NNE directed push of the India plate is the primary driving force accounting for the internal deformation of continental China. It produces the uplift, hori-zontal shortening and vertical thickening of the Tibetan Plateau as well as radiation-like material extru-sion. Of these extruded materials, one part accommodates the eastward "escape" of other blocks, generating convergence and compression of western China and widespread extension and local com-plicated deformation in eastern China under the joint action of the surrounding settings. The other part opens a corridor between the South China block and Tibetan Plateau, flowing toward southeast to the Myanmar range arc and filling the gap there which is produced by back-arc extension due to plate subduction. 相似文献
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IntroductionChinesemainlandliesinthesoutheastofEurasianPlateandisclampedbyindian,PacificandPhilippineSeaPlates.Besides,itislocatedatbetweenthetwobigseismicactivebeltsintheworldatthesametime.Differingfromtheshowoftwobigseismicbeltswhichhaveseismiczonaldistributionalongplateboundary,Chinesemainlandanditsperipheralareahaveapeculiarcharacter,expressingseismicallylargestrength,highfrequency,widedistribution,shallowfocus,seriousdamage,multiplestyles,extremelynonuniformspace-timedistributionandsoo… 相似文献
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ZHU ShouBiao & SHI YaoLin Institute of Crustal Dynamics China Earthquake Administration Beijing China Department of Geophysics Peking University Beijing China Laboratory of Computational Geodynamics Graduate University of Chinese Academy of Sciences Beijing China 《中国科学D辑(英文版)》2007,50(1):67-74
Based on data of principal stress orientation from focal mechanism and of geological features in China, we made pseudo-3D genetic algorithm finite element (GA-FEM) inversion to investigate the main forces acting on the Chinese continent and adjacent areas which form the Chinese tectonic stress field. The results confirm that plate boundary forces play the dominant role in forming the stress field in China, as noticed by many previous researchers. However, we also find that topographic spreading forces, as well as basal drag forces of the lower crust to the upper crust, make significant contribution to stresses in regional scale. Forces acting on the Chinese continent can be outlined as follows: the collision of the India plate to the NNE is the most important action, whereby forces oriented to the NW by the Philippine plate and forces oriented to the SWW by the Pacific plate are also important. Topographic spreading forces are not negligible at high topographic gradient zones, these forces are perpendicular to edges of the Tibetan Plateau and a topographic gradient belt running in the NNE direction across Eastern China. Basal drag forces applied by the ductile flow of the lower crust to the base of upper crust affect the regional stress field in the Tibetan Plateau remarkably, producing the clockwise rotation around the eastern Himalaya syntax. 相似文献
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利用青藏高原东缘1999—2013年间多期GPS水平速率观测数据,基于多面函数拟合,计算球面坐标系下区域不同时期的面应变和最大剪应变,分析地应变的时空演化特征,结合不同时期发生的中强以上地震(MS6.0),研究期间大震分布与地应变时空演化特征的关系,主要结论如下:(1)青藏高原东缘面应变分布与地块有一定的对应关系,面应变的差异会在块体边界和内部形成不同的断层闭锁形式,与地震发生位置和震源机制有一定的关联;(2)区域最大剪应变的高值区对应于构造活动性较强的断裂带,这些断裂带鲜有地震发生;低值区对应于活动性较弱的断裂带,在区域地壳运动剧烈的背景下,在这些活动性相对较弱的断层上易形成应变能积累,因而会发生地震。区域绝大多数地震都发生在最大剪应变的低值区。 相似文献
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We obtain the preliminary result of crustal deformation velocity field for the Chinese con-tinent by analyzing GPS data from the Crustal Motion Observation Network of China (CMONOC), particularly the data from the regional networks of CMONOC observed in 1999 and 2001. We de-lineate 9 tectonically active blocks and 2 broadly distributed deformation zones out of a denseGPS velocity field, and derive block motion Euler poles for the blocks and their relative motionrates. Our result reveals that there are 3 categories of deformation patterns in the Chinese conti-nent. The first category, associated with the interior of the Tibetan Plateau and the Tianshan oro-genic belt, shows broadly distributed deformation within the regions. The third category, associatedwith the Tarim Basin and the region east of the north-south seismic belt of China, shows block-likemotion, with deformation accommodated along the block boundaries only. The second category, mainly associated with the borderland of the Tibetan Plateau, such as the Qaidam, Qilian, Xining(in eastern Qinghai), and the Diamond-shaped (in western Sichuan and Yunnan) blocks, has thedeformation pattern between the first and the third, i.e. these regions appear to deform block-like,but with smaller sizes and less strength for the blocks. Based on the analysis of the lithosphericstructures and the deformation patterns of the regions above, we come to the inference that thedeformation modes of the Chinese continental crust are mainly controlled by the crustal structure.The crust of the eastern China and the Tarim Basin is mechanically strong, and its deformationtakes the form of relative motion between rigid blocks. On the other hand, the northward indentation of the Indian plate into the Asia continent has created the uplift of the Tibetan Plateau and the Tianshan Mountains, thickened their crust, and raised the temperature in the crust. The lower crust thus has become ductile, evidenced in low seismic velocity and high electric conductivity observed. The brittle part of the crust, driven by the visco-plastic flow of the lower crust, deforms extensively at all scales. The regions of the second category located at the borderland of the Tibetan Plateau are at the transition zone between the regions of the first and the third categories in terms of the crustal structure. Driven by the lateral boundary forces, their deformation style is also between the two, in the form of block motion and deformation with smaller blocks and less internal strength. 相似文献
10.
本研究使用中国数字地震台网(CDSN)(2009—2016)走时数据开展青藏高原地壳地震波速度三维层析成像研究,获得分辨率达到1°×1°×20 km的青藏高原地壳S波三维速度结构和泊松比分布.结果表明,分布在可可西里和羌塘北部的高钾质和钾质火山岩带,其上地壳到下地壳都存在S波波速扰动负异常和高泊松比.说明第三纪青藏高原隆升过程中,由于大陆碰撞使三叠纪的东昆仑缝合带重新破裂,造成大量壳幔混合熔融物质上涌和火山喷发,进而揭示了青藏高原北部新生代火山岩的存在与青藏高原的形成和隆升密切相关;青藏高原新生代裂谷位于中下地壳S波速度扰动负异常带的两侧,裂谷带之下的中下地壳泊松比减小到0.22以下.裂谷带之下中下地壳的S波速异常分布和泊松比值可以推断青藏高原新生代裂谷深达中地壳底部,这个推论与密度扰动三维成像的相关结论一致.青藏高原S波速度和泊松比在下地壳至壳幔边界随深度产生急剧变化,说明地壳内部发生了大规模的层间拆离和水平剪切;青藏高原东构造结之下泊松比高达0.29~0.33,S波速度扰动为负异常,推断东构造结下方地壳主要由坚硬的蛇纹石化橄榄岩组成;青藏高原中下地壳S波速负异常区范围大面积扩大,地壳底部几乎被S波速低值区全部覆盖.下地壳S波异常分布特点可能反映下地壳管道流的影响. 相似文献
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以青藏高原北缘及东北缘的柴达木-祁连山地块内的活动断裂、由断裂所围限的微小块体为研究对象,系统收集整理区内活动断裂定量参数和GPS速度场等资料,使用球面应变率计算方法分析研究区内GPS 速度场得到现今构造应变率场,讨论区内最大剪应变率、面膨胀率与旋转率等参数与区域构造变形之间的关系;同时,依据区内详实的活动断裂资料建立精细的微小活动块体模型,利用Backslip模型反演断裂所围限的各个块体边界断裂的滑动速率、块体内部统一应变率及块体欧拉运动学参数等,并与活动构造方法获得的滑动速率做对比;最后,讨论研究区内由GPS速度场所揭示的地壳运动变形模式.结果表明:(1)柴达木-祁连山地区地壳运动,在沿着山脉走向上具有带状区域分块运动特征,大范围内具有弥散变形特征;(2)青藏高原北部变形场应是通过不同断裂差异性相对运动、区域内部逆冲挤压和块体旋转共同作用的结果.从鄂拉山到古浪民勤一带具有强烈的逆冲活动,其两侧地壳块体分别具有逆向旋转的运动性质;(3)在研究区东部GPS速度场所呈现顺时针旋转的形态,应是处于不同地块边界处的中下地壳与地幔介质差异驱动机制对上地壳块体所产生的作用,并以近地表断层应变率积累形式表现的结果,是祁连山地块、阿拉善块体、鄂尔多斯地块等大型块体推挤旋转影响下的复杂运动学形态. 相似文献
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采用有限元方法模拟了近20万年来青藏高原岩石圈形变演化过程,探讨了印度-欧亚大陆的碰撞对中国大陆岩石层形变和应力场的影响以及它们与强地震活动性的关系.结合现代GPS、地震和地质学观测的结果,对比分析了中国大陆在百万年、十万年和十年尺度上的形变和构造应力场的基本格局.研究表明:(1)印度-欧亚大陆的碰撞以及印度大陆的持续向北推进、挤压所产生的应力环境,一直主导了以青藏高原为核心的我国西部地域岩石圈构造、运动和演化,但其影响随着远离青藏高原地区而逐渐变小.(2)断层滑移和重力势作用对于青藏高原东西部以及塔里木盆地的影响相当大,它们导致青藏高原岩石层东西向形变速率增大,对青藏高原的中南部地区产生拉张效应,同时导致塔里木盆地出现整体的右旋趋势.(3)青藏高原区域水平方向形变速率和GPS观测结果吻合较好.但在垂直方向上,一些地区计算结果与观测数据相差较大,这说明单纯的挤压作用不是现代青藏高原隆升的惟一机制.现代青藏高原的隆升可能与其他驱动机制,如地幔对流、重力均衡以及剥蚀作用等有关.(4)印度板块的挤压作用基本上决定了中国大陆西部的主压应力场分布.(5)印度板块的碰撞对中国大陆的强地震活动性有重要影响,但华北地区是个例外,该地区的地震活动性很强而印度板块的挤压在该区域产生的影响却很小,说明其他的驱动力在一定程度上活化了华北地块. 相似文献
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省市级区域CORS(Continuously Operating Reference Stations)系统是当代城市数字化、信息化和智慧化的重要组成部分,便于获取各类物体的时空信息及其相关动态变化.为了进一步实现区域框架基准的现代化与自主化,全面提升现代测绘基准综合服务水平和应急保障能力,同时为了提高中国大陆区域水平速度场的精度,并精细地刻画其自身的局部运动特征,本文利用陆态网上千站2011—2017年的连续观测数据,采用GAMIT/GLOBK软件,获得高精度的定位和速度成果,进而提出和构建了基于欧拉矢量模型的中国大陆省级块体相对运动模型和部分省内子块体相对运动模型,并与欧亚板块、大陆整体和二级板块相对运动模型进行对比分析;结果表明,欧亚板块相对运动模型仅能描述大陆的部分运动趋势,中国大陆整体板块相对运动模型能够较好地展现大陆整体运动趋势,二级板块和省级块体相对运动模型均能够较为精细地反映区域的局部运动特征,且两者水平相对速度的内符合精度均小于2mm·a~(-1),其外符合精度均小于3mm·a~(-1),其中前者物理意义更为明显,后者使用更为简便,但在青藏、川滇等地壳运动复杂的地区两者精度仍有欠缺.因此,本文提出利用K-Means++算法对地壳运动复杂区域的水平速度场进行聚类分析,以快速准确地对这些区域进行子块体划分;结果表明,划分成果与现有部分二级块体成果相符合.为了兼顾省内复杂地质构造与地形地貌的影响,同时提高省级块体划分的物理意义,对地壳运动复杂的省份再细分块体,进而对各子块体构建欧拉矢量模型;结果发现,该模型平均误差和中误差均小于2mm·a~(-1),提高新疆、西藏、川滇等地区的速度场模型精度至2mm·a~(-1)左右,在确保精确度的同时,满足使用简便性的要求. 相似文献
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利用连续地震背景噪声记录和互相关技术获得瑞利面波格林函数,进而反演获得了青藏高原东部和周边地区的地壳三维速度结构.地震数据源于北京大学宽频带流动观测地震台阵,国家数字测震台网数据备分中心提供的部分固定台站的连续记录及INDEPTH IV宽频带流动观测地震台阵.首先对观测数据进行处理和分析取得所有可能台站对的面波经验格林函数和瑞利波相速度频散曲线,反演得到了观测台阵下方周期从6~60s的瑞利波相速度异常分布图像.并且进一步反演获得研究区域三维剪切波速度结构和莫霍面深度分布.短周期(6~14s)相速度异常分布与地表地质构造特征吻合较好,在青藏高原和四川盆地之间存在一个明显的南北向转换带.而本文最重要的结果是周期大于25s的相速度异常分布图像显示,以昆仑断裂带为界,柴达木盆地和祁连山脉地区呈现与青藏高原截然不同的中地壳速度结构,反而与青藏高原东缘地区和川滇菱形块体速度结构相似.反演获得的剪切波速度在27.5~45km深度的切片也明显地揭示:青藏高原的松潘—甘孜地块和羌塘地块呈现均一的低速层;然而,柴达木盆地和祁连山脉地区则呈现较强的横向不均匀性,尤其是柴达木盆地的高速异常和四川盆地的高速异常相对应.这些结果为前人提出的青藏高原东北向台阶式增长模式提供了重要的地震学观测证据.与全球一维平均速度模型(AK135)相比较发现,本文测量和反演获得的研究区域内平均相速度和剪切波速度都比AK135模型慢很多,尤其是青藏高原的中地壳(25~40km)剪切波速度显著低于全球平均速度模型.进一步的层析成像反演证实松潘—甘孜和羌塘地块中地壳(27.5~45km)呈现大范围均一的低速层,为青藏高原可能存在大规模中下地壳"层流"提供地震学观测证据.在祁连山脉的27.5~45km深度观测到的明显低速异常体可能对应于该造山带下地幔岩浆活动导致的底侵作用,表明引起该地区地壳增厚的主要机制可能是来自地幔岩浆的底侵作用. 相似文献
15.
利用全国260多个陆态网络连续站以及2 000多个陆态网络区域站2011—2015年观测数据,计算分析中国大陆现今整体地壳构造形变特征以及板内应变场空间分布特征。根据密集、大范围的GPS速度场可知中国大陆现今整体速度场依然呈现西强东弱的态势,其中最大值出现在喜马拉雅地区,一般速率在35~42mm/a之间,而川滇地区形成的右旋剪切带的形变特征最为醒目,其西南部最小速率在3~9mm/a之间,北部最大速率在17~23mm/a;由应变场的空间分布可以看出应力最大的地区主要是喜马拉雅、昆仑山中部、川滇地区的鲜水河断裂带、天山地区以及京津唐地区;东部沿海地区应变速率表现为东西拉张型,主要是由于2011年日本大地震对该地区的影响还未完全消退造成的。 相似文献
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探讨地壳运动速度场模型的构建方法,提出结合欧拉矢量的维多样性动态权重粒子群算法构建地壳运动速度场模型。通过模拟算例验证该算法的稳定性和有效性,建立的速度场模型与线性权重粒子群算法和非线性权重粒子群算法的计算结果相比具有较高的精度,且收敛速度较快。利用青藏高原东北缘1999—2013年中国地壳运动观测网络观测到的GPS水平速率结果,在块体划分和模型辨识的基础上,建立青藏高原东北缘地壳运动速度场模型,并将其与最小二乘配置法的计算结果进行比较,结果表明改进的粒子群算法建立的地壳运动速度场模型具有较高的精度。 相似文献
17.
Ren Jinwei 《中国地震研究》2005,19(2):107-115
INTRODUCTION Moststudiesonactiveblockshavebeenfocusedonidentificationofblockboundariesandtheiractivity;inotherwords,mostoftheworkwaslimitedtothehorizontalmovementoftheblocks.Inreality,theblocksarenotonlysurroundedbyactivefaultsofhorizontalmotion,butalsoco… 相似文献
18.
在青藏高原的运动变形过程中,断层活动起着至关重要的作用.本文利用有限元数值模拟的方法,分别计算了在GPS做边界约束下青藏高原及周边区域的连续体模型和含断层的不连续体模型的运动状态和应力场分布.从连续性模型和非连续体模型的差异发现,断层存在与否很大程度上影响了青藏高原现代运动场的分布.主要体现在,断层的滑移运动(1)增加了青藏高原东西两侧的拉张趋势;(2)加大了青藏高原物质东移的速度;(3)改变了塔里木和柴达木盆地的运动状态.模拟结果显示,非连续模型的运动场分布与GPS观测结果吻合程度大大高于连续体模型结果,表明断层活动在青藏高原的运动学和动力学过程中起着重要的作用,在研究青藏高原的动力学机制中,必须考虑断层作用的影响. 相似文献
19.
Chen Lianwang 《中国地震研究》2006,20(2):127-137
INTRODUCTIONInthe late 1980’s ,aninternational cooperation project in earth sciences ,the World Stress MapProject ,wasinitiated underthe World Lithosphere Program. Measurements andresearch achievementsof the present-daytectonic stress field worldwide were analyzed and sorted out .The project achievedgood results and based on them, a world stress database was set up,the world stress map wascompiled,andthe general andregional crustal stress patterns were discussed (Zoback,et al .,1989 ;… 相似文献
20.
根据中国大陆不同来源的多个GPS区域监测网1991~1999年间的观测资料和“中国地壳运动观测网络”基本网1998~2000年的观测资料,联合处理得到中国大陆地壳水平运动速度场结果,通过最小二乘配置法建立中国大陆水平运动速度场模型,获得了基于连续介质假设的中国大陆水平应变场(或称为视应变场)初步结果. 分析了水平运动、应变场空间分布特征及其与强震的关系,并简要分析了2001年11月14日昆仑山口西8.1级大地震的区域构造变形背景. 结果表明:中国大陆中西部构造变形强烈,应变速率值高,又以青藏块体及其边缘和新疆西部最为显著. 除川滇、新疆西部外,大部分地区的近东西向断裂存在左旋剪切变形,近南北向的断裂存在右旋剪切变形. 而东部地区构造变形相对较弱. 强震通常发生在剪切应变率的高值区及其边缘,尤其是与构造变形背景相一致的剪应变率高值区. 昆仑山口西8.1级地震发生在最显著的东西向左旋剪切应变率高值区,从该区域的应变状态分析,具备近东西向断裂产生巨型走滑破裂错动的构造变形背景. 相似文献