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根据网络工程的GPS站点观测资料,计算相对中国大陆整体1999~2007年的趋势运动速率和2004~2007年的动态运动速率,用青藏亚板块和华南亚板块的参数计算龙门山断裂带的活动参量,研究了中国大陆运动场和其变化,分析了地壳运动场的特征与汶川Ms8级地震的孕育关系.结果揭示出:现今地壳的运动分区与地质新构造单元基本一致,显示现代地壳构造活动足新构造运动的继承和发展;中国大陆地壳运动的动力主要与印度板块、太平洋板块与欧亚板块的相互碰撞俯冲产生的作用力有关.汶川Ms8级地震的发生,主要是由于印度板块对青藏亚板块的向北推挤、产生侧向运动,致使龙门山断裂带遭受挤压产生能量积累所致.2004~2007年的地壳动态运动,使龙门山断裂带走滑活动加强,从稳定的压应变积累状态转入了剪切作用下的易活动状态. 相似文献
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根据网络工程的GPS站点观测资料,计算相对中国大陆整体1999~2007年的趋势运动速率和2004~2007年的动态运动速率,用青藏亚板块和华南亚板块的参数计算龙门山断裂带的活动参量,研究了中国大陆运动场和其变化,分析了地壳运动场的特征与汶川MS8级地震的孕育关系.结果揭示出:现今地壳的运动分区与地质新构造单元基本一致,显示现代地壳构造活动是新构造运动的继承和发展;中国大陆地壳运动的动力主要与印度板块、太平洋板块与欧亚板块的相互碰撞俯冲产生的作用力有关.汶川MS8级地震的发生,主要是由于印度板块对青藏亚板块的向北推挤、产生侧向运动,致使龙门山断裂带遭受挤压产生能量积累所致.2004~2007年的地壳动态运动,使龙门山断裂带走滑活动加强,从稳定的压应变积累状态转入了剪切作用下的易活动状态. 相似文献
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汶川M_S8.0地震前龙门山断裂带的水平形变和应变特征 总被引:1,自引:0,他引:1
根据1999年,2001年,2004年和2007年的GPS观测资料计算得到的1999--2007年全球框架下的站点速率,使用块体运动模型公式,根据青藏亚板块和华南亚板块上的GPS站点速度,分别计算两个块体的运动参数,并用来反算龙门山断裂带的运动参量。结果表明龙门山断裂带的活动速率为9.38mm/a。其中,右旋走滑速率为3.22mm/a,压缩速率为-8.81mm/a。 相似文献
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根据2004年和2007年GPS复测资料,计算出中国大陆的水平主应变数据,显示出各亚板块的主压应变轴方向与震源机制解的P轴和用地质方法得到的主压应力轴基本一致,表明在区域上和长时期中,地壳的构造应力场是相对稳定的.中国大陆西部的青藏亚板块和新疆亚板块的主压应力轴,为南北向及北北东-南南西向,受欧亚板块和印度板块相互碰撞而产生的作用力的控制;东部的黑龙江亚板块和华北亚板块的主压应变轴,为北东东-南西西向,显示出受欧亚板块与北美板块、太平洋板块碰撞俯冲产生的作用力影响,同时也受青藏亚板块和新疆亚板块侧向作用力的影响;华南亚板块的主压应变轴,为北西西-南东东向,反映出受菲律滨海板块与欧亚板块碰撞产生的作用力影响,同时也受青藏亚板块侧向作用力的影响.通过比较2004-2007年与2001-2004年的主压应变轴方向,反映出两个时间段各亚板块的主压应力作用方向基本一致,只是主应力轴方向集中程度有一定差别.前后两个时间段不同单元的面应变率显示,压性变化为主的数量减少,张性变化为主的数量有所增多. 相似文献
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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
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《地震研究》2013,(3)
通过对川滇地区块体细划,借助均匀弹性块体应变模型,利用1999~2007年和2009~2011年两个时段GPS观测地壳水平运动场,计算了这两个时间段该区块体应变状态、块体内部均匀弹性变形场及相邻块体边界带的相对运动。考虑汶川地震、玉树地震对该区域的地壳运动的影响,分析计算结果认为:(1)计算结果较好地反映了该区域构造运动特征;(2)川滇地区块体东边界运动主要以走滑为主,安宁河断裂和则木河断裂的交汇部位表现为明显的左旋走滑运动受阻,且其两侧块体应变率积累显著,是未来可能的强震孕育区;(3)2009~2011年与2007~2009年相比,整个区域块体边界运动空间差异增强,可能反映了汶川、玉树地震对该区域地壳运动的影响。 相似文献
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2017年8月8日四川发生九寨沟M7.0地震,是继2008年汶川M8.0地震后发生在巴颜喀拉块体东部的又一强震.现今GPS速度观测数据显示,2008年汶川地震前后的1999-2007年和2011-2016年两个时间段内巴颜喀拉块体东部地表速度场存在明显的差异.本文以实际GPS速度观测资料为约束,构建三维有限元地球动力学模型,分别计算分析了两个时段内震源区及周边现今地壳形变、弹性应变能和应力积累特征,进一步探讨汶川地震的发生对九寨沟地区变形及应力的影响.数值模拟结果显示,汶川地震之后(2011-2016年)巴颜喀拉块体东部的地壳形变、弹性应变能积累及应力积累速率均明显大于震前,增加量值达1.5-3倍;九寨沟地震发震断裂上库仑应力增长率在1999-2007年约为0.7 kPa·a~(-1),2011-2016年间增至1.2 kPa·a~(-1).上述结果表明,现今巴颜喀拉块体东部地壳应力积累过程有利于左旋走滑型九寨沟地震的发生,汶川地震的发生调整了区域应力状态,加速了九寨沟地震的孕育过程. 相似文献
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针对2010年4月14日玉树发生MS7.1地震,本文利用InSAR数据给出同震视线向位移确定出的发震断层空间展布,并以该同震位移为约束反演得到主震和最大余震的同震位错分布.结果表明,主震同震位错发生在东玉树断裂,最大余震同震位错发生在西玉树断裂东端;基于位错分布计算了同震库仑应力变化与西部余震集中区地震活动之间的关系,结果反映玉树主震后最为活跃的余震活动可能受控于近东西向的次级断层(走向约为85°),而非玉树主干断裂;玉树断裂带整体呈现为左旋走滑运动,但其具体断层运动形式表现出主干断裂典型走滑运动、走滑断裂间的拉张和逆冲性质的次级运动、次级断裂与主干断裂相互作用下更为复杂的多方向次级断层活动等等不同变形特征,而主震同震破裂与余震空间分布均与这些不同断层变形方式有着密切关系. 相似文献
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玉树和汶川地震前后区域水平形变的空间分布 总被引:3,自引:0,他引:3
以1999—2007年和2009—2010年两个时间段的GNSS观测资料为基础, 借助于多核函数解析、 滤波和应变场的无偏算法以及区域无旋转基准, 在运动场连续变化的条件下获得了玉树MS7.1和汶川MS8.0地震前后青藏高原东南地域运动与形变场, 并得到如下基本认知: ① 玉树和汶川地震前震源区构造活动在空间和较长时间上明显弱化, 最大正应变和最大剪切应变均处在区域构造活动的最低水平。 ② 与地震破裂相应的旋剪形变最大部位既不位于震源区也不远离震源区, 似乎存在某种协调有序活动, 玉树地震发震构造断裂带基本上处在区域右旋活动与左旋活动的过渡区上, 而左旋活动最大条带却为平行于该断裂带且相距约150 km的东北构造活动区内; 汶川地震发震构造断裂虽处在右旋活动的龙门山断裂带上, 但右旋活动最大条带为平行于该断裂带且相距约200 km的西北活动区内。 ③ 玉树地震震时较大水平形变的范围较小, 汶川地震震后水平形变仍较突出。 ④ 理塘—德巫断裂带的北段及周边地区应给予关注, 面应变为象限分布图像, 最大正应变和最大剪切应变均显示闭锁的迹象。 相似文献
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利用双差定位方法对玉树地震序列2010年4月14日至10月31日间发生的ML≥1.0地震进行双差定位,得到1545个地震的重定位结果.综合分析地震双差定位结果和玉树地震序列中强地震震源机制解,发现玉树MS7.3地震发震构造由北西向和北东东向两条相交断层组成,主震发生在北西走向的甘孜—玉树断裂带上,5月29日的MS5.9余震序列发生在北东东走向的一条隐伏断裂上,两条断裂均接近直立.甘孜—玉树断裂是羌塘地块和巴彦喀拉地块的构造边界,由于羌塘地块和巴颜喀拉地块的差异运动使甘孜—玉树断裂强耦合段应力高度积累,在应变能超过岩石强度时破裂失稳发生了MS7.3地震.主震断层的左旋滑动导致北东东向断层的正应力减小,库伦应力增加,45天后触发了MS5.9余震序列的活动. 相似文献
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Based on the GPS velocity field data of 1999-2007 and 2011-2013,we used the least squares configuration method and GPS velocity profile results to synthetically analyze the dynamic evolution characteristics of crustal deformation in the Yunnan area before and after the Wenchuan earthquake. The dynamic evolution of GPS velocity field shows that the direction is gradually changed from the south in the southern part of the Sichuan-Yunnan block to the south-west in the southern Yunnan block and there is a clear relative motion characteristic near the block boundary fault zone. Compared with the GPS velocity of 1999-2007, the results of 2011-2013 also reflect segmental deformation characteristics of the block boundary fault zone. Southeast movement shows a significant increase, which may be related to crustal deformation adjustment after the Wenchuan earthquake. The dynamic evolution of strain parameters shows a pattern of "extension in the middle and compression at both ends" in the whole area and the distribution of deformation (shear, extension or compression) is closely related to the background motion and deformation characteristics of the main fault zone. Compared with the results of the period of 1999-2007, the extensional deformation zone of 2011-2013 is expanded eastward and southward. The compressional deformation of the eastern boundary (the Xiaojiang fault zone) of the Sichuan-Yunnan block is no longer significant, which is mainly concentrated in the northern section of the Xiaojiang fault zone and may be related to the post-seismic deformation adjustment of the Wenchuan earthquake. The GPS velocity profile results show that the left-lateral slip velocity of the Xiaojiang fault zone reduced gradually from north to south (10mm/a-5mm/a), and the width of the northern section is wider. The right-lateral slip rate of the Honghe fault zone is about 4mm/a, and the deformation width is wider. The dynamic results show that the Wenchuan earthquake has little effect on the deformation modes of these two fault zones. 相似文献
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SPATIAL AND TEMPORAL DISTRIBUTION OF SLIP RATE DEFICIT ACROSS HAIYUAN-LIUPAN SHAN FAULT ZONE CONSTRAINED BY GPS DATA 
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下载免费PDF全文 As the northeast boundary of the Tibetan plateau, the Haiyuan-Liupan Shan fault zone has separated the intensely tectonic deformed Tibetan plateau from the stable blocks of Ordos and Alxa since Cenozoic era. It is an active fault with high seismic risk in the west of mainland China. Using geology and geodetic techniques, previous studies have obtained the long-term slip rate across the Haiyuan-Liupan Shan fault zone. However, the detailed locking result and slip rate deficit across this fault zone are scarce. After the 2008 Wenchuan MS8.0 earthquake, the tectonic stress field of Longmen Shan Fault and its vicinity was changed, which suggests that the crustal movement and potential seismic risk of Haiyuan-Liupan Shan fault zone should be investigated necessarily.
Utilizing GPS horizontal velocities observed before and after Wenchuan earthquake(1999~2007 and 2009~2014), the spatial and temporal distributions of locking and slip rate deficit across the Haiyuan-Liupan Shan fault zone are inferred. In our model, we assume that the crustal deformation is caused by block rotation, horizontal strain rate within block and locking on block-bounding faults. The inversion results suggest that the Haiyuan fault zone has a left-lateral strike-slip rate deficit, the northern section of Liupan Shan has a thrust dip-slip rate deficit, while the southern section has a normal dip-slip rate deficit. The locking depths of Maomao Shan and west section of Laohu Shan are 25km during two periods, and the maximum left-lateral slip rate deficit is 6mm/a. The locking depths of east section of Laohu Shan and Haiyuan segment are shallow, and creep slip dominates them presently, which indicates that these sections are in the postseismic relaxation process of the 1920 Haiyuan earthquake. The Liupan Shan Fault has a locking depth of 35km with a maximum dip-slip rate deficit of 2mm/a. After the Wenchuan earthquake, the high slip rate deficit across Liupan Shan Fault migrated from its middle to northern section, and the range decreased, while its southern section had a normal-slip rate deficit.
Our results show that the Maomao Shan Fault and west section of Laohu Shan Fault could accumulate strain rapidly and these sections are within the Tianzhu seismic gap. Although the Liupan Shan Fault accumulates strain slowly, a long time has been passed since last large earthquake, and it has accumulated high strain energy possibly. Therefore, the potential seismic risks of these segments are significantly high compared to other segments along the Haiyuan-Liupan Shan fault zone. 相似文献
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2008年3月21日新疆于田发生MS7.3级地震,2014年2月12日于田再次发生MS7.3级地震,两次地震相距约110 km.但是,前者震源机制为正断层,后者震源机制为左旋走滑断层.为进一步探讨这两次地震的孕育应力环境、发震机制及其动力学成因,本文进行三维有限元数值试验分析,计算了该区域在GPS约束条件下的速度场、应力和应变场变化,并与实际观测资料进行对比.数值计算得到的区域内几条主要大的走滑断层错动性质,与实际地质观察到的断层左旋或右旋性质吻合,验证了计算结果的可靠性.结果表明于田及其临近区域整体上处于北东-南西向挤压和北西-南东向拉张状态.在GPS速度约束条件下,2008年于田地震震中区域最大主张应变率大于最大主压应变率,处于以拉张为主的应力状态,NE走向断层受到北东-南西方向的拉应力作用,从而形成正断层;2014年于田地震处于拉张应变率与压应变率几乎一致的区域,NEE走向断层在NE-SW主压应力和NW-SE主张应力作用下发生左旋走滑. 相似文献
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The northwestern section of the Zhangjiakou-Bohai fault zone starts in the west of Zhangjiakou, extending southeast through Huailai, Shunyi and Tianjin and entering into the Bohai Sea, with a width up to several tens of kilometers, narrow in the west and wide in the east. The Neogene-Quaternary has extended in the northwest and southeast direction, forming a large regional active structure. There are many earthquakes of magnitude 7 or above in the history on the Zhangjiakou-Bohai fault zone and it is also a strong earthquake activity zone in eastern China. Therefore, the modern tectonic activities of this fault zone have an important impact on regional seismic hazard, and are of great significance for earthquake prediction and disaster reduction.
In this paper, using the mobile GPS station observation data of 1999, 2007, 2009, 2011, 2013 and 2015, and with the rigid-linear elastic block motion model equation proposed by LI Yan-xing, the horizontal deformation rate and strain rate of the Zhangjiakou-Bohai fault zone of the five adjacent periods of 1999-2007, 2007-2009, 2009-2011, 2011-2013 and 2013-2015 were calculated, the tectonic activity characteristics and evolution of the fault zone were studied. The results show that in the five periods, the average deformation rate of the Zhangjiakou-Bohai fault zone is 1. 74mm/a, the left-lateral strike-slip rate is 1.59mm/a, and the compression rate is -0.59mm/a. The Zhangjiakou-Bohai fault zone is characterized by left-lateral strike-slip and compression on the whole, and the left-lateral strike-slip rate is greater than the compression rate at each period. The strike-slip rate is significantly greater than the compression rate, indicating that the activity of Zhangjiakou-Bohai fault zone is dominated by left-lateral strike-slip faulting with compression. The minimum principal strain rate of the Zhangjiakou-Bohai fault zone in the five periods varies from -12.06×10-9/a to -4.62×10-9/a, and the average minimum principal strain axis direction is N63.9°E, with little change in direction. The maximum principal strain rate varies from 1.55×10-9/a to 5.99×10-9/a, and the average maximum principal strain axis direction is N333.9°W, the direction does not change much. The strike of the Zhangjiakou-Bohai fault zone is NWW(the overall strike is calculated by N300°W), and the normal strain rate of the fault zone is -5.87×10-9/a(being compressional), and the shear strain rate is 12.70×10-9/a. The shear strain rate on the fault zone is about twice the value of the normal strain rate, and the shear strain rate of the fault zone is greater than the normal strain rate, which indicates the shear stress of the 5 periods of 1999-2007, 2007-2009, 2009-2011, 2011-2013 and 2013-2015 is relatively significant, suggesting that the fault plain is dominated by left-lateral shear stress. This suggests that the Japan 3·11 earthquake has little effect on the deformation strain of the Zhangjiakou-Bohai fault zone, and it does not change the nature of activity of the fault zone. The tectonic activity is still inheriting. Since the tectonic activity of the Zhangjiakou-Bohai fault zone has gradually decreased after the Japan 3·11 earthquake, the deformation strain evolution trend has gradually returned to a unified consistent state. Therefore, the deformation strain state of the Zhangjiakou-Bohai fault zone does not have the condition for strong earthquakes. 相似文献
18.
利用1999—2007期和2009—2013期中国大陆GPS速度场数据,采用DEFNODE负位错反演程序估算了川滇菱形块体东边界——鲜水河—安宁河—则木河—小江断裂带在汶川地震前后的断层闭锁程度和滑动亏损空间分布动态变化特征,讨论了汶川地震对该断裂系统的影响范围和程度,并结合b值空间分布和地震破裂时-空结果分析了断裂系统的强震危险段.结果表明,汶川地震前鲜水河断裂最南端为完全闭锁(闭锁深度25km),中南段地表以下10~15km深度为强闭锁状态,中北段基本处于蠕滑状态;安宁河断裂最南端闭锁很弱,其余位置闭锁深度为10~15km;则木河断裂除最南端闭锁较弱以外,其余位置基本为完全闭锁;小江断裂在巧家以南、东川以南、宜良附近、华宁以北等四处位置闭锁较弱,其余位置为强闭锁.10年尺度的GPS速度场反演所得断层闭锁程度所指示的强震危险段,主要为鲜水河断裂道孚—八美段、安宁河断裂中段、则木河断裂中北段、小江断裂北段东川附近、小江断裂南段华宁—建水段,该结果与地质尺度的断层地震空区和30年尺度的b值空间分布所指示的危险段落具有一致性.汶川地震后断裂带远、近场速度分布和块体运动状态发生变化,这种区域地壳运动调整使得负位错模型反演得到的断裂带闭锁情况发生一定变化.汶川地震前后川滇菱形块体东边界平行断层滑动亏损速率均为左旋走滑亏损,且在安宁河断裂北端、则木河断裂中北段滑动亏损速率最大;除鲜水河断裂中南段与最南端和小江断裂东川附近以外,其余断裂震后滑动亏损速率均有所增加.垂直断层滑动亏损速率既有拉张亏损也有挤压亏损,且鲜水河断裂最南端由震前挤压转变为震后拉张,其余断裂除了安宁河断裂和小江断裂中段与最北端存在挤压滑动亏损速率外均为拉张速率. 相似文献
19.
利用川滇地区1991-1999年的高精度GPS观测处理结果,采用稳健 - 贝叶斯最小二乘算法与多断裂位错模型,分析研究了川滇菱形块体主要边界运动的定量模型.反演分析表明:川西鲜水河断裂带和安宁河断裂带的左旋走滑运动速率约30mm/a,倾滑运动(逆断层)速率分别约9-11mm/a;滇西红河断裂带、程海断裂带、鹤庆 - 洱源断裂带的走滑运动(分别为右旋、左旋、左旋)速率分别约、11、13mm/a,倾滑运动(正断层)速率分别约16、24、16mm/a;如将其视为弹性应力应变积累,则各断层每年有相当于6级左右的地震能量积累.依据上述反演结果,模拟了区域主要断层运动引起的水平位移、应变速率场图像,显示了边界断裂及其之间的相互作用. 相似文献
20.
The Wenchuan earthquake occurred near the "triple junction" linking the Bayan Har block, the South China block, and the Sichuan-Yunnan rhombic block, and its influences on the surrounding blocks and the main fault zones in the Sichuan-Yunnan region, i.e., the block boundary zone, cannot be ignored. In this paper, changes of movement and stress of the fault zones before and after a strong earthquake were simulated based on the GPS repetition survey results recently obtained during 1999–2007, 2009–2011, and 2011–2013 with a two-dimensional finite-element contact model and the "block- loading" method. The results show that, before the Wenchuan earthquake, the movement of the Longmenshan fault zone was very slow and its compressive stress accumulated rapidly; after the Wenchuan earthquake, movements toward the E-SSE direction of the Bayan Har, southwestern Yunnan, and rhombic blocks were enhanced, and the dextral and horizontal compressive speeds and annual accumulative compressive stress of the Longmenshan fault zone increased markedly by factors of 4.5, 2.1, and 2.5, respectively. The southern Xianshuihe, Anninghe, Zemuhe, Daliangshan, and Lijiang-Xiaojinhe fault zones accumulated compressive stress rapidly, forming enhanced compressive stress zones along a NE strike crossing the central part of the Sichuan-Yunnan region. The tensional movement of the Xianshuihe fault zone was enhanced and the slip movement in the central part of the zone was reversed in a short time. The changes are tightly related to the medium-intensity earthquakes that occurred during the same period in this region, revealing that the spatial migration of seismic activity is related to changes of movement of the blocks. 相似文献