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1.
Shear-waves have complicated interactions with the free surface, particularly in the presence of low-velocity surface layers, topographic irregularities, and the expected near-surface crack and stress anomalies. Consequently, it has been suggested that shear-waves should be recorded subsurface in vertical seismic profiles (VSPs), in order to extract accurate information about the in situ crack and stress geometry contained in shear-wave splitting. This paper compares the information in synthetic shear-waves in reflection gathers and VSPs, in order to assess the relative merits of the two techniques for investigating shear-wave splitting. Synthetic seismograms demonstrate that in the presence of even very simple surface layers, shear-waves recorded in reflection surveys at the surface have polarizations which may not indicate crack and stress geometry at depth. In contrast, shear-waves recorded in VSPs are relatively unaffected by surface layers and near-surface stress and crack anomalies, and the behaviour of shear-wave splitting is dominated by the structure of the rock mass in the vicinity of subsurface geophones. Matrix rotations of multicomponent-multisource shear-wave reflection data to extract the information contained in the split shear-waves, are found to be directly meaningful only in situations where crack orientations do not change with depth. 相似文献
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利用中国地震科学台阵第一期(2011-01-2014-06)及部分中国地震科学台阵第二期(2013-02-2015-12)的流动地震台阵记录到的小震波形资料,运用剪切波分裂系统分析(SAM)方法,分析南北地震带的地壳各向异性,对剪切波分裂参数所反映的区域应力环境及构造特征,以及区域内主压应力方向与断裂分布的关系展开讨论.研究结果表明,南北地震带快剪切波偏振方向自北向南由NE向逐渐转变为NNW向,与南北地震带区域主压应力的方向变化具有一致性.区域内分布的大量NE及WNW或NW向断裂构造同样对快波偏振方向有比较大的影响,位于走滑断裂附近的台站,其快波方向与断裂走向大致平行,部分位于走滑断裂附近的台站其快波方向几乎垂直于断裂走向,而与构造应力场方向一致性较好.个别台站表现出复杂快波优势方向特征,反映出研究区内构造环境的复杂性.慢波时间延迟结果显示,南北地震带南段的平均时间延迟高于北段,反映了受印度板块和欧亚板块的碰撞挤压作用,南段地壳介质各向异性程度更大,构造变形更加剧烈.对比南北地震带上地幔各向异性特征,推测在川滇菱形块体内部可能存在复杂的壳幔耦合现象,地壳剪切波分裂除了反映区域应力特征,还可以揭示出区域构造信息. 相似文献
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本文测定了2013年4月20日芦山MS7.0地震震源区及其附近台站的S波分裂参数,包括快波偏振方向和慢波延迟时间,最终得到了40个台站的S波分裂结果.结果显示:在地震主破裂区内观测到的快波优势取向为NE向,与余震分布的长轴方向一致;位于双石—大川断裂以西台站的快波偏振优势方向为NW向,与区域最大主压应力轴方向一致;位于荥经断裂附近台站的快波偏振优势方向为NW向,与该断裂走向一致.快波偏振优势方向随时间的变化结果显示:主震前位于地震破裂区附近的TQU和BAX台站的快波偏振优势方向均呈NE向;主震后TQU台站的快波偏振优势方向为近EW向,而BAX台站的快波偏振优势方向则不突出,反映出芦山地震主震前快波偏振方向受控于龙门山断裂带,而主震后受构造应力场的作用更加明显.此外,各台站的慢波延迟时间为1.25—5.40ms/km,在余震覆盖密集区域,台站的慢波延迟时间均大于3.0ms/km,反映出震源区的各向异性程度较强.芦山主震后,各台站的延迟时间随时间变化持续减小,反映出震源区地壳应力随余震活动逐渐减小. 相似文献
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各向异性介质中频率相关横波分裂参数的提取算法(英文) 总被引:1,自引:0,他引:1
基于曾新吾和MacBeth提出的时域内双源累积旋转方法,建立了频率相关介质中分析多分量VSP数据的横波分裂参数提取算法(DCTF)。该算法可以在频域中针对单个频率提取横波各向异性参数(快横波的极化方向以及快、慢横波间的时间差),从而避免了目前常用方法中使用窄带通滤波可能带来的误差。通过对地震合成记录的数值分析,确定了该算法的可行性和正确性,并与目前常用方法的应用结果进行了比较。结果显示,频率相关横波分裂参数可以利用DCTF从地震四分量数据中直接提取。在地震频率范围内,含较大尺度裂缝时各向异性参数将表现出频率相关性,这意味着在地震频率范围会出现频散。随着频率的增加,各向异性有降低的趋势。 相似文献
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The scattering of shear-waves in the crust 总被引:2,自引:0,他引:2
Stuart Crampin 《Pure and Applied Geophysics》1990,132(1-2):67-91
The two major sources of scattering for shear-waves in the crust, interactions with the topography at the surface and the effective anisotropy of aligned cracks throughout the rockmass, introduce first-order changes to the shear-wave particle-motion. At the surface, shear-waves are scattered by the topography within a wavelength or two of the recording site so that, unless the effective incidence angle is less than the critical angle sin–1
V
S/V
P, the recorded waveforms may bear little relationship to the waveforms of the incident wave. Within the rockmass, shear-waves are scattered by extensive-dilatancy anisotropy (EDA), the distribution of stress-aligned fluid-filled cracks, microcracks, and preferentially oriented pore-space pervading most rocks in the crust. Analysis of this shear-wave splitting yields new information about the internal structure of thein situ rockmass which is not otherwise available. 相似文献
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青藏高原东北缘由于受到多个构造块体的共同约束,表现出复杂的地球物理特性和地质特性,本文利用甘肃数字地震台网(2001-2008年)的观测资料,采用系统分析方法(SAM),进行地壳剪切波分裂分析,获得研究区内18个台站共1005条记录的剪切波分裂参数.研究结果表明,青藏高原东北缘介质各向异性在空间上存在差异,慢剪切波延迟时间表明了地壳介质各向异性的强弱变化特征,快剪切波平均偏振方向则反映了本区区域构造应力的空间变化特征.分析认为,祁连山-河西走廊活动构造区直接受青藏地块与阿拉善地块间相互作用,与青藏地块构造应力一致;甘东南活动构造区的应力环境主要受到内部活动断裂的共同作用,具有局部构造应力的特征. 相似文献
10.
The most diagnostic effect of anisotropy on shear waves is shear-wave splitting. This phenomenon creates a distinctive signature in the 3D particle motion. Methods to extract the effects of anisotropy from shear-wave data attempt to measure details of this motion. Many techniques have been published recently which process the shear waves in the time or frequency domain. Here we examine the way in which information on the interference effects between the split shear waves is contained within the frequency domain, and suggest some criteria which may be used in future processing algorithms. The time-delay between the split shear waves, and the polarization direction of the leading shear wave can be converted into easily measured features from analysis of the Fourier spectrum of the shear-wave signal on each component of motion. These features arise in the spectral interference patterns which are formed by the interaction between the two closely-spaced and similar waveforms. The interference patterns are interpreted for synthetic and observed seismogram data. 相似文献
11.
太行山山前断裂西南段地壳介质各向异性特征浅析 总被引:2,自引:0,他引:2
根据太行山山前断裂西南端, 包括石家庄及其周边地区的位于太行隆起与华北盆地两大地质构造单元交汇处的构造环境复杂情况。 该文应用SAM分析方法与首都圈近4年(2002年1月至2005年8月)的观测数据, 分析该区地壳介质各向异性特征。 研究结果表明, 太行山山前断裂西南端快剪切波平均偏振方向与华北区域最大主压应力场方向一致, 是区域应力环境的较好描述。 该区慢剪切波平均时间延迟比较首都圈西北部和东南部均较小。 区内台站的快剪切偏振方向既受到区域构造背景应力环境的作用, 又受到局部的NNE向构造带的制约, 是两者共同作用的结果。 井径(JNX)台站的剪切波分裂参数与紧邻台站有明显不同, 其原因有待更多数据加以补充并做细致讨论。 相似文献
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通过对云南遥测地震台网2000年1月1日——2003年12月31日4年资料的分析, 使用剪切波分裂SAM综合分析方法,获得了云南地区10个数字地震台站的快剪切波偏振结果. 结果表明, 云南地区大部分台站的快剪切波偏振优势方向主要为近N——S或NNW方向; 位于活动断裂上的台站的快剪切波偏振优势方向与活动断裂的走向一致;与GPS主压应变方向一致,与区域主压应力方向基本一致;少数台站的快剪切波偏振较为复杂,或与活动断裂的走向及GPS主压应变方向不一致. 这样的台站总是位于几个断裂的交会处,反映了复杂的断裂背景和复杂的应力分布特征. 快剪切波偏振优势方向代表了原地最大主压应力方向,受到区域应力场和断裂分布等多种因素的控制. 相似文献
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Temporal variations of shear-wave splitting in field and laboratory studies in China 总被引:1,自引:0,他引:1
Observations of shear-wave splitting at seismic stations above a swarm of small earthquakes on Hainan Island, China, and other examples world-wide, suggest that the time-delays of split shear-waves monitor the build up of stress before earthquakes and the stress release as earthquakes occur. Rock physics experiments on marble specimens also show variations of shear-wave time-delays with uniaxial pressure analogous to the field observations. The rock experiments show an abrupt decrease in time-delays immediately before fracturing occurs. Similar precursory behaviour has been observed before earthquakes elsewhere, and is believed to be important for two reasons. Precursory changes in shear-wave splitting could be used for short-term forecasting, but of greater importance may be the information such behaviour provides about the source processes in earthquake preparation zones. 相似文献
14.
There are two main sources of non-orthogonality in multicomponent shear-wave seismics: inherent non-orthogonal split shear waves arising from substantial ray deviation in off-symmetry planes due to strong anisotropy or complex overburden, and apparent non-orthogonal split shear waves in the horizontal plane due to variation of the angle of incidence even if the two shear waves along the raypath are orthogonal. Many techniques for processing shear-wave splitting in VSP data ignore these kinds of non-orthogonality of the split shear waves. Assuming inherent non-orthogonality in zero-offset VSPs, and apparent non-orthogonality in offset VSPs, we derive equations for the four-component data matrix. These can be solved by extending the linear-transform technique (LTT) to determine the shear-wave polarizations in zero-offset and offset VSPs. Both full-wave synthetic and field data are used to evaluate the technique and to examine the effects of non-orthogonal polarized split shear waves. If orthogonality is incorrectly assumed, errors in polarization measurements increase with the degree of non-orthogonality, which introduces a consistent decreasing trend in the polarization measurements. However, the effect of non-orthogonality on the estimation of geophone orientation and time delays of the two split shear waves is small and negligible in most realistic cases. Furthermore, for most cases of weak anisotropy (less than 5% shear-wave anisotropy) apparent non-orthogonality is more significant than inherent non-orthogonality. Nevertheless, for strong anisotropy (more than 10% shear-wave anisotropy) with complicated structure (tilted or inclined symmetry axis), inherent non-orthogonality may no longer be negligible. Applications to both synthetic and real data show that the extended linear-transform techniques permit accurate recovery of polarization measurements in the presence of both significant inherent and apparent non-orthogonality where orthogonal techniques often fail. 相似文献
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通过收集鄂尔多斯块体西缘固定地震台网2010年6月至2017年8月的近场地震资料,选择符合剪切波分裂分析的14个台站记录的共137个有效事件波形,得到了剪切波分裂参数,即快剪切波(简称快波)偏振方向和慢剪切波(简称慢波)时间延迟.结果表明,研究区的快波偏振方向和慢波时间延迟具有明显的分区特征,快波偏振方向主要与构造应力场方向或者断层走向大体一致.鄂尔多斯西缘紧邻块体边界的台站,快波偏振方向自北向南呈现NS、NNE、NE向的变化,与青藏高原东北缘主压应力方向变化基本一致.银川地堑东西两侧的快波偏振方向有差异,东侧区域主要受青藏高原NNE向挤压和黄河-灵武断裂共同影响,而西侧区域可能受到阿拉善块体与鄂尔多斯块体之间的NW方向的主张应力和阿拉善块体内部应力分布的影响;鄂尔多斯块体、阿拉善块体与青藏高原的交汇区快波优势偏振方向为NE向,与青藏高原东北缘主压应力方向一致;海原断裂带及以南区域快剪切波优势偏振方向为WNW向,与断裂走向基本一致,较好的说明了海原断裂带为活跃的活动断裂.构造与断裂分布都是控制快波偏振方向的主要因素,走滑断裂上的台站快波偏振方向与断裂走向一致,表明这些台站主要受到断裂的强烈影响;走滑断裂附近的个别台站快波偏振方向呈现与构造应力场一致的方向,表明几乎没有受到断裂的影响.鄂尔多斯、阿拉善与青藏高原的交汇区平均时间延迟高于其他地区,反映了青藏高原在NE向运动过程中,受到稳定的鄂尔多斯块体阻挡作用,导致了交汇区地壳介质各向异性程度增加.以海原断裂带到六盘山断裂带为界,其两侧区域的各向异性差异性明显,揭示了应力与介质特性的差异,暗示其邻近区域,特别在海原断裂带东端到六盘山断裂带与鄂尔多斯块体西缘交汇区域,可能有较高的强震危险背景.本研究还对该区域的地壳和上地幔的耦合问题进行了初步讨论. 相似文献
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龙门山断裂带上发生了2008年汶川8.0级和2013年芦山7.0级地震,为了研究芦山地震前后该区域地壳各向异性的空间分布和变化,以及较大地震对快剪切波偏振方向造成的影响,本文运用剪切波分裂系统分析方法,结合固定地震台网(2010-01—2017-10)和川西流动地震台阵(2006-10—2009-07)的小震波形数据,得到了龙门山断裂带及邻近地区上地壳各向异性参数.结果表明,慢剪切波时间延迟主要分布在0.65~7.39 ms·km-1之间,横向上具有不均匀性,地壳20 km以上的介质对各向异性的贡献较大.快剪切波优势偏振方向主要为NW或NWW和NE向,具有明显的分区特性.位于龙门山断裂带附近台站的快剪切波偏振方向自北向南由NWW转变为NW、NE向,在南段又变为NWW、NE向,指示了龙门山断裂带的分段特性是其构造属性.根据得到的有效事件数据,本文使用的49个台站中有19个台站的各向异性参数与反方位角、深度、震级和路径长度等显示出一定的相关性.研究区内的芦山地震及其他较大地震可能影响了局部快剪切波偏振方向.研究表明,更多的有效事件数据将有益于定量分析局部构造应力场和断裂属性的变化情况,从而有益于断裂带地震学特性及地震预测研究. 相似文献
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Construction of regional and local seismic anisotropic structures from wide-angle seismic data: crustal deformation in the southeast of China 总被引:10,自引:0,他引:10
We present a method to obtain spatial distributions of seismic anisotropy associated with regional stress and local faulting
in the crust from wide-angle seismic data. The method contains three steps. The first step consists of obtaining radial- and
transverse-component seismic sections using a pre-stack depth migration algorithm from the S-wave velocity model determined
by conventional interpretation of picked intra-crustal seismic events. In the second step, we compute time delays between
split shear-waves and polarizations of fast split shear-waves by minimizing the transverse-component seismic energy. The time
delay and polarization in each layer are derived using a layer-stripping method. The final step is to estimate the average
splitting parameters along the whole profile. Thus, the average time delay and polarization can be regarded as caused by the
effects owing to regional structure and stress fields, whereas the residual values of the splitting parameters are considered
to be related to local structures and local faulting. Our method allows us to construct multi-layer anisotropic images, which
may later be interpreted in terms of intra-layer coupling/decoupling or deformation. We present results from a set of three-component
seismic data acquired by a controlled source experiment in the southeast region of China. The results demonstrate that the
average polarizations and time delays are consistent with the direction and strength of the stress field, and their lateral
variations related to local anisotropy match the spatial distribution of surface faulting crossing the acquisition seismic
profile. 相似文献
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Introduction Anisotropy of the crust is a common phenomenon(Crampin,1984).Shear-wave splitting can be used to study the earthquake anisotropic characteristic in crust,to analyze crustal stress field condition,and to describe the static and the dynamic state of the related anisotropic parameters(GAO et al,1999).Shear-wave splitting is quite sensitive to anisotropy.The domestic scholars applied shear-wave splitting to studying the crustal anisotropy(YAO et al,1992;GAO and FENG,1990).The st… 相似文献
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主要利用辽宁区域地震台网8个台站记录到的1999年6月至2004年12月的波形数据,采用剪切波分裂SAM分析方法,对辽宁地区的剪切波分裂特征进行了研究。发现大部分台站的快剪切波优势偏振方向为NEE(近EW)向,与原地主压应力方向一致,也与华北北部的区域构造应力场方向一致。然而,辽宁中部的SJ台站和东部的KD台站的快剪切波优势偏振方向分别为近NS向和NW向,与其他台站的结果有差异,可能是受到复杂的局部构造的控制和影响,这2个台站的结果还需要更多资料的证实。根据GPS、地震和地球物理等其它资料,对该地区断层的区域分布、主压应力以及剪切波分裂参数的空间分布特征进行了讨论 相似文献
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Upper mantle anisotropy and crust-mantle deformation pattern beneath the Chinese mainland 总被引:5,自引:0,他引:5
WANG ChunYong CHANG LiJun DING ZhiFeng LIU QiongLin LIAO WuLin Lucy M FLESCH 《中国科学:地球科学(英文版)》2014,57(1):132-143
Over the past 10 years,the number of broadband seismic stations in China has increased significantly.The broadband seismic records contain information about shear-wave splitting which plays an important role in revealing the upper mantle anisotropy in the Chinese mainland.Based on teleseismic SKS and SKKS phases recorded in the seismic stations,we used the analytical method of minimum transverse energy to determine the fast wave polarization direction and delay time of shear-wave splitting.We also collected results of shear-wave splitting in China and the surrounding regions from previously published papers.From the combined dataset we formed a shear-wave splitting dataset containing 1020 parameter pairs.These splitting parameters reveal the complexity of the upper mantle anisotropy image.Our statistical analysis indicates stronger upper mantle anisotropy in the Chinese mainland,with an average shear-wave time delay of 0.95 s;the anisotropy in the western region is slightly larger(1.01 s)than in the eastern region(0.92 s).On a larger scale,the SKS splitting and surface deformation data in the Tibetan Plateau and the Tianshan region jointly support the lithospheric deformation mode,i.e.the crust-lithospheric mantle coherent deformation.In eastern China,the average fast-wave direction is approximately parallel to the direction of the absolute plate motion;thus,the upper mantle anisotropy can be attributed to the asthenospheric flow.The area from the Ordos block to the Sichuan Basin in central China is the transition zone of deformation modes between the east and the west regions,where the anisotropy images are more complicated,exhibiting"fossil"anisotropy and/or two-layer anisotropy.The collision between the Indian Plate and the Eurasian Plate is the main factor of upper mantle anisotropy in the western region of the Chinese mainland,while the upper mantle anisotropy in the eastern region is related to the subduction of the Pacific Plate and the Philippine Sea Plate beneath the Eurasian Plate. 相似文献