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地壳介质剪切波分裂研究的部分进展 总被引:1,自引:0,他引:1
剪切波穿过各向异性介质传播时会发生分裂现象,而在地壳中产生各向异性的主要因素是大量充满液体的定向排列的微裂隙。通过剪切波分裂参数可以研究地壳介质的特性、地壳应力状态及应力场的变化,并可用于地震预测。利用地壳介质各向异性特征研究断层性质也是一个新的动向。 相似文献
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《地球物理学进展》1991,(4)
就加利福尼亚Cajon山口深科学钻孔而言,由垂直地震剖面获取了剪切波记录,进而采用各种方法研究了剪切波分裂。这些使用的方法应该允许我们使用一个六角形对称并有一个水平对称轴的系统探测由可能的各向异性产生的(AI)剪切波分裂。对直达剪切波的精心研究后得出的结论是:AI型剪切波分裂观测结果竟然和用常规的观测不到AI型剪切波分裂的简单系统的结果相吻合,没有观测到AI剪切波分裂的原因部分地是由于该区域最大最小主应力的差异太小。因此使裂隙组和微裂隙组在垂向排列上变得很不明显。该区域剪。该区域剪切波的传播和偏振也许更受复杂的地质因素控制而不是受现在应力场的制约.显然。没有检测到AI剪切波分裂并不意味著介质就是各向同性;偏振图提供的剪切波分裂的明显证据表明的是一个高阶的各向异性。 相似文献
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根据乌海地区构造环境,采用SAM方法研究乌海地区地壳各向异性特征,使用乌海地震台2014年1月至2020年6月数字地震波形进行分析。根据65个有效地震记录,得到乌海地区剪切波分裂参数,其中快剪切波平均优势偏振方向为NE63.1°±46.4°,慢剪切波平均时间延迟为(1.13±0.66)ms/km。乌海地震台快剪切波偏振显示出4个优势偏振方向,分别为NE、EW、NNE、NNW向。将得到的各向异性结果与研究区应力场和地质构造进行分析,认为研究区周边复杂的剪切波分裂变化是主压应力场、原地主压应力、断裂带分布共同作用的结果。 相似文献
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本文通过对2006—2009年四川紫坪铺水库库区8个地震台站记录的地震事件,采用剪切波分裂方法获得了水库库区剪切波分裂参数,并结合地震活动性与水库水位之间的变化关系,分析了紫坪铺水库库区地壳应力的变化特征.剪切波分裂结果显示该研究区域快波偏振方向有两个,分别为北东向和北西向,充分体现了紫坪铺水库地区地壳应力是由北西向的区域主压应力与南东走向的龙门山断裂带综合作用的结果.慢波延迟时间平均值为5.8ms·km-1,慢波延迟时间较大的地区位于库坝和库尾,分别是水库蓄水排水引起地壳应力变化最大的区域.对比慢波延迟时间的变化和水库水位的变化显示了慢波延迟时间与水库水位之间的一致变化关系,揭示了水库的蓄水排水对地壳应力的影响. 相似文献
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本研究利用四川紫坪铺水库数字地震台网2004年8月17日~2008年5月11日的地震观测波形资料,使用剪切波分裂SAM系统分析方法,获得了四川紫坪铺水库库区8个数字地震台站的快剪切波偏振结果.结果表明,紫坪铺库区台站的快剪切波偏振优势方向主要为NE或NW方向;台站的快剪切波偏振优势方向与区域主压应力方向或活动断裂走向一致;快剪切波偏振方向变化可能与汶川大地震前区域应力场的增加和龙门山断裂带微破裂增加有关,慢剪切波时间延迟的变化与四川紫坪铺水库水位升降变化相关. 相似文献
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地震剪切波分裂(SWS)可用来监测饱和流体微裂纹岩石的细微形变。本文报告了由小地震记录到的剪切波分裂系统性变化的证据,通过监测震前的应力积累可预测即将发生的大震的时间和震级。通过对冰岛西南部的M1.7级震群事件到台湾Ms7.7级集集地震等15个震例(其中包括成功预测的冰岛西南部的M5.0地震)的剪切波分裂研究,可以看到预测效果。大地震发生前观测到剪切波分裂时间延迟会明显增加,而临震前短时间内时间延迟会突然下降。研究表明,震级与临震前这种时间延迟增加的持续时间和减小的持续时间的对数都具有线性相关。然而,作为日常应力预测常缺乏适当的持续小震群。可靠的地震预测需要应力监测站(简称SMS)中采用毗邻钻孔中的可控源井间地震技术。利用应力监测站的全球网络实时应力预测世界范围破坏性地震是非常可能的。 相似文献
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破裂临界状态下大理岩的剪切波分裂特征 总被引:4,自引:2,他引:2
以山东莱州大理岩为样品对岩样在破裂临界状态下的剪切波分裂特征进行了观测和分析,在两个样品上,得到破裂临界状态下的系列记录,结果表明,在岩石崩溃之前的临界状态下,即使载荷不变,剪切波分裂时间延迟也可能会有涨落现象,即剪切波分裂时间延迟可能会有一个下降的过程。 相似文献
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1992年1月海南省东方县发生小震群活动,本文利用在震中附近设立的5台DCS-302数字磁带加速度地震仪记录的近场资料,进行了剪切波分裂的研究采用相关函数方法,通过对18个做了精确定位的地震事件共42条有效记录的分析,计算出了快剪切波的偏振方向为113°±18O°,慢剪切波的时间延迟为(3.1±1.1)ms/km,裂隙密度的平均值为0.0097±0.0033.结合该地区的地震活动性,分析了区域应力变化对时间延迟的影响,并根据EDA理论讨论了分裂剪切波的时间延迟的变化特征,发现快、慢剪切波的到时差(时间延迟)随地震活动性及应力积累而变化,并推断出该区的主压应力场为北西西方向. 相似文献
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V. Babuska J. Plomerova L. Vecsey P. Jedlicka B. Ruzek 《Studia Geophysica et Geodaetica》2005,49(3):423-430
Research on high-resolution tomography, three-dimensional anisotropy modelled from shear-wave splitting and P-residual analysis, as well as receiver function interpretation, are in progress with the aim to image the crust and uppermost mantle velocities in the Bohemian Massif. Structure of the deep lithosphere and location of boundaries of mantle domains will be compared with tectonics of the crust and limits of terranes derived by geologic and palaeomagnetic methods. 相似文献
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青藏高原东北缘(94°E—105°E,32°N-40°N)是高原北东向扩张的前沿地带,亦是研究高原生长过程的重要区域.本文利用青海省数字地震台网(2008-2014年)共7年的地震目录和波形数据,首先使用双差定位获取精定位震源位置,在此基础上,挑选位于S波窗口内(射线入射角≤45°)的地震事件,依据S波分裂分析方法(SAM),获取研究区域内共26个台站的S波分裂参数.研究结果表明:地处多个块体交汇部位的西宁及其周缘,地壳各向异性呈现两个优势偏振方向,表明该区中上地壳应力环境由区域主压应力场和活动断层共同约束;玉树地震序列的地壳各向异性优势偏振方向与区域主压应力场一致. 相似文献
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In 25 years, the presence of azimuthally varying seismic anisotropy throughout the Earth’s crust has progressed from general
denial to universal acceptance, so that many international geophysical meetings now have sessions on seismic anisotropy. Over
this period, the proceedings of the biennial series of International Workshops in Seismic Anisotropy (IWSAs) have captured
many of the notable advances in the theory, calculation, observation and interpretation of particularly shear-wave splitting
(seismic birefringence) in the Earth’s crust. Shear-wave splitting is the almost-infallible indicator of seismic anisotropy
along the ray path. This paper reviews 13 IWSA meetings (0IWSA–12IWSA) as a catalogue of 25 years of progress in seismic anisotropy.
The evidence now suggests that shear-wave splitting monitors the low-level pre-fracturing deformation of the stress-aligned
fluid-saturated microcracks pervading almost all in situ rocks in the crust. Shear-wave splitting indicates that microcracks
are so closely spaced they are critical systems with all the universality, calculability, predictability, “butterfly wing’s”
sensitivity, and deterministic chaos that that implies. This leads to a New Geophysics, where low-level deformation can be
monitored with shear-wave splitting, future behaviour calculated–predicted with the anisotropic poro-elastic model of rock
evolution, and in some circumstances even potentially controlled by feedback. We anticipate the New Geophysics will greatly
invigorate IWSA. 相似文献
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The collision of the Indian and Eurasian plates, to the east of the eastern Himalayan syntaxes, forms the Sanjiang lateral collision zone in the southeast margin of the Tibetan Plateau, where there are intense crustal deformation, active faults, earthquakes, as well as a metallogenic belt. Given the lack of adequate seismic data, shear-wave splitting in this area has not been studied. With seismic data from a temporary seismic linear array, as well as permanent seismic stations, this paper adopts the identification on microseismic event to pick more events and obtains shear-wave splitting parameters from local earthquakes. From the west to the east, the study area can be divided into three subzones. The “fast” polarization (i.e. the polarization of the fast shear wave) varies gradually from NNW to NS to NNE in these three subzones. The time delay of the slow shear wave (i.e. the time difference between the two split shear waves) also increases in the same direction, indicating the presence of seismic anisotropy above 25 km in the crust. Both shear-wave splitting parameters are closely related to stress, faults and tectonics. The scatter and the “dual” (i.e. two) dominant orientations of the fast polarizations at several stations indicate strong distortions caused by nearby faults or deep tectonics. The anisotropic parameters are found to be related to some degree to the metallogenic belt. It is worth to further analyse the link between the anisotropic pattern and the metallogenic area, which suggests that shear-wave splitting could be applied to study metallogeny. This paper demonstrates that the identification on microseismic event is a useful tool in detecting shear-wave splitting details and exploring its tectonic implications. 相似文献
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M. Pohl. F. Wenzel T. Weiss S. Siegesmund T. Bohlen W. Rabbel 《Pure and Applied Geophysics》1999,156(1-2):139-155
—The genesis of the laminated lower crust has been attributed to extensional processes leading to structural and textural ordering. This implies that the lower crust might be anisotropic. Laboratory measurements of lower crustal rock samples and xenolithes show evidence of anisotropy in these rocks due to oriented structure.¶In this paper we investigate the seismic shear-wave response of realistic anisotropic lower crustal models using the anisotropic reflectivity method. Our models are based on representative petrophysical data obtained from exposed lower crustal sections in Calabria (South Italy), Val Strona and Val Sesia (Ivrea Zone, Northern Italy). The models consist of stacks of anisotropic layers characterized by quantified elastic tensors derived from representative rock samples which provide alternating high and low velocity layers.¶The seismic signature of the data is comparable to seismic observations of in situ lower crust. For the models based on the Calabria and Val Strona sequences shear-wave splitting occurs for the Moho reflection at offsets beyond 70 km with travel-time delays up to 300 and 500 ms, respectively. The leading shear wave is predominantly horizontally polarized and followed by a predominantly vertically polarized shear wave. Contrastingly, the Val Sesia model shows no clear evidence of birefringence. Isotropic versus anisotropic modelling demonstrates that the shear-wave splitting is clearly related to the intrinsic anisotropy of the lower crustal rocks for the Val Strona sequence. No evidence of birefringence caused by thin layering is found. 相似文献
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On April 20, 2013, the Lushan Ms7.0 earthquake struck at the southern part of the Longmenshan fault in the eastern Tibetan Plateau, China. The shear-wave splitting in the crust indicates a connection between the direction of the principal crustal compressive stress and the fault orientation in the Longmenshan fault zone. Our relocation analysis of the aftershocks of the Lushan earthquake shows a gap between the location of the rupture zone of the Lushan Ms7.0 earthquake and that of the rupture zone of the Wenchuan Ms8.0 earthquake. We believe that stress levels in the crust at the rupture gap and its vicinity should be monitored in the immediate future. We suggest using controlled source borehole measurements for this purpose. 相似文献
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天山构造带位于中国大陆西北部,是典型的岩石圈陆内缩短造山带.本文利用新疆区域数字地震台网2009年1月至2014年12月的近场小地震波形资料,采用剪切波分裂分析对天山构造带及邻区的地壳各向异性特征进行研究,获得了研究区域内39个台站的快剪切波偏振方向和慢剪切波时间延迟.剪切波分裂参数的空间特征显示,研究区上地壳各向异性具有分区性,各向异性特征与局部构造、地壳介质变形和应力分布有关.天山构造带的快剪切波偏振呈现出两个优势方向的特点,第一优势方向大致平行于台站附近断裂和天山构造带的走向,与断裂构造和应力的综合影响有关,另一个优势方向反映了主压应力的直接作用.北天山山前断裂带东段的断裂弯折部位和南天山局部地区的剪切波分裂参数与东、西两侧不同,与准噶尔盆地、塔里木盆地的南北向挤压作用密切相关.快剪切波偏振优势方向的剧烈变化揭示,在准噶尔盆地和塔里木盆地双向挤压隆起的过程中,天山构造带产生了强烈的局部不均匀变形.塔里木盆地西侧快剪切波偏振具有两个优势方向,一个为NNE方向,与帕米尔高原受到印度一欧亚板块碰撞产生的北向挤压作用有关,另一个为NW方向,指出了塔里木盆地区域主压应力方向.准噶尔盆地北部也存在NE和NW两个快波偏振优势方向,主要与断裂的影响有关.天山构造带区域内的慢剪切波时间延迟总体上低于塔里木盆地西侧和准噶尔盆地北部,同时慢剪切波时间延迟的结果也进一步证实了天山构造带的局部强烈变形. 相似文献
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利用甘肃和青海两省固定宽频带地震台记录的远震波形资料,挑选高质量SKS震相,联合使用最小切向能量方法和旋转互相关方法获得230对高信噪比分裂参数;同时对接收函数中Pms震相随方位角的变化进行拟合,得到了24个台站的地壳各向异性分裂参数.整个区域SKS分裂快波方向均值为123°,Pms分裂快波方向均值为132°,且大部分区域SKS、Pms快波方向与地表构造走向相一致,说明青藏高原东北缘以岩石圈垂直连贯变形为主,地壳上地幔相互耦合.SKS、Pms分裂时差均值分别为1.0s和0.6s,显示地壳各向异性对于SKS分裂时差有较大贡献.昆仑断裂附近Pms、SKS分裂快波方向与昆仑断裂走向基本一致,说明昆仑断裂可能是岩石圈尺度深大断裂;而阿尔金断裂东缘二者快波方向显著差异意味着阿尔金断裂在东缘可能仅为地壳尺度的断裂. 相似文献