青藏高原东北缘地壳各向异性的构造含义

青藏高原东北缘记录了印度—欧亚大陆板块碰撞和汇聚的远场效应,且仍正处于侧向生长阶段.而地壳各向异性则反映了高原地壳的形变特征.为此,本文主要利用甘肃数字地震台网(2001年1月—2010年10月)波形记录资料,采用SAM方法进行剪切波分裂研究,得到青藏高原东北缘地壳各向异性的平均剪切波分裂参数及剩余地震各向异性参数,两个参数分别反映了区域构造和应力场特征及局部构造和局部断裂特征.研究结果表明:快剪切波2个优势偏振方向分别为NE47.72°±21.83°和121.65°±22.07°,慢剪切波平均时间延迟为2.63±1.31ms·km-1.快剪切波平均偏振方向反映了该区域的水平主压应力方向,快剪切波偏振方向的第二优势取向揭示了NWW的局部构造意义,表明应力环境受本区NWW深大断裂带的影响.各个台站的剩余快剪切波偏振方向的优势取向与断裂走向一致,表明活动断裂控制着剩余快剪切波偏振方向.剩余慢剪切波时间延迟变化反映了断裂引起地震各向异性程度,形变具有区域特征.     

蒙古中南部地区地壳各向异性及其动力学意义

利用蒙古中南部地区布设的69套宽频带数字地震仪2011年8月—2013年7月记录的远震事件,使用时间域反褶积方法提取接收函数,并挑选高质量Pms震相,通过改进的剪切波分裂方法对研究区地壳各向异性参数进行了研究,最终获取了1473对各向异性参数.经过统计分析,有48个台站可以归纳出两个方向的各向异性,11台站得到单个方向的各向异性,而剩余10个台站各向异性方向比较发散.结果显示,各向异性在蒙古中南部地壳中呈不均匀分布,有54个台站得到了NE-SW向各向异性,快波偏振方向平均值为N58°E±16°,与最大水平主应力σHmax方向和区域内主要断层走向一致,说明这部分地壳各向异性的主要成因存在于上地壳,可能与流体填充的微裂隙有关.而NW-SE向各向异性在53个台站被观测到,各向异性方向变化范围平均N132°E±16°,与研究区大部分SKS分裂快波方向具有较好的一致性,说明下地壳成岩矿物晶体定向排列是各向异性的主要成因.研究区地壳各向异性的分层特征总体上支持岩石圈受到NE-SW向挤压的动力学模型.     

Anisotropic Measurements in the Rhinegraben Area and the French Massif Central: Geodynamic Implications

—As part of an integrated seismic study, polarization of shear waves has been analyzed for teleseismic events recorded at a set of permanent broadband, semi-permanent long- and short-period and temporary short-period seismological stations located in two geodynamically important areas in western Europe, namely the Rhinegraben-Urach area and the French Massif Central volcanic field.¶While for the semi-permanent and the permanent stations there is a good azimuthal coverage of teleseismic earthquakes which allowed us to investigate the azimuthal dependence and the spatial variation over short distances of an anisotropy direction, no even azimuthal distribution of teleseismic recordings with a clear elliptical (or linear) polarization of the S phases could be obtained in the case of the temporary stations.¶While the mean values of the splitting parameters φ and δt are geographically coherent for adjacent stations, our results show a large scatter of the individual splitting parameters for the set of events used. The magnitude of the splitting time suggests that the deformation extends below the lithosphere and that the thickness of the anisotropic structure is at least 100–200 km.¶For some stations located in the Rhinegraben-Urach area (ECH, RG-N, RG-S, RBG), the variations of φ are consistent with a two-layer anisotropic model as suggested by Vinnik et al. (1994) for the South German Triangle. For the stations ECH (Vosges mountains), RG-N and RG-S (Rhinegraben proper), the resulting estimates of fast direction are around N10°E–N30°E and N80°E–N100°E for the upper and lower layers, respectively. For the station RBG (Urach), the results are N60°E–N70°E and N125°E–N135°E, respectively.¶In the Rhinegraben-Urach area, the estimates of the effective fast direction for a one-layer model show a rotation from a graben-related (30°) pattern to an Alpine belt-related pattern in the eastern part (≈ E–W). In the French Massif Central region, the results reveal two distinct fast polarization patterns. While to the west of the Sillon Houiller, φ is parallel to this late-variscan transformlike fault zone and perpendicular to the variscan belt, it is to the east rather perpendicular to the Alpine belt. The results suggest a mixture of both a lithospheric and an asthenospheric component of the seismic anisotropy for the Rhinegraben-Urach as well as for the French Massif Central areas.     

青藏高原东北缘中上地壳介质各向异性及其构造意义

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.     

青藏高原东南缘三江地区上地壳各向异性初步研究

三江地区位于青藏高原东南缘,川滇菱形块体的西侧.受陆-陆板块碰撞作用的影响,构造活动强烈,地震活动频繁.为研究该区的应力环境、构造特征及二者间的关系,本文使用三江流动线性地震台阵SL-Array（2016-12—2017-05）和国家固定地震台网（2015-01—2017-12）记录到的地震波形资料,运用剪切波分裂分析技术研究三江地区上地壳各向异性研究.计算得到该区域快剪切波优势偏振方向为NNW向,与区域主压应力方向一致.结果显示各向异性特征有分区性,以维西—乔后断裂和小金河—丽江断裂为界,将线性台阵划分为A、B和C三个区域.A区快波优势偏振方向表现出与区域主压应力方向的一致性.B区局部构造复杂,快波优势偏振方向表现为近NS向.C区结果比较离散,无明显快波优势方向.自西向东,研究区域快波优势偏振方向表现为NNW至近NS向的变化趋势.计算得到研究区域慢剪切波时间延迟为2.8±1.7 ms·km^-1,其中B区最大,A区最小,反映了该区地壳介质各向异性强度的不均匀分布,也揭示了区域构造复杂程度与地震各向异性强度的关系.     

Looking for layered anisotropic structures in the mantle beneath the northern Apennines

Competing geodynamic scenarios proposed for northern Apennines (Italy) make very different predictions for the orientation of strain in the upper mantle. Constraints on the pattern are offered by observations of seismic anisotropy. Previous study of the anisotropy beneath the northern Apennines used birefringence of core-refracted shear waves (SKS phases), and demonstrated the presence of two domains: Tuscan and Adria. In the transition between the two domains, across the Apennines orogen, anisotropy measurements reflect a complex deep structure. To define better the upper-mantle structure beneath this area we analyze seismological data recorded by a set of seismic stations that operated for 3 years, between 2003 and 2006, located in the outer part of the Apennines belt, in the Adria terrane, collected by the RETREAT Project. Directionally distributed sets of SKS records were inverted for layered anisotropic structures with a well-tested method, adding new results to previous hypotheses for this area. New data analysis argues for two-layer anisotropy for sites located on the Apennines wedge and also one site in the Tuscan terrane. Beneath the wedge an upper layer with nearly north-south fast polarization pervades the lithospheric mantle, while at depth a nearly NW–SE Apennines-parallel direction is present in the lower layer. Beneath Tuscany a shallower NW–SE direction and a deeper E–W one suggest the deeper strain from active slab retreat, with a mantle-wedge circulation (i.e. an east–west corner flow), overlain by an Apennines-parallel fast polarization that could be a remnant of lower-crust deformation.     

中国数字地震台网(CDSN)单台站P波偏振分析

偏振分析可以定量描述地震波的质点运动。P波质点运动在水平方向上发生偏振,使得传播方向会偏离台站与地震震源之间大圆弧的方向。P波偏振分析可以用来约束地下结构以及反映地震各向异性,提供与剪切波分裂等手段不同的证据。本文介绍并使用主成分分析(Principle Component Analysis, PCA)的方法,计算了单一地震台的P波偏振,同时,利用谐和分析,对台站下方的各向异性进行了分析。将P波偏振分析应用到中国数字地震台网(China Digital Seismograph Network, CDSN)的四个台站10年左右的数据,筛选并分析了震相清晰、信噪比高的远震三分量初至P波的质点运动,拟合出四个台站接收到的地震事件后方位角与P波水平偏离角度之间的三角函数曲线,计算出拉萨台、昆明台下方上地幔各向异性的偏振方向分别为66°和57°,大致呈现北东东方向。     

鄂尔多斯块体北缘与西缘地区地壳各向异性特征

本研究使用内蒙古自治区数字测震台网2010年1月至2017年10月区域小地震的波形记录资料,采用SAM方法,进行了地壳剪切波分裂的分析,得到鄂尔多斯块体北缘与西缘地区地壳介质地震各向异性的初步研究结果.根据15个台站161个有效地震记录的分析,鄂尔多斯块体北缘与西缘地区的快剪切波平均偏振方向为NE44.4°±38.4°,慢剪切波平均时间延迟为1.7±1.6ms·km~(-1).研究区域的快剪切波偏振显示出两个优势方向,一个是NE方向,另一个是近NS方向.区内的逆冲凸起与走滑正倾断层构造对剪切波分裂产生了直接的影响,造成了剪切波分裂参数的复杂分布,反映了剪切波分裂参数受到区域应力和构造共同作用的影响.鄂尔多斯块体北缘的快波偏振特征有NE和近NS两个优势偏振方向,其东区与西区的快剪切波偏振表现出明显不同的特征.东区的第一快剪切波优势偏振方向为NE,第二快剪切波优势偏振方向为近NS;西区的第一快剪切波优势偏振方向为近EW,第二快剪切波优势偏振方向为近NS.鄂尔多斯块体北缘的区域背景主压应力方向可能总体上为近NS方向,但空间分布有差异,东区NE方向的优势偏振与西区近EW方向的优势偏振更可能反映了断裂与构造的影响.鄂尔多斯块体西缘的快剪切波偏振特征显示出非常清楚的NE向的优势偏振方向,近NS向的优势偏振方向则不太明显,反映出该地区复杂构造对各向异性分布的影响.慢波时间延迟呈现出西低东高的特点,时间延迟的高值出现在鄂尔多斯块体北缘的东部,时间延迟的这种西低东高的各向异性强度变化,可能反映了区域构造活动西强东弱的特性.     

Seismic anisotropy of upper mantle in eastern Tibetan Plateau and related crust-mantle coupling pattern

By using the polarization analysis of teleseismic SKS waveform data recorded at 116 seismic stations which respectively involved in China National Digital Seismograph Network, and Yunnan, Sichuan, Gansu and Qinghai regional digital networks, and portable broadband seismic networks deployed in Sichuan, Yunnan and Tibet, we obtained the SKS fast-wave direction and the delay time between fast and slow waves of each station by use of the stacking analysis method, and finally acquired the fine image of upper mantle anisotropy in the eastern Tibetan Plateau and its adjacent regions. We analyzed the crust-mantle coupling deformation on the basis of combining the GPS observation results and the upper mantle anisotropy distribution in the study area. The Yunnan region out of the plateau has dif-ferent features of crust-mantle deformation from the inside plateau. There exists a lateral transitional zone of crust-mantle coupling in the eastern edge of the Tibetan Plateau, which is located in the region between 26° and 27°N in the west of Sichuan and Yunnan. To the south of transitional zone, the fast-wave direction is gradually turned from S60°―70°E in southwestern Yunnan to near EW in south-eastern Yunnan. To the north of transitional zone in northwestern Yunnan and the south of western Sichuan, the fast-wave direction is nearly NS. From crust to upper mantle, the geophysical parameters (e.g. the crustal thickness, the Bouguer gravity anomaly, and tectonic stress direction) show the feature of lateral variation in the transitional zone, although the fault trend on the ground surface is inconsis-tent with the fast-wave direction. This transitional zone is close by the eastern Himalayan syntaxis, and it may play an important role in the plate boundary dynamics.     

乌海地区剪切波分裂研究

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。     

Shear-wave splitting in the southeast of Cathaysia block, South China

This study is focused on Fujing Province in China, southeast of Cathaysia block (SECB). The present work benefits from the data provided by the Fujian Seismic Network (FJSN) to study the seismic anisotropy in the crust. By means of a systematic analysis and adequate software package, we examine shear-wave splitting from data recorded at ten FJSN stations during the period January 1999 to December 2003. The results demonstrate that the average fast wave polarization is N109.4° E ± 42.6°, corresponding to the horizontal principal compressive stress in the test zone, and the average normalized slow wave time delay is 2.5 ± 1.5 ms/km. The predominant polarizations at stations in the eastern part of SECB are in the N–W direction, which suggests that they are related to the regional horizontal principal compressive stress and also to the strikes of faults. In contrast, the predominant polarizations at two stations in the western part of SECB are in the N–E direction. This polarization direction does not coincide with the direction of the horizontal principal compressive stress, but it follows the strikes of near faults, thus suggesting the influence of the local tectonics and a change in the stress field. The results prove that the predominant polarizations are parallel to the strikes of faults whenever the stations are on active faults. At a few stations near the coastal line, some polarizations show a certain amount of scatter which may be caused by crossing faults and irregular topography. Finally, the spatial distribution of time delays depicts strong lateral variations near the coast just where the seismic activity is comparatively bigger, so that the magnitude of anisotropy seems to be consistent with the most seismically active area.     

青藏高原东南缘地震各向异性及其深部构造意义

青藏东南缘是青藏高原物质东流的通道,为了更全面了解复杂的岩石圈结构和强烈的变形特征,本文介绍了青藏东南缘岩石圈各向异性的形态,综合其他研究者得到的该区域壳幔各向异性结果,增加了部分新的资料,更新了青藏东南缘岩石圈方位各向异性图像,探讨了区域深部构造意义.
基于近场小震、远震和背景噪声资料计算结果,青藏东南缘地震各向异性展现出独特的区域空间分布和垂向层次性分布形态,展现了3个主要特征.（1）青藏东南缘上地壳各向异性与地表变形测量结果相符,快剪切波偏振方向（即快波方向）呈现与地表运动特征一致的发散性,与主压应力方向一致,但受到地质构造的影响.（2）青藏东南缘下地壳方位各向异性展现了更好的方向一致性,但方位各向异性程度相对较弱,在红河断裂带西北端部和小江断裂带下方有两个下地壳低速区,其方位各向异性程度与上地壳相当.（3）青藏东南缘岩石圈方位各向异性,呈现南、北分区特征,南北分界线大致在26°20'N,快波方向在北部近似为NS方向,在南部近似为EW方向.
本文推测：（1）在26°20'N北侧的上地幔有较厚的高速体,高速体南侧边缘呈现出近EW走向的直立墙形构造,其南侧软弱的上地幔物质在EW方向上流动,导致了岩石圈方位各向异性特征在空间发生突然的变化,快波方向由北部的NS变为南部的EW方向;（2）小江断裂带是现今的华南地块的地壳西边界,但岩石圈尺度的方位各向异性展现出的趋势性表明,华南地块的上地幔物质越过了小江断裂带到达其西侧,揭示了华南地块与青藏地块接触碰撞造成的岩石圈物质变形和上地幔软流圈物质运移的深部图像.地震各向异性能揭示区域深部构造与介质变形的信息,不同观测资料的综合分析有助于获得更清晰的各向异性三维图像.     

Anisotropy beneath the Iberian Peninsula: The Contribution of the ILIHA-NARS Broad-band Experiment

—The presence of anisotropy beneath the Iberian Peninsula and its main distinctive features can be established through the analysis of teleseismic shear-wave splitting observed in the ILIHA-NARS experiment. In this experiment, an homogeneous data set is provided by a network of 14 broad-band stations deployed over the entire peninsula for about one year. Even if technical problems led to an amount of data smaller than expected, significant variations in the inferred fast velocity direction are observed for stations located in different Iberian domains. The stations in Central and East Iberia show a fast velocity direction oriented roughly E–W, coincident with previous results in Toledo. A clearly different NE–SW direction is observed in the Ossa-Morena zone, supporting the image from a previous regional experiment. The observed delay times lie between 0.5 and 1 s. Although large-scale mechanisms, such as the absolute plate motion of Eurasia, can be invoked to explain the origin of anisotropic features in many sites, the regional variations observed in some domains imply that differentiated origins of the anisotropy have to be considered, probably related to the particular tectonics in the area. An interesting example of this fact is provided by the stations in the Betic chain; the fast velocity direction inferred for a station located in the limit of the External Betics (South Iberian domain), oriented N80°E, is clearly different from the N15–35°E direction observed in the Internal Betics (Alboran crustal domain), the origin of which has to be related to the Alpine building of the chain.     

基于背景噪声研究青藏高原东北缘瑞利波相速度和方位各向异性

本研究收集了甘肃、青海、宁夏等118个宽频带数字地震台站的连续波形资料,利用噪声互相关,经过计算和筛选,在5~38 s范围内,共得到5773条瑞利波相速度频散曲线.然后采用1°×1°的网格划分,反演获得青藏高原东北缘相速度和方位各向异性分布.结果表明：短周期8~12 s内,鄂尔多斯从低速异常变为高速异常;该周期范围内各向异性结果与区域断裂走向有很好的一致性.18~25 s周期内,祁连地块、松潘-甘孜地块、羌塘地块低速异常范围逐渐变大,随周期增加地壳低速异常与人工探测结果相符;鄂尔多斯表现为速度随周期增加逐渐变大,说明其中下地壳速度相对偏高,不存在低速异常;该周期范围内的各向异性特征表现为,祁连地块和松潘甘孜地块大致呈NW-SE方向,而青藏高原内部快波方向显示了顺时针旋转的形态.在30~35 s范围内面波速度主要受莫霍面深度和莫霍面附近介质速度的影响,与地壳厚度分布有非常好的吻合.综合不同方法获得的各向异性研究结果,支持印度-欧亚板块的碰撞使青藏高原东北缘地壳发生缩短和逐渐隆升的观点,认为整个岩石圈的垂直缩短变形是青藏高原东北缘的主要形成机制.     

山东地区上地幔各向异性研究

通过分析山东地区数字地震台网37个宽频带地震台站的远震SKS波形资料,使用最小能量法和旋转相关法求得每一个台站的SKS快波偏振方向和快、慢波时间延迟,获得了山东地区上地幔各向异性图像.该研究区的各向异性快波方向基本呈WNW-ESE方向,快、慢波时间延迟为0.73-1.71 s.研究表明,山东地区上地幔存在明显的各向异性...     

青藏高原中部地壳和上地幔各向异性分析

对布设于青藏高原中部INDEPTH-III宽频带数字地震台阵的41个台站记录的远震体波资料所提取出的P波接收函数和SKS波形资料做偏振分析,并采用以误差为权的叠加分析方法求得每一个台站的Pms和SKS快波偏振方向和快慢波的时间延迟,获得了从拉萨块体中部,经喀喇昆仑-嘉黎断裂系和班公湖-怒江缝合带,到羌塘块体中部的地壳和...     

腾冲地区近震S波分裂研究

本文利用布设在云南腾冲地区的15个固定和流动地震台站记录的近震波形数据,采用剪切波分裂分析方法得到了593对高质量的各向异性分裂参数.结果显示,腾冲火山区地震台站下方的近震各向异性的慢波延迟时间为0.02～0.37 s,平均延迟时间0.2 s.结合已有接收函数地壳各向异性研究结果,推测研究区地壳各向异性的主要贡献源自中上地壳.研究区不同台站的快波偏振方向变化很大,似乎反映了构造和区域应力场的共同作用.其中腾冲火山断裂西侧多数台站的快波偏振方向呈近N-S向,而东部多数台站的快速偏振方向呈NE-SW向,与区域主压应力方向一致,暗示研究区中上地壳各向异性主要是受主压应力引起定向排列的裂隙所致.基于近震走时得到的研究区平均V_P/V_S为1.68,推测腾冲火山区地壳应力场的局部变化可能与上地壳中富含气体的中酸性岩浆膨胀活动有关.另一方面,在腾冲火山区外围个别台站(MIZ、MZT)观测到了快波偏振方向与主压应力、已知断层等构造走向不一致的现象,暗示其各向异性是构造或构造和区域应力场共同作用的结果.     

Shear wave splitting analysis of local earthquakes from dense arrays in Shimian,Sichuan

The Shimian area of Sichuan sits at the junction of the Bayan Har block, Sichuan-Yunnan rhombic block, and Yangtze block, where several faults intersect. This region features intense tectonic activity and frequent earthquakes. In this study, we used local seismic waveform data recorded using dense arrays deployed in the Shimian area to obtain the shear wave splitting parameters at 55 seismic stations and thereby determine the crustal anisotropic characteristics of the region. We then analyzed the crustal stress pattern and tectonic setting and explored their relationship in the study area. Although some stations returned a polarization direction of NNW-SSE, a dominant polarization direction of NW-SE was obtained for the fast shear wave at most seismic stations in the study area. The polarization directions of the fast shear wave were highly consistent throughout the study area. This orientation was in accordance with the direction of the regional principal compressive stress and parallel to the trend of the Xianshuihe and Daliangshan faults. The distribution of crustal anisotropy in this area was affected by the regional tectonic stress field and the fault structures. The mean delay time between fast and slow shear waves was 3.83 ms/km, slightly greater than the values obtained in other regions of Sichuan. This indicates that the crustal media in our study area had a high anisotropic strength and also reveals the influence of tectonic complexity resulting from the intersection of multiple faults on the strength of seismic anisotropy.     

Upper crustal deformation characteristics in the northeastern Tibetan Plateau and its adjacent areas revealed by GNSS and anisotropy data

The northeastern part of the Tibetan Plateau is a region where different tectonic blocks collide and intersect, and large earthquakes are frequent. Global Navigation Satellite System(GNSS) observations show that tectonic deformation in this region is strong and manifests as non-uniform deformation associated with tectonic features. S-wave splitting studies of near-field seismic data show that seismic anisotropy parameters can also reveal the upper crustal medium deformation beneath the reporting...     

用接收函数Ps转换波研究地壳各向异性--以哀牢山-红河断裂带为例

倾斜界面与各向异性介质均可使接收函数的切向分量产生明显的能量.通过对不同模型的理论接收函数的研究,可以发现倾斜界面产生的接收函数切向分量与各向异性介质产生的接收函数切向分量具有显著的差异,主要表现在到时差与周期性上.利用各向异性和倾斜界面造成的切向分量不同的周期性,可以通过加权叠加的方法突出各向异性或倾斜界面的影响,并可对接收函数径向、切向分量进行波形互相关计算,获取各向异性分裂参数.通过对布设于红河断裂附近的4个三分量宽频带流动台站的接收函数莫霍面Ps震相的研究,获得红河断裂附近的地壳各向异性快波方向为132°,快慢波时间延迟为024s.地壳各向异性快波方向与红河断裂带构造走向一致,与上地幔各向异性的快波方向相差近90°,表明红河断裂地区地壳与上地幔构造可能存在解耦现象.