中国大陆及其邻域地壳上地幔速度结构的面波层析成像研究.

利用中国数字化地震台网（CDSN）11个台站和IRIS在中国周边的12个数字地震台站的长周期瑞利面波资料，根据面波群速度层析成像方法反演得到的10～92ｓ周期范围内的25个中心周期的群速度分布资料，用光滑约束的遗传算法反演得到了中国大陆及其邻域的地壳上地幔横波三维速度结构；给出了沿北纬30、38两条东西向剖面和沿东径90、120两条南北向剖面的地壳上地幔横波速度结构，并在４个不同深度的水平切片上展示了中国大陆及邻域的横波速度分布图象．      

中国大陆及其邻域的瑞利波群速度分布图象与地壳上地幔速度结构

利用中国数字化地震台网（CDSN）11个台站和周边地区的11个IRIS数字化地震台站记录的长周期面波资料,用多重滤波方法测定了在647条不同路径上周期从10～92ｓ的基阶瑞利波群速度频散曲线．采用Dimtar Yanovskaya方法,反演得到北纬18～54、东经70～140范围内,25个中心周期的群速度分布图象．结果表明：在10～15.9s周期范围内,群速度分布存在着明显的横向不均匀性．其分区分块特征与大地构造单元有着密切的对应关系,两个明显的低速区域分别位于塔里木盆地和东海及北部邻域;从21～33ｓ逐渐显示出深部构造块体的格局;在36.6～40ｓ周期附近的群速度分布图象中,十分清晰地显示出中国大陆岩石圈结构的分区特征,南北地震带、青藏高原、华北、华南块体及东北地块的边界非常明显．本文给出了沿30N、38N 纬线和沿90E、120E 经线剖面的群速度随周期分布图象．在这些剖面上,较明显地展示出中国大陆及其邻域地壳上地幔速度结构的基本特征．各构造块体的深部速度结构差异较大,在青藏高原东部地区的地壳中部存在局部低速区域;塔里木盆地、扬子地台的上地幔速度较高,显示出稳定地台特征;华北平原上地幔低速层的埋深浅、厚度大;东海及日本海的上地幔速度较低,这可能与菲律宾板块下插产生的摩擦热与喜山期以来受强烈拉张有密切的关系．     

中国西部地区地壳上地幔S波速度结构

利用10～184 s基阶瑞利波频散曲线反演得到了中国西部及邻近区域地壳上地幔(0～300 km)的S波速度结构.反演采用了传统的两步法,即通过时频分析获得频散曲线后,首先利用Occam方法反演出各周期面波速度在二维网格结点上的分布,然后反演每个结点下方的S波速度结构,从而给出研究区域的三维速度结构.     

中国北部及其邻区地壳上地幔三维速度结构

In this paper,an inversion has been made of 3D S-wave velocity structure of crust and upper mantle in the northern China and its adjacent areas from long and middle period Rapleigh wave data respectively.The results show that the lateral inhomogeneity is very evident in crust,the characteristics of the active tectonics areshown in many district,but the leteral change of uppe mantle velocity structure has been lessened relatively.The crustal thickness In the studied region increases gradually from eastto west.The crustal average veloclty distribution framework corresponds with the distribution of the crustal thickness.The abrupt variation belt of crustal thickness and average velocity are basically identical with the distribution tendency of gradient belts of Bouguergr avity anomaly.From the value variation,the identity of Bouguer gravity anomaly and crustal thickness distribution is much higher than that of gravity anomaly and average velocity.Therefore,we candetermine that the fluctuation of Moho discontinuity is the main factor controlling Bouguer gravity anomaly.     

中国北部及其邻区地壳上地幔三维速度结构

本文利用中周期和长周期瑞利面波资料分别反演得到中国北部及其邻区的三维Ｓ波带度结构。结果表明，地壳中横向非均匀性非常明显，许多地区显示出构造活动的特征；上地幔速度结构的横向变化相对减小。研究区的地壳厚度从东向西逐渐增大，地壳平均速度分布的格局与地壳厚度分布大体一致。地壳厚度与地壳平均速度的空变带处与布格重力异常梯级带基本一致。从数据上看，地壳厚度远比地壳平均速度与布格重力异常的一致性程度高，因此可以     

华北地区地壳上地幔速度各向异性研究

本文介绍面波反演得到的华北地区地壳上地幔速度各向异性分布图像,并与S波分裂的结果作初步的定性比较.不同周期瑞利波群速度的方位各向异性图像呈现显著的横向变化,与华北地区地壳上地幔的构造分块和垂直分层结构有比较密切的联系.在鄂尔多斯和阿拉善等稳定地块中,岩石圈地幔到160 km深度都保持比较一致的显著各向异性;而在发生过岩石圈减薄的华北克拉通东部,大约80~150 km深度范围内基本没有探测到方位各向异性,可能说明岩石圈减薄过程抹去了原有的各向异性印迹而且没有显著的水平构造运动造成新的方位各向异性.地球介质的各向异性具有明显的分层特征,面波的反演结果是如此,而S波分裂测量所表现的离散性,也可能是由各向异性的分层差异和倾斜的各向异性对称轴等因素引起.采用多层的各向异性模型,在多数情况下可以定性地解释面波反演和S波分裂结果之间的差异.进一步的工作要求增大面波的探测深度和改善分辨能力,获取更多的S波分裂测量资料,从而建立定量或半定量的三维各向异性模型.     

用数字台网的面波资料研究中国大陆的地壳上地幔结构

本文采用适配滤波频时分析技术对中国数字地震台网记录的长周期面波资料进行处理,获得了路经中国大陆的23条波路径的基阶瑞雷面波群速度频散曲线,频散曲线的周期从10.5秒至150秒。使用HARKRIDER面波反演程序反演了各条波路径的平均地壳上地幔结构。所得模型直至230km。深处仍有较好的分辨。根据所得结果将中国大陆划分为四个构造单元。各构造单元之间差异明显且在某些单元内部横向变化也很显著。     

根据环境地震噪声和远震瑞雷波分析得到的台湾海峡地壳和上地幔S波速度结构

虽然台湾西部的造山运动逐渐减弱,但台湾海峡的确还发生大、小地震。主要由于后勤原因,以前的研究基本没触及该地区。然而该地区的整体地壳构造具有特殊意义,因为它可能提供造山运动之前原始台湾的线索。通过将使用台站对从环境地震噪声提取的时域经验格林函数（TDEGF）与传统面波双台法（TS）相结合,我们能构建出5～120s之间的瑞雷波相速度频散曲线。使用台湾和海峡两岸的台湾宽频带地震台阵（BATS）的台站,我们能够获得该地区不同地方的平均一维Vs结构。如预期所料,结果显示在地壳上部15km内有显著的剪切波速度差异。总的来说,中国大陆沿海地区上地壳和台湾岛西南海域上地壳分别出现最高Vs和最低Vs,它们相差约0．6～1．1km／s。对于海峡的不同地方,海峡中部上地壳Vs结构比北部和南部低约0．1～0．2km／s。台湾海峡地下的上地幔Vs结构（莫霍面-150km）比AK135模型低约0．1～0．3km／s。整体地壳厚度约为30km,比台湾岛下的地壳厚度更薄且变化更小。使用水深超过1000m海域中的短周期频散数据反演地震波速度结构除大陆架外还应将水层考虑进去。     

渤海湾盆地及其邻域地区地壳与上地幔层析成像

渤海湾盆地及其周边地区蕴藏着丰富的油气资源, 同时也是现代板内地震比较活跃的地区之一. 尽管该研究区的构造背景非常复杂, 但通过前人多年的研究和工作, 积累了丰富的地质、地球物理和地球化学资料. 在吸收和学习前人的这些成果, 特别是各种地质、地球物理研究成果的基础上, 收集1978~2004年间研究区内发生的近震和区内台站所记录到的部分远震的P波震相到时, 在对这些数据进行了相关处理并建立了研究区的初始速度模型后, 利用层析成像技术揭示了研究区的地壳和上地幔的速度结构. 最后, 对比和分析了各个主要深度层和剖面的速度扰动图像, 结果显示: 渤海湾及其周边地区的地壳速度结构受地表主要构造单元和深大断裂的影响, 速度扰动异常大多为NE-NNE向展布, 具有“东西分带, 南北分块”的特点; 区内的深大断裂带, 切穿莫霍面乃至岩石圈, 成为地幔热物质上涌或基性物质上涌的通道.     

中国东部海域地壳-上地幔瑞利波速度结构研究

为了进一步了解中国东部沿海及相邻海域的地壳－上地幔结构特征,对该区域的构造演化历史、地震活动及深部构造等方面研究提供一些基础资料,利用３１个数字地震台记录的高质量瑞利波资料,采用一种新的混合路径频散的网格反演方法（Ｏｃｃａｍ方法）,对中国东部海域瑞利波群速度横向不均匀分布进行了初步研究．根据反演得到的１０—１５０ｓ共３６个中心周期的群速度分布特征,以及几个典型地点的剪切波速度结构的深度变化,对研究区域内各构造单元的划分以及它们在速度结构和上地幔低速层埋深等方面的特征进行了讨论。     

Shear wave velocity structure of the crust and upper mantle underneath the Tianshan orosenic belt

From April,2003 to September,2004,a passive broadband seismic array consisting of 60 stations was deployed over the Tianshan orogenic belt by State Key Laboratory of Earthquake Dynamics,Institute of Geology,China Earthquake Administration.Among them,51 stations make up an about 500-km-long profile across the Tianshan Mountains from Kuytun to Kuqa.The receiver function profile and S-wave velocity structure of the crust and upper mantle down to 100 km deep are obtained by using the receiver function method (Liu et al.1996,2000).The main results can be summarized as follows:(1) A clear mountain root does not exist beneath the Tianshan Mountains,and the crust-mantle boundaries underneath the stations mostly have transitional structures.This implies that the material differentiation between the crust and mantle is not yet accomplished and the orogenic process is still going on.(2)The crust beneath the Tianshan Mountains has laterally blocked structures in direction perpendicular to the mountain strike,and the crust-mantle boundary has a clear dislocation structure.Both of them correspond to each other.(3)The offsets of the Moho discontinuity are highly correlated to the tectonic borders on the surface and that corresponding to the frontal southern Tianshan fault reaches to 14 km.This manifests that large vertical divergent movement took place between different blocks.This supports the discontinuous model of the Tianshan orogeny,and the Tarim block subduction is restricted only to the southern side of the South Tianshan.(4)Inside the upper and middle crust of the Tianshan Mountains exist several low-velocity bodies correlated with high seismicity located on the mountain-basin jointures on both sides of the mountain and between different blocks,and the low-velocity bodies on the mountain-basin jointures are inclined obviously to the mountain.This implies that the low-velocity bodies may be correlated closely to the thrust and subduction of the basins on both sides of the mountain,the splicing of adjacent blocks and the fast uplift of the Tianshan Mountains.     

Shear wave velocity structure of the crust and upper mantle underneath the Tianshan orogenic belt

From April, 2003 to September, 2004, a passive broadband seismic array consisting of 60 stations was deployed over the Tianshan orogenic belt by State Key Laboratory of Earthquake Dynamics, Institute of Geology, China Earthquake Administration. Among them, 51 stations make up an about 500-km-long profile across the Tianshan Mountains from Kuytun to Kuqa. The receiver function profile and S-wave velocity structure of the crust and upper mantle down to 100 km deep are obtained by using the re-ceiver function method (Liu et al. 1996, 2000). The main results can be summarized as follows: (1) A clear mountain root does not exist beneath the Tianshan Mountains, and the crust-mantle boundaries underneath the stations mostly have transitional structures. This implies that the material differentia-tion between the crust and mantle is not yet accomplished and the orogenic process is still going on. (2) The crust beneath the Tianshan Mountains has laterally blocked structures in direction perpendicular to the mountain strike, and the crust-mantle boundary has a clear dislocation structure. Both of them correspond to each other. (3) The offsets of the Moho discontinuity are highly correlated to the tectonic borders on the surface and that corresponding to the frontal southern Tianshan fault reaches to 14 km. This manifests that large vertical divergent movement took place between different blocks. This sup-ports the discontinuous model of the Tianshan orogeny, and the Tarim block subduction is restricted only to the southern side of the South Tianshan. (4) Inside the upper and middle crust of the Tianshan Mountains exist several low-velocity bodies correlated with high seismicity located on the moun-tain-basin jointures on both sides of the mountain and between different blocks, and the low-velocity bodies on the mountain-basin jointures are inclined obviously to the mountain. This implies that the low-velocity bodies may be correlated closely to the thrust and subduction of the basins on both sides of the mountain, the splicing of adjacent blocks and the fast uplift of the Tianshan Mountains.     

Three dimensional shear wave velocity structure of the crust and upper mantle beneath China from ambient noise surface wave tomography

We determine the three-dimensional shear wave velocity structure of the crust and upper mantle in China using Green's functions obtained from seismic ambient noise cross-correlation.The data we use are from the China National Seismic Network,global and regional networks and PASSCAL stations in the region.We first acquire cross-correlation seismograms between all possible station pairs.We then measure the Rayleigh wave group and phase dispersion curves using a frequency-time analysis method from 8 s to 60 s.After that,Rayleigh wave group and phase velocity dispersion maps on 1° by 1° spatial grids are obtained at different periods.Finally,we invert these maps for the 3-D shear wave velocity structure of the crust and upper mantle beneath China at each grid node.The inversion results show large-scale structures that correlate well with surface geology.Near the surface,velocities in major basins are anomalously slow,consistent with the thick sediments.East-west contrasts are striking in Moho depth.There is also a fast mid-to-lower crust and mantle lithosphere beneath the major basins surrounding the Tibetan plateau (TP) and Tianshan (Junggar,Tarim,Ordos,and Sichuan).These strong blocks,therefore,appear to play an important role in confining the deformation of the TP and constraining its geometry to form its current triangular shape.In northwest TP in Qiangtang,slow anomalies extend from the crust to the mantle lithosphere.Meanwhile,widespread,a prominent low-velocity zone is observed in the middle crust beneath most of the central,eastern and southeastern Tibetan plateau,consistent with a weak (and perhaps mobile) middle crust.     

华北地区地壳上地幔三维P波速度结构

利用华北地震科学台阵和首都圈地震台网记录的4511次近震和625次远震的P 波到时数据,采用纬度和经度方向分别为0.5deg;times;0.5deg;的网格划分,反演得到了华北北部地区（111deg;E——120deg;E,37deg;N——42deg;N）深至400km 的地壳上地幔三维P 波速度结构.层析成像结果表明,研究区的速度存在明显的横向不均匀性,随着深度增加横向不均匀性总体呈现减弱趋势.燕山隆起带在60——120km 深度内存在明显的高速异常,这与较大的岩石圈厚度有关;山西裂陷盆地、华北平原下方60km 深度存在明显低速异常,与软流圈的出现有关.燕山隆起带岩石圈厚度在120km 以上,明显比太行山隆起的岩石圈厚度大,与稳定大陆地区的岩石圈厚度一致.太行山山前断裂已切穿莫霍面,贯入岩石圈.研究区上地幔顶部大范围的低速异常反映了软流圈上隆的特点.在华北平原及燕山隆起下方200——300km 存在高速异常可能与太古代大陆板块岩石圈的残留体有关.     

3-D velocity structure of P wave in the upper mantle beneath southwestern China and its adjacent areas

IntroductionSouthwestern China and its adjacent areas studied in the paper is the range of 10(N-36(N, 70(E-110(E, which includes southwestern areas of China (Sichuan, Xizang, Yunnan, Guizhou, Guangxi Provinces, southwestern Shaanxi Province and so on), India, Myanmar, Thailand, Vietnam, Laos and Cambodia countries and oceanic areas of Bay of Bengal and Beibu Gulf. The collision and extrusion of India plate and Eurasia plate makes the geological tectonic complex in this area (Figure 1…     

Upper mantle P wave velocity structure of the northern part of China and Mongolia

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Velocity structure of the crust and upper mantle in Xingtai earthquake region and its adjacent area

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Three dimensional shear wave velocity structure of crust and upper mantle in South China Sea and its adjacent regions by surface waveform inversion

IntroductionHistorically, surface waves provided much of our understanding of the lateral heterogeneity in the crust and the upper mantle, especially in oceans or desert areas. Traditional method utilizes the great circle theorem for surface waves. It assumed that surface wave propagates along the great circle connecting epicenter with station. Firstly, traditional surface wave analysis was carried out by using multi-frequency-filter dispersion analysis to acquire the group or phase velocity d…     

利用地震面波频散重建川滇地区壳幔S波速度

利用适配滤波频时分析技术分析覆盖川滇地区的长周期面波记录,计算了周期10~100 s内的面波群速度频散,对研究区进行划分尺度大小1.5°×1.5°分格后,采用射线追踪方法求取各分段射线的长度和时间,得到各个格子的纯路径频散.继而采用阻尼最小二乘法求解,反演得到该研究区壳幔S波速度分布.研究结果表明,川滇地区表现出地壳增厚和缩短,在地壳和上地幔顶部,川滇菱形块体内部与其外部相比,虽然存在局部速度负异常,总体上呈相对高速,其周边的走滑断裂带呈现深至上地幔顶部的负速度异常,这有助于地壳块体沿断裂的侧向挤出;此外,云南西部和四川西部壳内和上地幔高导层的存在被认为是与部分熔融的物质或与滑脱构造相关联;从纬向剖面和经向剖面可以得到四川盆地莫霍面平均深度大约为45 km,云南地区莫霍面深度南北方向不一致,云南地区最北端深度达到49 km,南端莫霍面深度大约为36 km,这说明不同构造块体在构造运动过程中受到影响的程度不同.