Crustal structure beneath the Songpan—Garze orogenic belt

The Benzilan-Tangke deepseismic sounding profile in the western Sichuan region passes through the Song-pan-Garze orogenic belt with trend of NNE.Based on the travel times and the related amplitudes of phases in the record sections,the 2-D P-wave crustal structure was ascertained in this paper.The velocity structure has quite strong lateral variation along the profile.The crust is divided into 5layers,where the first,second and third layer belong to the upper crust,the forth and fifth layer belong to the lower crust.The low velocity anomaly zone gener-ally exists in the central part of the upper crust on the profile,and it integrates into the overlying low velocity basement in the area to the north of Ma‘erkang.The crustal structure in the section can be divided into 4parts:in the south of Garze-litang fault,between Garze-Litang fault and Xianshuihe fault,between Xianshuihe fault and Longriba fault and in the north of Longriba fault,which are basically coincided with the regional tectonics division.The crustal thickness decreases from southwest to northeast along the profile,that is ,from62km in the region of the Jinshajiang River to 52km in the region of the Yellow River.The Moho discontinuity does not obviously change across the Xianshuihe fault basesd on the PmP phase analysis.The crustal average velocity along the profile is lower,about 6.30 km/s.The Benzilan-Tangke profile reveals that the crust in the study area is orogenic.The Xianshuihe fault belt is located in the central part of the profile,and the velocity is positive anomaly on the upper crust,and negative anomaly on the lower crust and upper mantle.It is considered as a deep tectonhic setting in favor of strong earthquake‘s accumulation and occurrence.     

Study and review on crust-mantle velocity structure in Bohai Bay and its vicinity

Introduction Bohai Bay, along with its adjacent areas, is one of the seismically active areas in North China. Understanding its crust/upper-mantle structural characteristics and lateral heterogeneity of the medium in this area is of great significance to the study of seismogenic environment, thus improvimg the level of earthquake prediction. For years, scientists have studied the area by gravity and magnetic methods (FENG, et al, 1989), geothermal field (WU, et al, 1988; TIAN, ZHANG, 19…     

Characteristic of crustal structure in the Shulu fault basin and its vicinity

（王椿镛，张先康，林中洋，李学清）ＣｈａｒａｃｔｅｒｉｓｔｉｃｏｆｃｒｕｓｔａｌｓｔｒｕｃｔｕｒｅｉｎｔｈｅＳｈｕｌｕｆａｕｌｔｂａｓｉｎａｎｄｉｔｓｖｉｃｉｎｉｔｙ￥Ｃｈｕｎ－ＹｏｎｇＷＡＮＧＩ；Ｘｉａｎ－ＫａｎｇＺＨＡＮＧ；Ｚｈｏｎｇ－ＹａｎｇＬ...     

小江断裂带周边地区三维P波速度结构及其构造意义

作为青藏高原的东南边界,小江断裂带在高原物质的侧向逃逸中发挥着重要的作用.本文利用流动地震台阵及固定台站的走时观测资料,对小江断裂带及周边区域的壳幔三维P波速度结构进行了研究.结果表明,在中上地壳,小江断裂带内部主要为低速异常,其东侧主要为高速异常.在中下地壳,小江断裂带中部为低速异常,北部和南部主要为高速异常,其中北部的高速异常可延伸到地表附近,南部的高速异常可一直延伸到上地幔.我们推测,小江断裂带中部的低速异常与深部热作用有关;北部的高速异常可能是晚古生代地幔柱活动导致大量基性和超基性幔源物质侵入地壳引起的,它的存在对青藏高原物质向南逃逸起到了一定的阻挡作用,可能是导致川滇活动块体北部次级块体快速抬升的重要因素;南部顶界面向北倾斜的高速异常体对川滇活动块体向南滑移起到了进一步的阻挡作用,导致其上覆的中上地壳低速异常区发生较强的变形和强烈的地震活动,同时在上地幔深度范围起到了稳定的作用,使其南部区域的介质受青藏高原物质向南挤出的影响明显减小.     

Crustal structure and accurate hypocenter determination along the Longmenshan fault zone

Ｃｒｕｓｔａｌｓｔｒｕｃｔｕｒｅａｎｄａｃｃｕｒａｔｅｈｙｐｏｃｅｎｔｅｒｄｅ┐ｔｅｒｍｉｎａｔｉｏｎａｌｏｎｇｔｈｅＬｏｎｇｍｅｎｓｈａｎｆａｕｌｔｚｏｎｅＺＨＵＺＨＡＯ１）（赵珠）ＪＵＮＦＡＮ１）（范军）ＳＩ－ＨＵＡＺＨＥＮＧ２）（郑斯华）ＡＫ...     

阿坝-遂宁宽角地震剖面重建藏东缘龙门山地区地壳速度结构

龙门山断裂带位于青藏高原东缘,在中生代和晚新生代经历强烈的构造变形,急剧抬升,是研究青藏高原隆升和扩展动力学过程的重要窗口.本文利用起伏地形下的高精度成像方法,对"阿坝—龙门山—遂宁"宽角反射/折射地震数据重新处理,通过走时反演重建研究区地壳速度结构.剖面自西向东跨越松潘—甘孜块体、龙门山断裂带和四川盆地,不同块体速度结构表现了显著的差异.松潘甘孜块体地表复理石沉积层内有高速岩体侵入,低速层低界面起伏不平反映了该区的逆冲推覆构造.中下地壳速度横向上连续变化,平均速度较低（约6.26 km·s-1）.四川盆地沉积层西厚东薄,并在西侧出现与挤压和剥蚀作用相关的压扭形态.中下地壳西薄东厚,平均速度较高（约6.39 km·s-1）.龙门山断裂带是地壳速度和厚度的陡变带,Moho面自西向东抬升约13 km.在整个剖面上Moho面表现为韧性挠曲,中下地壳横向上连续变化,推测古扬子块体已到达松潘甘孜块体下方.松潘甘孜块体下方中下地壳韧性变形,并在底部拖曳着被断裂切割的脆性上地壳,应力在不同断裂上积累和释放,诱发大量地震.     

郯庐断裂带鲁苏皖段地壳速度结构的分段特征及其地质意义

本文采用天然地震近震走时反演地壳三维速度结构的方法获得了郯庐断裂带鲁苏皖段及附近地壳(30°N—37°N,113°E—122°E)三维速度结构.对地壳内分层速度结构的分析发现,郯庐断裂带鲁苏皖段存在速度的分段特征.郯庐断裂带鲁苏皖段浅层35.3°N以北,34.5°N—35.3°N间,33°N—34.5°N间呈现的速度分段和地表出露地层有关,与地质上安丘段、莒县—郯城段,新沂—泗洪段三个破裂单元相对应,且和各段的地震活动相呼应,表明郯庐带新沂到泗洪段可能是断裂的闭锁段.郯庐断裂带鲁苏皖段地壳速度结构自浅至深分为三段, 大体位置是:南段(32.5°N—33°N以南),中段(32.5°N—33°N至35°N—35.3°N),北段(35°N—35.3°N以北).上地壳分段与苏鲁超高压变质岩带的插入有关,中、下地壳速度分段则可能和火山岩滞留有关.地壳各层速度结构不同段的速度差异反映了构造块体的速度差异,表明各构造块体在地壳下部仍有差异,郯庐带西侧速度总体高于东侧,反映了不同构造块体的形成和组成差别,也说明了该断裂带可能延伸到莫霍面.而不同深度的分段性可能反映了不同地质演化过程.     

用接收函数方法研究上海地震台阵下地壳结构

利用上海地震台阵16个台站记录的远震资料,采用接收函数线性反演方法,对台阵下的地壳速度结构进行研究,获得了研究区域内地壳厚度和地壳速度的分布特征。研究结果表明,研究区域Moho面深度约为33±2 km,Moho面深度基本不变,地幔顶部S波速度约4.4 km/s,地壳内没有发现明显的低速层。     

P-wave crustal velocity structure in western Sichuan and eastern Tibetan region

A deep seismic sounding profile located in the western Sichuan and eastern Tibetan region extends from Batang (Zhubalong) to Zizhong, Sichuan. It passes through the Songpan-Garzê Fold System and the Longmenshan Tectonic Zone, and ends in the Yangtze Craton. Based on the travel times of phases on the profile, incorporating information on the relevant amplitudes, we determined 2-D P-wave crustal velocity structure along the profile, analyzed the principle differences between the crustal and upper mantle structure in the Western Sichuan Plateau and Sichuan Basin, discussed the deep feature of the major faults on the profile, the tectonic relation between the Yangtze Craton and the Tibetan Plateau and the deep structural environment where strong earthquakes occurred.     

六盘山断裂带及其邻区地壳结构

新生代期间,中国大陆西部受印度—欧亚板块碰撞和青藏高原隆升影响,以地壳缩短、增厚、陆内造山和强烈地震活动等为主要特征.在青藏高原东北边缘,高原物质侧向移动被鄂尔多斯地块所阻,在六盘山地区发育了一系列左旋斜冲断裂.断裂带周缘构造变形强烈,地震活动频繁,是研究青藏高原横向扩展控制大陆内部弥散变形的理想场所.本文对穿越青藏高原东北缘—六盘山断裂带—鄂尔多斯地块的宽角反射与折射地震资料使用层析成像和射线反演算法进行成像,获得了研究区地壳速度结构模型,其结果反映出六盘山断裂带两侧地壳结构、构造特征差异显著：1）上地壳层析成像结果显示鄂尔多斯盆地一侧地壳上部速度较低,等值线呈近水平状,具有典型的沉积盆地特征,而青藏高原东北缘一侧上地壳速度相对较高,横向变化剧烈,呈褶皱状,二者的分界为海原—六盘山逆冲走滑断裂;2）全地壳射线反演结果显示鄂尔多斯地块地壳速度梯度大,下地壳底部速度高由铁镁质物质组成,具有典型稳定古老克拉通的特征,青藏高原东北缘地壳速度总体较低,主要由长英质及长英-铁镁质过渡物质组成,具有典型造山带的特征,而六盘山断裂带下方地壳速度结构复杂,层面呈拱形,部分层出现速度逆转,为两个构造单元的接触过渡带;3）青藏高原东北缘一侧地壳厚度~50 km,鄂尔多斯地块地壳厚度~42 km,六盘山断裂带下方莫霍面发生叠置,揭示出青藏高原东北缘、鄂尔多斯地壳在六盘山下汇聚,较薄且刚性的鄂尔多斯地壳挤入较厚且塑性的青藏高原东北缘地壳中的构造模式.

     

Crustal structure in northern margin of Tianshan mountains and seismotectonics of the 1906 Manas earthquake

Introduction The Tianshan orogenic belt between the Tarim and Junggar basins has re-uplifted in Cenozoic due to the collision and the northwards push-compression of Asia-India plate. The special active tectonic zones have been formed along both south and north margins of the Tianshan mountains (FENG, et al, 1991). The Tianshan seismic belt is one of the major seismic belts in China. A se-ries of strong earthquakes occurred in two flanks of the Tianshan mountains in 20th century, such as …     

深地震测深揭示的华南地区地壳结构及其动力学意义

20世纪70年代以来,我国实施与华南地区有关的深地震测深剖面达57条.本文收集该区的深地震测深研究成果,利用保真能力强的三维克里金插值技术构建了100°E~125°E,18°N~34°N区域内的三维地壳速度模型.基于三维地壳结构模型,分别探讨了华南地区不同构造单元地壳厚度空间变化特征、地壳属性、上地幔顶部地震波速变化以及太平洋向欧亚板块的俯冲方向等.研究结果表明:(1)扬子地块平均地壳厚度为40 km左右,地壳平均速度为6.30 km/s;华夏地块平均地壳厚度32 km左右,地壳平均速度6.24 km/s.(2)扬子地块的四川盆地与全球地台区具有相似的地壳速度-深度变化特征,华夏地块与全球伸展区结构相似,台湾造山带具有较典型全球大陆弧的特点.(3)华夏地块上地幔顶部Pn波平均速度为8.02 km/s;台湾造山带Pn波平均速度为7.98 km/s;扬子地块的Pn波速度为7.94 km/s,包含四川盆地(Pn速度达8.02 km/s)和川滇地区(Pn速度最低为7.75 km/s).川滇地区和松潘—甘孜褶皱带东部构造活动性较强,四川盆地和华夏地块相对较稳定.(4)推测太平洋板块向欧亚板块俯冲的方向为NW-SE方向.     

Crustal structure beneath Qiangtang and Lhasa terrane from receiver function

To determine the crustal structure in central Tibet, we used teleseismic waveform data recorded by 18 stations in the INDEPTH-Ⅲ seismic array across the central Tibet from the central Lhasa terrane to the central Qiangtang terrane. The S-wave velocity structures beneath stations are determined by inverting the stacked radial receiver function using the GA method. The first order features in the receiver function are modeled. Our results show that the Moho in Qiangtang is about 8 km shallower than that in Lhasa terrane along the INDEPTH-Ⅲ profile. It maybe suggests the northward subduction of the Lhasa mantle lid beneath the Qiangtang terrane is affected by the India-Asia collision. We conclude that there exist low velocity zone in the middle crust across the northern Lhasa and Qiangtang terrane, which can be related to the high temperature upper mantle beneath that.     

Crust and upper mantle structure of the Ailao Shan-Red River fault zone and adjacent regions

Using arrival data of the body waves recorded by seismic stations, we reconstructed the velocity structure of the crust and upper mantle beneath the southeastern edge of the Tibetan Plateau and the northwestern continental margin of the South China Sea through a travel time tomography technique. The result revealed the apparent tectonic variation along the Ailao Shan-Red River fault zone and its adjacent regions. High velocities are observed in the upper and middle crust beneath the Ailao Shan-Red River fault zone and they reflect the character of the fast uplifting and cooling of the metamorphic belt after the ductile shearing of the fault zone, while low velocities in the lower crust and near the Moho imply a relatively active crust-mantle boundary beneath the fault zone. On the west of the fault zone, the large-scale low velocities in the uppermost mantle beneath western Yunnan prove the influence of the mantle heat flow on volcano, hot spring and magma activities, however, the upper mantle on the eas     

Crust-mantle structure feature and the seismic activity of the main tectonic units in the North Tanlu fault zone

IntroductionThe Northern Tanlu fault zone (from Yingkou to Luobei) crosses the northeast mainland ofChina. Because of its large scale, long history activity and controlling earthquakes prominently, itis paid closely attention by geologists, and a imp amount of geological survey has been done inthese years (Bureau of Geology and Mineral Resources of Liaoning Province, 1989; Bureau ofGeology and Mineral Resources of Jinn Province, 1988; Bureau of Geology and Mineral Resources of Heilongi…     

雷琼拗陷地壳结构特征

根据1984～1985年在雷琼地区完成、长约210 km的白延—江洪深地震测深资料,应用有限差分法、时间项法反演和二维非均匀动力学射线追踪等方法,得到白延—江洪地壳剖面的二维非均匀构造图像.结果显示：琼北及雷州半岛地壳厚约25～26 km,地壳平均速度在琼州海峡南段琼北凸起约6.16 km·s-1,海峡北段雷琼拗陷区约5.70 km·s-1;地壳速度偏低,下地壳尤为明显,仅约6.3～6.5 km·s-1;结晶基底显示为厚约2～4 km、速度5.5～6.0 km·s-1的速度梯度带,Moho界面上、下界面速度分别是6.5 km·s-1和8.05 km·s-1的一级速度间断面,没有发现明显的壳幔过渡带.白延—江洪剖面位于雷琼拗陷更新世玄武岩覆盖区,推测地壳厚度减薄以及低速度构造主要反映了该区域自新生代以来一直延续至第四系晚期的多期火山岩浆喷发热地幔对地壳底部的底浸、拆层与地壳仍处于相对温热状态相关.     

基于重复微震的小江断裂带深部滑动速率研究

利用云南数字地震台网1999~2011年的波形资料,通过辨识源于同一位置破裂的重复微震来估算小江断裂带不同段落、不同深度的断层滑动速率.针对研究区台站分布稀疏的客观情况,应用了在子采样条件下基于S-P相对到时差来约束地震相对位置的方法,在小江断裂带识别出29组重复微震,其复发间隔存在差异变化.重复微震的时空分布初步分析表明:准周期的重复微震在空间上相对独立,远离其它重复微震和背景地震; 在重复微震集中分布的区域,位置相近的重复微震可能会相互作用而影响其复发间隔;在背景地震活跃阶段,相邻背景地震发生引起的应力变化可能缩短重复微震的复发间隔.利用重复微震的地震矩和重复间隔,估算出小江断裂带孕震深处3~12 km的滑动速率为1.6~10.1 mm·a-1,显示不同破裂段的深部滑动速率存在明显差异.     

Crustal structure and local seismicity in Colombia

Using P-wave travel time data from local seismicity, the crustal structure ofthe central and southern part of Colombia was determined. A very stableand narrow range of possible velocity models for the region was obtainedusing travel time inversion. This range of models was tested with earthquakelocations to select the best velocity model. The 1D velocity modelproposed has five layers over a halfspace, with interfaces at depths of 4,25, 32, 40 and 100 km and P-wave velocities of 4.8, 6.6, 7.0, 8.0, 8.1and 8.2 km/sec, respectively. According to this model the Moho lies at32 km depth on average. For P-waves, the station corrections range from–0.62 to 0.44 sec and for S-wave they range from –1.17 to 0.62 sec.These low variations in station residuals indicate small lateral velocitychanges and therefore the velocity model found should be well suited forearthquake locations and future starting model for 3D tomography studies.Using this new velocity model, the local earthquakes were relocated. Theshallow seismicity, < 30 km, clearly shows the borders betweentectonic plates and also the main fault systems in the region. The deepseismicity, > 80 km, shows two subduction zones in the country: theCauca subduction zone with a strike of N120^°E, dip of 35^°and thickness of 35 km, and the Bucaramanga subduction zone which has,for the northern part, a strike of N103^°E, dip of 27^° andthickness undetermined and, for the southern part, a strike ofN115^°E, dip of 40^° and thickness of 20 km. Based ondifferences of thickness of brittle crust in the subducted slab and spatialdistribution of the seismicity, the Cauca and Bucaramanga subduction zonesseem to represent independent processes. The Cauca subduction seems tobe connected to the process of the Nazca plate being subducted under theNorth Andes Block. In the Bucaramanga subduction zone, the transitionbetween southern and northern parts and changes in geometry of the slabseem to be gradual and there is no evidence of a tear in the slab, howeverthe local seismicity does not allow us to determine which plate or plates arebeing subducted. The Bucaramanga nest appears to be included into thesubducted slab.     

小江断裂中段及其邻近地区应力场时间变化分析

研究地壳构造应力状态及其时空分布特征,特别是应力变化的信息,是探讨地震成因、分析发震条件的重要有效途径之一.本文利用1998年1月至2009年1月以来小江断裂中段及其邻区ML≥2.5的共计740个震源机制解,基于小江断裂中段及其邻近地区地质构造背景,对研究区进行了分区;以该区域内较大地震为界,结合余震时间序列特征,进行...     

Study on crust-mantle tectonics and its velocity structure along the Beijing-Huailai-Fengzhen profile

ｔｕｄｙｏｎｃｒｕｓｔｍａｎｔｌｅｔｅｃｔｏｎｉｃｓａｎｄｉｔｓｖｅｌｏｃｉｔｙｓｔｒｕｃｔｕｒｅａｌｏｎｇｔｈｅＢｅｉｊｉｎｇＨｕａｉｌａｉＦｅｎｇｚｈｅｎｐｒｏｆｉｌｅＺＨＩＰＩＮＧＺＨＵ（祝治平）ＸＩＡＮＫＡＮＧＺＨＡＮＧ（张先康）...