西秦岭北缘断裂带的深部构造特征及其与地震活动的关系

西秦岭北缘断裂带是中国的一条主要超壳断裂带，也是祁连褶皱系与秦岭褶皱系的分界断裂带。利用近几年取得的人工地震、重力、航磁、地热等资料，从地质和地球物理两个方面就该断裂及其两侧的深部构造特征作一初步分析并讨论了断裂带的最新活动及地震活动。     

天水地震区深部地温场的有限元计算

用有限元方法计算了天水地震区上地壳地温场。结果表明，影响该区浅部（层）地温场的主要因素是基底构造和断裂构造。祁连褶皱系为高热异常区，秦岭褶皱系为低热异常区，西秦岭北缘断裂带为地温梯度带。认为该带历史地震的发生与热应力差有关     

青藏高原东北缘合作-大井剖面地壳电性结构研究

青藏高原东北缘合作-大井剖面的大地电磁探测结果表明,该区域的电性结构呈明显的纵向分层、横向分块的特点,中下地壳普遍存在高导层.青藏高原东北缘西秦岭北缘断裂带、北祁连南缘断裂带、北祁连北缘断裂带(海原断裂带)及龙首山南缘断裂带等区域性断裂带在电性结构模型中均表现为电性梯度带或低阻异常带.电性结构的横向分区与构造上的地块划分有明显的一致性,各个地块的电性结构存在明显差异.西秦岭北缘断裂带作是一个大型的板块边界,但板块结合带附近没有明显逆冲或俯冲痕迹,可能主要以左旋走滑为主.北祁连地块向北仰冲与阿拉善地块向南俯冲边界可能不是海原断裂带,而是龙首山南缘断裂带.西秦岭造山带内的壳内高导层与青藏高原内部存在的高导层具有可对比性,可能是由于部分熔融与含盐水流体共同作用的结果.中祁连地块内的高导层可能是含盐水流体引起的.而北祁连与河西走廊过渡带内的高导层则可能是板块俯冲或仰冲的构造运动痕迹,也可能是由含盐水流体引起的.     

渭河盆地及邻区地壳深部结构特征研究

利用穿越区域南段为秦岭褶皱带山区,中段为渭河断陷盆地,北段为鄂尔多斯地台南缘的宽角反射/折射地震测深剖面所获得的资料对该区地壳结构进行研究.结果表明:该区地壳呈明显的分层、分区结构;上下地壳的分界是由壳内反射波较为连续可靠的P2以及P3所确定的.鄂尔多斯地台是本区M界面最深的地区,地壳厚度大,达42 km左右,结构相对简单,结晶基底浅. 秦岭褶皱带的地壳厚度约37~38 km,结晶基底浅,甚至出露.渭河断陷盆地莫霍界面相对两侧明显且不对称的上隆,地壳结构复杂;而莫霍界面相对鄂尔多斯地块突变隆起和上地幔高速物质侵入于下地壳,是该区发生中强地震的深部构造背景.     

鄂尔多斯及邻区航磁异常特征及其大地构造意义

本文通过对航磁异常资料进行向上解析延拓、垂向不同阶导数及磁性体边界确定新方法等处理，并结合地震震中分布对鄂尔多斯块体及邻区不同深度场源磁异常特征加以分析研究.结果表明，鄂尔多斯块体虽具有整体刚性的特征，但其内部也存在非均质性；块体东缘的华北克拉通地区经后期改造，产生近SN向的基底软弱带；青藏高原地壳缩短增厚的同时，其东北缘下地壳韧性物质分别沿秦岭、祁连两个软弱带向周缘塑性流动，而且青藏高原巨大的NE向挤压应力造成鄂尔多斯块体逆时针旋转；鄂尔多斯块体及其边界多样化的构造特征反映了不同刚性程度的地质体在外部不同应力作用下产生了显著差异的地质构造形态，这种构造形态具有继承性和叠加性.     

深地震反射剖面揭示的渭河盆地西部宝鸡凸起断裂深部特征

渭河盆地西部宝鸡凸起位于鄂尔多斯西南缘、祁连褶皱系东南缘与秦岭褶皱系北缘之间,在其附近发生过多次7级以上强震,是我国大陆东西和南北巨型构造单元的交接地带,有多条断裂构造带在此通过.     

基于GNSS的青藏高原东北缘地壳运动场及强震趋势研究

利用“中国大陆构造环境监测网络”GNSS数据研究1998—2018年青藏高原东北缘排除同震影响等干扰后的速度场、主应变率场、最大剪切应变率场、面应变场等的变化,活动断裂滑动速率变化、跨活动断裂基线变化等。将研究区域内的二级块体再分区,获得各次级块体内部的应变率变化;获取研究区域地壳运动场的趋势性、动态特征。研究结果显示,阿尔金断裂带中东段、祁连块体和柴达木块体交界、巴颜喀拉块体与羌塘块体交界、祁连块体南边界中段、海原—六盘山断裂带和西秦岭北缘断裂带西段的逆冲运动,祁连块体北边界西段、庄浪河断裂的左旋走滑运动,祁连块体北边界东段、西秦岭北缘断裂带东段的左旋逆走滑运动,都属于造成一定程度地壳变形的持续性局部应变增强活动。阿尔金断裂带东段、东昆仑断裂带中西段、祁连块体北边界、庄浪河断裂北段、海原断裂南段、六盘山断裂北段、西秦岭北缘断裂带东段可能存在闭锁,未来十年可能发生M_S6.0以上地震。     

海原构造区及其周缘上部地壳结构研究

基于甘肃省夏河县—陕西省靖边县剖面的8次人工地震初至波数据, 利用有限差分走时方法反演得到了沿该剖面长约650 km的上部地壳速度结构和结晶基底的深度分布． 反演结果显示: 海原构造区西侧的西秦岭—祁连山褶皱区上部地壳的横向非均匀性明显, 基底深度从1 km到5 km不等, 反映了褶皱区改造变形强烈的构造特征; 其东侧的鄂尔多斯盆地基底深度约为5—6 km, 其速度均匀、 稳定, 上地壳呈弱速度梯度特征; 海原构造区及海原弧形断裂带附近上部地壳的破坏变形最严重, 区内横向高低速相间分布． 综上可知, 海原构造区东西两侧上地壳结构的显著差异揭示了其结构复杂性的成因及其与地震活动性的关系．      

青藏高原东北缘海原构造带马东山阶区深部电性结构特征及其构造意义

海原一六盘山构造带是青藏高原东北缘地区的一条重要边界,在海原断裂带和六盘山断裂带接触区形成了特殊的马东山挤压阶区,本文对跨过该挤压阶区一条密集测点大地电磁剖面数据进行了处理和二维反演,获得的深部电性结构图像揭示在马东山挤压阶区深部电性结构表现为在高阻背景下镶嵌多个向西南倾斜的低阻条带电阻率结构样式,并在深度约25 km汇聚到中下地壳低阻层内,共同组成"正花状"结构;海原一六盘山构造带西南侧到陇中盆地区间呈现高、低阻相互"楔合"的深部结构特征,而其东北侧的鄂尔多斯西缘带自地表到中下地壳为较完整的高阻块体.另外结合跨过海原断裂带中段和西秦岭造山带的大地电磁探测结果,对海原一六盘山构造带分段性及其两侧的陇中盆地和鄂尔多斯地块的接触关系进行了研究分析.大地电磁探测成果佐证了在海原断裂带中段为具有走滑特点的断裂,而其尾端与六盘山断裂带斜交区域的马东山地区发生了强烈的逆冲推覆与褶皱变形;活动构造研究发现沿海原断裂带所产生的左旋走滑位移被其尾端的马东山、六盘山以东西向的地壳缩短调节吸收,GPS观测表明青藏高原东北缘地区现今构造变形分布在海原一六盘山构造带以西上百公里的范围内,陇中盆地一海原一六盘山构造带和鄂尔多斯地块一线的深部电性结构图像也很好地解释了该区变形状态:海原一六盘山构造带带及西南盘的陇中盆地的中下地壳非常破碎,在青藏高原向北东方向的推挤下容易发生变形,而北东盘鄂尔多斯地块地壳结构完整,很难发生构造变形.对海原一六盘山构造带马东山阶区和龙门山构造带的深部电性结构及变形特征等进行了比较分析,发现该区有与2008年汶川地震相似的深部构造背景,应重视该区强震孕育环境的探测研究.     

长乐-诏安断裂带深部地质-地球物理研究进展综述

本文从4个方面综述了长乐-诏安断裂带深部地质-地球物理探测研究的概况和新进展:岩浆岩活动与分布特征;地壳上地幔速度结构、Q 值结构和电性结构;地球物理场分布特征;矿产资源远景预测、开发和利用。根据在该带发现文象、晶洞花岗岩,地壳中存在低速-低 Q-高导层,低速层隆起区与莫霍面隆起区、居里面隆起区基本吻合,地球物理场显著变异,大地热流值明显偏高,存在深断裂等地壳深部构造背景等,笔者等认为地壳内可能存在着半熔融态的高温透镜体软物质,预测在长乐-诏安断裂带能够找到高温热水田。     

对应分析约束下的重磁联合反演及其在塔里木盆地的应用

综合应用重磁对应分析和重磁联合反演的基础上提出对重磁联合反演的一种改进方法：约束联合反演，即利用重磁异常相关系数对联合反演中目标函数进行加权。实验结果表明，该方法有利于迭代反演的收敛性。把该方法应用于塔里木盆地东部库尔勒～若羌剖面，结果说明，以对应分析的结果作为先验认识，有助于合理地建立最优化反演的初始模型，能提高解释结果的质量     

Magnetic and gravimetric modeling of the central Adriatic region

The high-amplitude wide magnetic anomaly that covers a large area of the north-eastern – central Adriatic Sea in the Croatian offshore is ∼100 km wide and extends NW–SE for ∼350 km. The anomaly is located between the Dinarides and Apennines chains, in an interesting geodynamic scenario. The presence of intruded gabbroid rocks in the Croatian archipelago also contributes to making this intriguing and still not extensively investigated anomaly potentially significant to the geologic and geophysical context in which it is located. In this work, we model the Bouguer and magnetic anomalies across the Adriatic Sea. The 2D geophysical modeling was produced across four cross sections considering surface heat flow data to calculate the Curie depth. The magnetic susceptibilities and densities used for the synthetic bodies are in agreement with the literature and with those derived by previous models. The results suggest the presence of an uplifted magnetized basement with high magnetic susceptibility (0.075 SI units) to be the main contributor to the observed magnetic anomaly. This magnetic susceptibility is interpreted as representative of a gabbroid-intruded basement. The high-susceptibility basement is in lateral continuity with a relatively low susceptibility basement (0.025–0.038 SI units). The results of the geophysical modeling are compared with a conceptual geological model realized from the integration of surface, well and geophysical data, the latter concerning seismic, tomographic, magnetic and gravimetric anomalies and heat flow data. These data have been merged in an integrated data-base using MOVE software, and the geophysical modeling was performed using GM-SYS. The comparison allowed to confirm the hypothesis that the magnetic anomaly is related to the basement and to its position in the complex geodynamic evolution of the Apennines–Adriatic–Dinarides system.     

STATISTICAL MULTIVARIATE ANALYSIS OF AIRBORNE GEOPHYSICAL DATA ON THE SE BORDER OF THE CENTRAL LAPLAND GREENSTONE COMPLEX*

Statistical multivariate methods for the integrated processing of airborne geophysical data were tested. The data consisted of magnetic, electromagnetic and gamma radiation measurements, to which cluster analysis, principal components analysis and discriminant analysis were applied. Also, auxiliary variables were derived from the original ones and their value was tested. Although the frequency distributions of the data do not favour statistical analysis, the practical results are acceptable. Principal component analyses show geological and technical aspects that are difficult to obtain from the original observations. In cluster analyses, the sources of measured fields control the grouping of variables. Discriminant analysis was applied to the automatic identification of rocks by geophysical data. The rocks investigated are metasediments and metavolcanics, some magnetic and others conductive. When all available geophysical data were included, correct identifications were made in more than 60% of cases. In particular, gamma ray observations were found to improve the discrimination of non-magnetic and non-conductive rocks. The geophysical similarity of rocks studied by cluster analysis depends on electrical and magnetic properties as well as on their origin; the content of radioactive elements in turn is related to the origin.     

Geophysical analysis of Catalão I alkaline–carbonatite complex in Goiás,Brazil

The Catalão I alkaline–carbonatite complex, which is located in Central Brazil, is one of the main producers of niobium and phosphates in the world. It has been intensely studied geologically and geochemically for its economic potential. This work presents a geophysical analysis over this complex, identifying its behaviour in the subsurface and in portions that have not been explored yet. Different geophysical methods and techniques were applied to achieve the most reliable results possible: at the surface, through radiometric, geological, and topographic data, and at depth, by geological, magnetic, and gravimetric data. The analysis was successfully completed with inversions of gravity and magnetic data that resulted in quite similar models, both in volume and shape. Their density and magnetic susceptibility contrasts were consistent with the expected dunite–pyroxenite lithology from the original mafic intrusion and indicated (by exclusion) the volume of the carbonatite body, which along with the known contents of phosphates and niobium allowed an indirect estimate of the reserves and resources of the complex.     

大庆外围盆地地球物理场与盆地基底特征

根据收集到的大庆外围盆地的布格重力异常和航磁异常数据,对外围盆地中的8个盆地进行了地球物理场特征的分析.对各盆地的重力异常进行了由下地壳与上地幔的密度差引起的重力效应的剥离,对磁力异常进行了由居里面起伏引起的磁力效应的剥离.在此基础上应用调和级数法和遗传算法分别反演计算了这8个盆地的重力基底和磁性顶界面，并分析了其基底特征. 各盆地重力基底在0.2~9.0 km之间变化,磁性顶界面在1.8~9.8 km之间变化,其特征反映了各盆地的基本现状.     

Mapping of magnetic basement in Central India from aeromagnetic data for scaling geology

The Central Indian region has a complex geology covering the Godavari Graben, the Bastar Craton (including the Chhattisgarh Basin), the Eastern Ghat Mobile Belt, the Mahanadi Graben and some part of the Deccan Trap, the northern Singhbhum Orogen and the eastern Dharwar Craton. The region is well covered by reconnaissance‐scale aeromagnetic data, analysed for the estimation of basement and shallow anomalous magnetic sources depth using scaling spectral method. The shallow magnetic anomalies are found to vary from 1 to 3 km, whereas magnetic basement depth values are found to vary from 2 to 7 km. The shallowest basement depth of 2 km corresponds to the Kanker granites, a part of the Bastar Craton, whereas the deepest basement depth of 7 km is for the Godavari Basin and the southeastern part of the Eastern Ghat Mobile Belt near the Parvatipuram Bobbili fault. The estimated basement depth values correlate well with the values found from earlier geophysical studies. The earlier geophysical studies are limited to few tectonic units, whereas our estimation provides detailed magnetic basement mapping in the region. The magnetic basement and shallow depth values in the region indicate complex tectonic, heterogeneity, and intrusive bodies at different depths, which can be attributed to different thermo‐tectonic processes since Precambrian.     

Potential Field,Geoelectrical and Reflection Seismic Investigations for Massive Sulphide Exploration in the Skellefte Mining District,Northern Sweden

Multi-scale geophysical studies were conducted in the central Skellefte district (CSD) in order to delineate the geometry of the upper crust (down to maximum ～ 4.5 km depth) for prospecting volcanic massive sulphide (VMS) mineralization. These geophysical investigations include potential field, resistivity/induced polarization (IP), reflection seismic and magnetotelluric (MT) data which were collected between 2009 and 2010. The interpretations were divided in two scales: (i) shallow (～ 1.5 km) and (ii) deep (～4.5 km). Physical properties of the rocks, including density, magnetic susceptibility, resistivity and chargeability, were also used to improve interpretations. The study result delineates the geometry of the upper crust in the CSD and new models were suggested based on new and joint geophysical interpretation which can benefit VMS prospecting in the area. The result also indicates that a strongly conductive zone detected by resistivity/IP data may have been missed using other geophysical data.     

中国中南地区综合地质地球物理研究

利用重、磁和天然地震资料对中南地区进行了综合地质地球物理研究.根据研究区的重、磁异常的分布特征,可将其分为4个重力异常区、3个航磁异常区.根据重力资料反演计算得到的研究区的地壳厚度在295～41 km之间,总的趋势为西厚东薄,地壳厚度与地形起伏基本上呈镜像关系.根据磁力资料计算得到的研究区居里界面在12～40 km之间变化.地震层析成像结果表明研究区内的速度分布总体上体现了纵横交错的断块特征.在纵向尺度上,江汉－洞庭盆地以及周缘造山带的上地壳结构变化不大,中地壳和下地壳则普遍受到现今构造活动的改造,以致岩石的结构发生了一定的变化.它们主要表现为低速区域的扩大,尤其是在地壳下部尤为突出,这与断陷盆地的拉张以及造山带岩石层的底侵和拆沉作用密切相关.通过对研究区地球物理场的分析计算,在研究区共提取主要断裂带34条.根据岩石层板块大地构造理论,依据岩石层结构、地壳结构和结晶基底等深部结构的不同,将研究区中板内不同构造单元——块体作为一级构造单元,块体之间的深大断裂带作为块体的边界——块体结合带,据此原则在研究区中划分出两个一级构造单元,五个二级构造单元.     

NVESTIGATION OF TECTONICS BY GRAVITY DETAILING*

Mapping of fault patterns is an important part of geophysical exploration. A computerized digital template analysis method is described which tests gravity maps for the effects of faults by comparing measured gravity data with calculated master curves. The interpreted gravity data are incorporated in a tectonic map using geological symbols and units, for ready use by the geologists. Tectonics can be investigated by gravity detailing if the smallest undulations on the Bouguer map are taken into consideration. Up to now, residual and derivative gravity maps have explained gravity effects by assuming spherical bodies which are almost unknown in geology. The method discussed here uses tectonic elements, such as fault-blocks and dikes as a basis of interpretation instead of the spherical bodies of the conventional interpretation methods. Gravity data can be easily and relatively cheaply obtained in the early phases of exploration by area wide spot coverage following lines of easy access such as roads, etc. Seismic studies, by contrast, have the disadvantage of being executed along predetermined profile lines. Only after sufficient detailing do seismic profiles permit-if at all -an areal mapping of faults. Thus a tectonic map is obtained only at the end of a geophysical survey instead of being available prior to the planning of costly seismic profiles. The use of gravimetric data and their interpretation by the suggested method provides tectonic detail maps in the early phases of geophysical studies. In addition, this article discusses a general geophysical interpretation method, using the investigation of faults by gravity as an example. Applications of this method for different gravity and magnetics problems as well as for combined interpretations are outlined. Detailed case histories will be published in later articles.     

地球物理信号能量(密度)多维分形及应用

地球物理信号代表的地质地球物理过程在多种尺度上和尺度之间表现为自相似性（self-affinity)或尺度无关性（Scale Invariant)，称为地球物理信号的分形性质，多个分形地球物理信号叠加在一起表现为多维分形特征，研究多维分形地球物理信号的能量或能量密度特征，可以进行时间或空间地球物理信号的校正、奇异性研究分析，或进行不同地球物理动力学过程的分解，本文描述了地球物理时间（空间）信号的多维分形过程和功率谱密度（能量密度）与波数以及重磁场能谱密度及面积（能量）与能谱密度的多维分形关系，并用地球物理测井与重磁资料作了试算。