鄂尔多斯周缘地震活动性和近期地震趋势分析

利用历史地震资料，分析了鄂尔多斯周缘地区地震活动的时空分布特征、地壳应力特征、7级以上强震前的地震活动图象和强震活动和活动构造的关系。利用灰色预测理论预测了块体周缘未来5a内的发震时间。     

中国西部地区地壳结构特征与强震活动相关性研究

中国西部地区是地震活动十分强烈的地区,天山、阿尔泰、帕米尔和西昆仑都是著名的地震构造带,在这些地震构造带和周边地区发生了多次震级大于5级的强震.本文通过分析西部地区的重力场特征,根据重力数据结合地震剖面、应用Parker-Oldenburg方法反演得到了研究区莫霍面深度,通过对比地震层析成像的反演结果,分析了研究区的地壳结构特征.计算结果表明,研究区地壳结构不均匀特征明显,在造山带地区一般是莫霍面坳陷区,盆地则是莫霍面隆起区,主要造山带地壳速度结构表现为高速区,盆地和主要凹陷区为低速区.根据计算结果和以往强震震中位置分析了地壳构造与强震活动的相关性,西部地区的地震活动与地壳结构的横向不均匀密切相关,强震主要发生在地壳速度变化带附近和地壳速度结构差异较大的地区,在构造应力作用下,这些地壳介质非均匀地区易发生强震,这是中国西部造山带和盆-山边界附近频发强震的构造原因之一.     

云南主要构造体系与强震分布规律的初步分析

本文在概述云南地壳构造特点和地震活动特征的基础上,以七级和七级以上地震为例,重点分析了云南主要构造体系与强震分布的相关特点,利用多年来地震地质、地球物理及地震活动性成果,简述了云南及邻区的现代构造形变特征。结合地震破裂带、地壳形变、绝对应力测量、震源机制以及模拟实验等动态观测资料,得到云南现今构造应力场总的以北北西向主压应力为主导。最后,以上述资料为依据,对云南地区未来强震发生的可能地段作了趋势估计。     

青藏高原的地震构造与地震活动

根据地震地热说原理和中国西部的大地构造资料,讨论了青藏高原的地震构造活动模式及地震活动特征,认为兴都库什地震柱和缅甸地震柱是控制青藏高原构造运动和地震活动的主因,青藏高原深达70km的巨厚地壳是内陆地区壳内强震频发的有利构造条件,利用35km以下青藏高原的下地壳地震和周边地区的壳下地震活动动态,参考历史震例,可以为研究区内的壳内强震活动与火山活动提供可能的活动强度、活动地点及大致活动时段等前兆性指标,并取得了初步成效。利用地震柱概念对青藏高原地震构造活动模式的解释似乎更加贴近青藏高原的地震活动特征,可以更加合理地解释壳内强震或者火山发生的成因,也可以预测未来几年内地震柱及其影响区的活动趋势。     

福建省现代地壳垂直运动与断裂活动

根据福建省境内１９７２年以来两次精密水准复测资料,利用速率面拟合法研究福建省现今地壳垂直运动的特征,并结合本区地质构造和地震活动性探讨这种运动的地球物理意义。资料分析表明,本区内新华夏系构造带是强震活动的主要场所,强震活动地点则又受到与这些新华夏系构造交汇的次一级的东西向构造、北西向构造和环状构造活动的制约;在主要构造断块的交接带上则表现为较显著的地壳垂直运动的差异性,差异活动较强烈的地区与本区地     

张家口-渤海地震构造带的地壳形变研究

华北北部地区的张家口-渤海断裂带是控制现代强震的一条地震构造带。新近纪以来,在区域NEE向主压应力的作用下,新发育了一系列的NE向构造活动带,与张家口-渤海断裂带组成1组共轭的剪切破裂系统,控制了近代强震的发生。文中主要探讨了这条断裂带的地壳形变特征。长趋势GPS地壳形变图像反映了这条活动断裂带相对完整的左旋走滑活动。分期的地壳形变图像揭示了在中强地震前,沿该断裂带出现一系列的NE向梯度异常带,分别指示了唐山-河间、三河-涞水以及延怀-山西地震构造活动带的活动,表明了沿张家口-渤海断裂带出现了中强地震的中期前兆。研究认为,强震前地壳形变揭示的是深部蕴震层的应变活动信息,而强震之后比较杂乱的图像特征体现了盖层的调整运动     

地壳应变速率与地震活动关系的研究——从地壳应变场探索强震活动的场源关系

通过研究应变积累速度（亦即地壳应变速率）与地震活动的关系,籍以探讨从地壳应变场中寻找近期强震危险区的方法。针对不同地区的地震活动水平特别是地震复发期的差异,丁国瑜（１９８４）指出,各地震区大震复发时间的差异主要取决于由大震孕育环境和构造物理条件所决定的构造活动速率（亦即应变累积速率）的差异。从近几年地震实况的初步（阶段性）检验看,应用大地测量中垂直形变速率梯度判定强震危险区,具有较好的效果和可喜的前景。作者从理论分析、实际资料对比及计算机模型研究等方面来讨论地壳应变速率与地震活动水平之间的关系,进而为场源关系研究中的“场中求源”的科学思路探索可能的技术途径,并讨论了从应变速率场中寻找强震危险区的方法。     

邢台地震空间分布随时间变化的立体图象与地震发生过程

本文利用邢台地震台网资料研究了1966年3月邢台地震强震活动期间地震位置的空间分布随时间变化的过程。给出了一系列反映邢台地震序列强震孕育、破裂、应力场调整及地震构造的立体图象。进一步探讨了震区地壳介质中存在的障碍体与地震发生的关系。认为这种震区介质的非均匀构造所导致的邢台地震的破裂是一个沿北北东方向的断断续续的发展过程。较好地解释了几个六级以上强震的发生以及强震期后出现的中强余震两头跳现象。本文还对六级以上强震的破裂过程进行了讨论,并与已有结果作了对比,还考察了强震活动期间震源深度随时间变化与大震发生的关系。      

山西地震构造带强震发生的地震地质条件

山西地震构造带内与强震活动有关的断裂多为北北东—北东走向的高角度正断层,是位于重力梯度带上的深断裂、新生代以来长期活动、新构造运动强烈活动的下沉地段、是许多强震的发震区.山西地震构造带下部上地幔是个隆起带,许多强震发生在上地馒隆起的斜坡带上,那里是地壳厚度变异带,分布有切割莫氏面的深断裂.地壳上层构造与深部构造相互结合、互相制约是山西许多强震发霉必要的地质构造条件.水平与垂直相互叠加的应力场是强震发震的应力条件,而且垂直挤压应力起重要的作用.     

滇东潜在震源区图象识别研究

从滇东地区地震地质、地球物理、地壳形变等方面资料所分析选定的１７个构造标志中，经综合图象识别的标志筛选，确定出１０个与强震潜在震源区相关性相对较好的构造标志，并以这１０个标志为基础，判定讨论了该区的强震潜在震源区，最后分析了强震潜在震源区的地震构造标志     

海原活动断裂的地壳脱气作用

根据实验结果讨论了1920年海原8．5级大震发震断裂的气体构造地球化学作用。海原活动断裂带上的脱气以地壳脱气作用为主,脱气作用产物来源于上中地壳,脱气作用的弹度与断层应力状态运动特点密切相关。不同元素所反映的脱气深度范围及特征有所不同,氡对浅部断层活动及拉张区脱气作用较为灵敏,汞、氦能反映较深地壳内的脱气作用,氢的异常则与断层的逆中、推覆作用及断面上岩水作用密切相关。     

高噪声背景下GNSS垂向分量应用探讨

通过对部分GNSS连续站和全国多期GNSS区域站垂向复测资料的分析, 对如何提取和利用GNSS垂向分量在高噪声背景下的有用信息进行了分析研究; 结合地壳运动和地震孕育发生的机理, 进一步讨论了GNSS垂向分量应用于地壳运动与强震预测的可能性。 结果显示, GNSS垂向分量升降分布格局往往与大地构造格局和大地震孕育发生的区域密切相关, 在机理上存在内在的联系。 这些异常升降变化在精细的数据处理中通过某些要素的改正有可能被减弱或消除, 但这种要素的异常也很可能与大地震的孕育过程相关。 这一认识对地形变研究和大地震预测具有参考价值。     

大同阳高震区及其邻区壳幔速度结构与深部构造

利用通过本区６条宽角反射／折射剖面资料对大同阳高震区及邻区地壳上地幔速度结构与构造进行了详细的研究。结果表明,地壳上地幔速度结构与构造在纵向和横向上具有明显的不均一性。浅部基底断裂发育,而在其深部,根据波组特征、壳内界面及速度等值线起伏变化和低速异常体的边界等推测有３处地壳深断裂带。本区最明显的上地壳低速体位于大同—阳原附近,其南界存在地壳深断裂,大同阳高地震群与该低速异常体和深断裂有关。     

SPECTRAL STRUCTURE OF VELOCITY INHOMOGENEITY OF CRUST MEDIUM BELOW THE SOUTHEASTERN MARGIN OF TIBETAN PLATEAU AND ITS ADJACENT REGIONS

In this paper we present results of spectral structure of crustal velocity inhomogeneity beneath the southeastern margin of Tibetan plateau and its adjacent region based on the S wave envelope broadening algorithm. The spectral structure of 8~16Hz band is selected to analyze the special character of crustal inhomogeneity and discuss the correlation between strong earthquakes and inhomogeneities. The result shows that strong and complex inhomogeneities of crustal medium are found in the southeastern margin of Tibetan plateau and its adjacent region. In the upper part of upper crust, the strong and small scale inhomogeneities are imaged in the Longmengshan fault zone and the north of the Anninghe fault zone, the weak and large scale inhomogeneites are imaged in the section from Huolu to Daofu of Xianshuihe fault zone and the south of the Anninghe fault zone. In the lower part of upper crust, strong inhomogeneites are found in the Longmengshan fault zone, Lianfeng fault zone, the north of the Anninghe fault zone and the sections from Huolu to Daofu of the Xianshuihe fault zone, weak inhomogeneites are found in the section from Daofu to Kangding of Xianshuihe fault zone. In the middle crust, strong inhomogeneities are observed in the section of the Baoxing to Dujiangyan, the Baoxing to Kangding, and Kangding to Shimian, and weak inhomogeneities are observed in the northwestern section from Huolu to Kangding, and the Lianfeng fault zone. Comparing the medium inhomogeneities with the location of the strong earthquakes, our results suggest existence of high correlation between them. Strong earthquakes are often located in the transitionary zone between the strong and the weak inhomogeneities. The spatial distribution of the strong and the weak medium inhomogeneities may be related to the broken medium from the strong movement of geological tectonic and the heat flow upwelling along active faults induced by frequent tectonic and volcanic activity.     

CHARACTERISTICS OF MULTI-SCALE GRAVITY FIELD VARIATION AND SEISMOGENIC MECHANISM ANALYSIS IN THE SOUTHEASTERN TIBETAN PLATEAU

As the most basic geophysical field, the earth gravity field has achieved wide attention, and its spatial anomaly characteristics and dynamic variation can provide important scientific basis for studying the internal structure and dynamics of the Earth. Based on the mobile gravity observation data of the southeastern Tibetan plateau from 2013 to 2016, the dynamic variation tendency and anomaly characteristics of the regional gravity field in different temporal resolutions are obtained before and after the Ludian and Jinggu earthquakes in the study area respectively. The method of wavelet multi-scale decomposition is used to analyze the relationships of gravity field variation with the earth movement, material density change, and strong earthquake preparation. The deep material variation, dynamic process and the mechanism of earthquake inoculation in the southeastern Tibetan plateau are further discussed. Results indicate that the gravity field variation in the source region before the Ludian and Jinggu earthquake respectively is characterized by obvious positive and negative anomalous transition zone and gradient zone that are consistent with the direction of fault tectonics, suggesting the strong crustal movement and mass migration during the earthquake incubation period. The result of wavelet multi-scale decomposition of the gravity field during the period from September 2013 to April 2014 shows that the gravity field variation at different depth and space scale in the crust and upper mantle of the southeastern Tibetan plateau is significantly correlated with seismic distribution and the location of active fault zone. This indicates that the earthquake inoculation in the study area is closely related to the fault movement and the distribution of material density in the crust and upper mantle, which may be affected by the complex deep dynamic process of the material migration in the crust and mantle. The characteristic that strong earthquakes always occur near positive and negative anomaly transition zones and gradient zones of gravity field change is preliminarily explained, based on the dynamic process of material migration in the crust and upper mantle of the southeastern Tibetan plateau. The research results of this paper have some reference value to the study on the earth movement and seismogenic mechanism.     

THE THREE DIMENSIONAL DENSITY STRUCTURE OF CRUST AND UPPER MANTLE IN THE CENTRAL-SOUTHERN PART OF LONGMENSHAN

In recent years, strong earthquakes of M_S8.0 Wenchuan and M_S7.0 Lushan occurred in the central-southern part of Longmenshan fault zone. The distance between the two earthquakes is less than 80 kilometers. So if we can obtain the inner structure of the crust and upper mantle, it will benefit us to understand the mechanism of the two earthquakes. Based on the high resolution dataset of Bouguer gravity anomaly data and the initial model constrained by three-dimensional tomography results of P-wave velocity in Sichuan-Yunnan region, with the help of the preconditioned conjugate gradient(PCG)inversion method, we established the three dimensional density structure model of the crust and upper mantle of the central-southern segment of Longmenshan, the spatial interval of which is 10 kilometers along the horizontal direction and 5 kilometers along the depth which is limited to 0~65km, respectively. This model also provides a new geophysical model for studying the crustal structure of western Sichuan plateau and Sichuan Basin. The results show obvious differences in the crustal density structure on both sides(Songpan-Ganzê block and Sichuan Basin)of Longmenshan fault zone which is a boundary fault and controls the inner crustal structure. In Sichuan Basin, the sedimentary layer is represented as low density structure which is about 10km thick. In contrast, the upper crust of Songpan-Ganzê block shows a thinner sedimentary layer and higher density structure where bedrock is exposed. Furthermore, there is a wide scale low density layer in the middle crust of the Songpan-Ganzê block. Based on this, we inferred that the medium intensity of the Songpan-Ganzê block is significantly lower than that of Sichuan Basin. As a result, the eastward movement of material of the Qinghai-Tibet plateau, blocked by the Sichuan Basin, is inevitably impacted, resulting in compressional deformation and uplift, forming the Longmenshan thrust-nappe tectonic belt at the same time. The result also presents that the crustal structure has a distinct segmental feature along the Longmenshan fault zone, which is characterized by obviously discontinuous changes in crustal density. Moreover, a lot of high- and low-density structures appear around the epicenters of Wenchuan and Lushan earthquakes. Combining with the projection of the precise locating earthquake results, it is found that Longmenshan fault zone in the upper crust shows obvious segmentation, both Wenchuan and Lushan earthquake occurred in the high density side of the density gradient zone. Wenchuan earthquake and its aftershocks are mainly distributed in the west of central Longmenshan fault zone. In the south of Maoxian-Beichuan, its aftershocks occurred in high density area and the majority of them are thrust earthquake. In the north of Maoxian-Beichuan, its aftershocks occurred in the low density area and the majority of them are strike-slip earthquake. The Lushan earthquake and its aftershocks are concentrated near the gradient zone of crustal density and tend to the side of the high density zone. The aftershocks of Lushan earthquake ended at the edge of low-density zone which is in EW direction in the north Baoxing. The leading edge of Sichuan Basin, which has high density in the lower crust, expands toward the Qinghai-Tibet Plateau with the increase of depth, and is close to the west of the Longmenshan fault zone at the top of upper mantle. Our results show that there are a lot of low density bodies in the middle and lower crust of Songpan-Ganzê Block. With the increase of the depth, the low density bodies are moving to the south and its direction changed. This phenomenon shows that the depth and surface structure of Songpan-Ganzê Block are not consistent, suggesting that the crust and upper mantle are decoupled. Although a certain scale of low-density bodies are distributed in the middle and lower crust of Songpan-Ganzê, their connectivity is poor. There are some low-density anomalies in the floor plan. It is hard to give clear evidence to prove whether the lower crust flow exists.     

北京西北地区壳幔结构的非均匀性特征与地震活动

利用在北京西北部地区穿过张家口——渤海地震带北西段地震测深剖面进行了综合解释和研究, 揭示了延庆——怀来、 张北——尚义地震活动区异常的深浅地壳结构特征. 结果表明: 研究区基底结构具有明显的起伏变化, 不同的地质构造单元基底埋深存在着较大差异. 基底埋深在局部地段呈现出的急剧变化可视其为基底断裂存在的一种标志, 基底断裂与地壳深断裂的存在为岩浆的上溢提供了条件, 从而导致了地壳结构强烈的非均匀性. 延怀地区壳内复杂反射波组序列和局部强弱不连续反射带现象的出现, 表明该地区地壳结构发生了强烈的挤压变形, 从而构成了该地区复杂的地壳结构, 为该地区地震的发生提供了动力来源; 张北——尚义地区壳内不同深度范围低速异常体和局部的C1界面的存在, 可以认为是岩浆多期活动的产物, 在区域构造活动的作用下脆性的上地壳内, 当局部应力积聚到一定的程度从而引发了地震的发生.      

云南南部地区深部电性结构特征研究

在云南南部地区布设了一条孟连-罗平的北东向大地电磁测深剖面,以开展该地区的深部电性结构探测和孕震环境探查.沿该剖面进行了114个大地电磁测深点的观测,经过对观测资料的远参考Robust处理、定性分析和二维反演,得到了沿该剖面地壳、上地幔电性结构模型,从模型的电性结构特征进一步探讨了剖面穿过的3个地震区的深部地震孕育环境.研究结果表明：沿剖面的地壳上地幔电性结构反映出与区域地质构造资料基本一致的构造特征;该区的三个强震带地球深部都存在壳内低阻体,地震发生在电阻率梯度带上;断裂带的两侧块体介质的电阻率差异是强震活动带重要的深部背景.     

张北—尚义地震区的壳幔构造

通过对河北张家口地区的深地震测深宽角反射／折射剖面资料的研究表明：近东西向的张北—崇礼地壳断裂带与北西西向的张家口—渤海地壳深断裂带在张北６２级地震区交汇。在这里延伸至莫霍面的地壳深断裂带和壳内界面的不连续处是汉诺坝大面积玄武岩溢出的通道。震区中上地壳内的局部速度逆转和下地壳内异常的低速带预示着岩浆活动仍较强烈。张家口—渤海地壳深断裂带近期活动可能是张北地震发生的主要因素     

Seismotectonic Study on the West Part of the Interaction Zone Between Southern Tianshan and Northern Tarim

The interaction zone between southern Tianshan and northern Tarim is located at the northeast side of Pamir. It is a region with high seismicity. We constructed a seismotectonic model for the west part of this zone from geological profiles, deep crust seismic detection and earthquake focal mechanisms data. Based on the synthesized geological features, deep crust structure, and earthquake focal mechanisms, we think that the main regional tectonic feature is that the Tianshan tecto-lithostratigraphic unit overthrusts on the Tarim block. The Tianshan tectonic system includes the Maidan fault and thrust sheets in front of the fault; The Tarim tectonic system includes the underground northern Tarim margin fault, conjugate faults in basement and overthrust fault in shallow. The northern Tarim margin fault is a high angle fault deep in the Tarim crust, adjusting different trending deformation between Tianshan and Tarim. It is a major active fault that can generate large earthquakes. The other faults, such as the Tianshan overthrust system and the Tarim basement faults in this area may generate moderately strong earthquakes with different styles.