山西地区ML≥3.0地震震源机制解研究

选取2007年至2010年ML≥3.0的49个地震,重点研究该时间段内山西发生的5次ML4.0以上的地震,通过snoke方法的计算结果,与仅用振幅比方法所得的结果进行对比分析,结果表明,snoke方法是可行的。     

Incidence, reflection and transmission angles in anisotropic media

IntroductionGenerallyspeaking,theinclusionofanisotropy(exceptdeclaration,anisotropyreferstohomogenousanisotropy)rendersthemathematicalformulationquitecomplicated.Snell'Slawisnotanexceptionandthecalculationofreflectionandtransmissionanglesisnotatrivialtask.ThegraphicalapproachestocalculatingreflectionandtransmissionanglesforanisotropicmediawerepresentedbyAuld(1973)andRokhlin,etal(1986).DaleyandHorn(1977,1979)andSlawinski(1996)deriveSnell'slawintheparticularcasesoftransverselyisotropicandelli…     

华东地区主要矿山环境地质问题

华东地区经济发达,人口密集,城市化程度较高。对环境要求也高。但是华东地区资源丰富,涉及的矿种多,数量大,矿产资源开发普遍,由此造成的矿山环境地质问题比较突出。本文详细分析了华东地区矿产资源开发引发的矿山环境地质问题,如土地资源破坏和占用、水资源破坏、水土污染和矿山地质灾害等,指出区内因矿产资源开发引发的资源损毁、环境污染以及地质灾害的规模,分析引发矿山环境地质问题的主要自然和人为因素。     

地震力对高架桥梁轨道车辆影响之动态模型

将轨道车辆系统仿真成由车厢、转向架及轮轴所组成。车厢与转向架间有次悬吊系统,转向架与轮轴间则有主悬吊系统。数学模型之推导将考虑车辆横向、垂向、翻滚(roll)及摇摆(yaw)方向之运动,将车辆仿真成三维具16个自由度之系统。本研究将探讨行驶高架桥梁之轨道车辆受地震激振时,建立轨道车辆与高架桥相互耦合之动态数学模型。     

筒桩基础的地震反应分析

本文基于Biot动力固结方程，在BDWF模型的基础上，通过等价线性迭代不断修正土体模量以逼近土体的非线性动态响应，对建筑筒桩基础的地震反应进行了动力分析。为了分析筒桩基础的地震反应，考虑桩-土-结构的动力相互作用，将桩-土-结构地震反应分析的空间体系简化为二维问题计算。结果表明，筒桩基础桩基相对桩基于桩基有较好的抗震性能，筒桩基础的柔性改善了结构的基本周期。     

GIS技术在油气勘探中的应用及发展趋势

GIS是处理空间信息的强大工具,GIS应用于油气勘探中,能够有效的分析潜在资源,发现新资源或扩展现有资源。今后,网络GIS、三维甚至高维GIS是GIS在油气勘探领域应用的重要发展方向。     

物探方法在水库坝基渗漏勘探中的应用

近年来物探方法在坝基勘探、活断层探测、溶洞探测和基础检测等工程中得到广泛应用,并取得了令人瞩目的成绩。本文介绍了在某水库坝基渗漏勘探开展物探工作的情况,取得了满意的结果,表明应用多种物探方法对解决工程问题具有较好的效果。     

短时气压干扰下TJ-Ⅰ、TJ-Ⅱ型体应变观测频谱对比分析

短时气压干扰是形变观测中常见且显著的影响因素之一。本文选取易县地震台2015年3月1日至12月31日的TJ-Ⅰ型和TJ-Ⅱ型体应变观测分钟数据为研究对象,对受气压干扰的主测项与钻孔气压观测值进行对比分析,利用小波变换方法分别提取出高、低气压环境干扰下两台仪器观测值在不同频段的频谱特征,结果显示:对于短时气压干扰,TJ-Ⅰ型与TJ-Ⅱ型体应变均与气压变化发生同步响应;在高气压干扰下,两套体应变主测项及其辅助气压测项分别在其小波6阶细节上的变化同步且相关系数接近;对于低气压干扰,TJ-Ⅱ型体应变主测项与其钻孔气压测项在高频6阶的节相关系数更大,说明TJ-Ⅱ型体应变更易于在高阶细节部分识别低气压干扰。     

痕量氢观测环境及供电系统建设

应用ATG-6118H痕量氢在线自动分析仪在水井类观测点观测过程中发现,外界观测环境的变化对于痕量氢浓度的观测存在一定干扰。文章依据宁河痕量氢观测井的观测环境及供电系统的改造过程,对2017年11月11日井房改造完成前后的痕量氢浓度数据进行分析论述,为该仪器的后续观测提供一些借鉴经验。     

APPLYING 3D INVERSION OF SINGLE-PROFILE MAGNETOTELLURIC DATA TO IDENTIFY THE SHADE AND YUNONGXI FAULTS

Many synthetic model studies suggested that the best way to obtain good 3D interpretation results is to distribute the MT sites at a 2D grid array with regular site spacing over the target area. However, MT 3D inversion was very difficult about 10 years ago. A lot of MT data were collected along one profile and then interpreted with 2D inversion. How to apply the state-of-the-art 3D inversion technique to interpret the accumulated mass MT profiles data is an important topic. Some studies on 3D inversion of measured MT profile data suggested that 2D inversions usually had higher resolution for the subsurface than 3D inversions. Meanwhile, they often made their interpretation based on 2D inversion results, and 3D inversion results were only used to evaluate whether the overall resistivity structures were correct. Some researchers thought that 3D inversions could not resolute the local structure well, while 2D inversion results could agree with the surface geologic features much well and interpret the geologic structures easily. But in the present paper, we find that the result of 3D inversion is better than that of 2D inversion in identifying the location of the two local faults, the Shade Fault(SDF)and the Yunongxi Fault(YNXF), and the deep structures. In this paper, we first studied the electrical structure of SDF and YNXF based on a measured magnetotelluric(MT) profile data. Besides, from the point of identifying active faults, we compared the capacity of identifying deep existing faults between 2D inversion models and 3D models with different inversion parameters. The results show that both 2D and 3D inversion of the single-profile data could obtain reasonable and reliable electrical structures on a regional scale. Combining 2D and 3D models, and according to our present data, we find that both SDF and YNXF probably have cut completely the high resistivity layer in the upper crust and extended to the high conductivity layer in the middle crust. In terms of the deep geometry of the faults, at the profile's location, the SDF dips nearly vertically or dips southeast with high dip angle, and the YNXF dips southeast at depth. In addition, according to the results from our measured MT profile, we find that the 3D inversion of single-profile MT data has the capacity of identifying the location and deep geometry of local faults under present computing ability. Finally, this research suggests that appropriate cell size and reasonable smoothing parameters are important factors for the 3D inversion of single-profile MT data, more specifically, too coarse meshes or too large smoothing parameters on horizontal direction of 3D inversion may result in low resolution of 3D inversions that cannot identify the structure of faults. While, for vertical mesh size and data error thresholds, they have limited effect on identifying shallow tectonics as long as their changes are within a reasonable range. 3D inversion results also indicate that, to some extent, adding tippers to the 3D inversion of a MT profile can improve the model's constraint on the deep geometry of the outcropped faults.