2004年印尼8.7级强震前昌黎台的远场电性异常特征探讨

分析了在2004年12月26日印尼8.7级地震前河北昌黎台记录到的自然电位及电场异常, 结果显示昌黎台自电位、 电场正常时段观测到的半日、 半月潮汐波周期变化在震前1个多月发生畸变, 周期消失, 变化幅度相应减小, 震后快速恢复, 且潮汐波记录比震前正常时段更加清晰。 该台地电阻率的观测结果显示起始下降变化比较平缓, 震前一周左右, 变化加剧, 出现多次阶变。 究其原因, 在强震发生前断层的蠕滑作用导致孔隙压力变化, 产生一种可以在岩石中传播的应变波, 由于台站下方岩土层对小应变信号具有很好的放大作用, 所以记录到了这种小幅度的应变波, 也就是远场的静态应变效应。 随着地震临近, 应力作用加强, 远程应变波引起台站下方水位、 水化学性质以及岩石孔隙度、 渗透率等的改变, 导致电阻率、 电场大幅度的阶变, 这反映了远场应变波的动态效应。 当然就异常幅度而言, 应变波的效应还嫌弱一些, 因此昌黎台异常变化可能还叠加了震源区激发的电磁波。     

井资料高分辨率层序地层学

在准层序中进行层组一级地层单元的识别和对比是高分辨率层序地层学研究的主要难点.提出了一种综合应用井资料进行层组界面识别和对比的新方法.通过测井曲线形态特征、岩心观察、铸体薄片、X衍射、扫描电镜分析、FMI测井资料, 对工区内钙质夹层成因、泥岩电阻率差异、储层电阻率和海拔深度关系进行了研究.结果表明: 钙质夹层单层厚度在0.5~2m之间, 靠近风化壳和断层位置单层厚度大, 分布在水下分支河道底部和河口坝顶部; 低阻泥岩(4~5Ω·m)和高阻泥岩(> 10Ω·m) 分别来源于不同的沉积物源或者形成于不同的沉积相带; 储层电阻率随着海拔深度的增加而增加.因此, 钙质夹层可以作为层组界面识别和对比的标志, 利用泥岩电阻率差异可以确定层组的叠置关系, 判断储层连通性.据此, 建立了准噶尔盆地石南地区西山窑组含油层段等时地层格架, 确定了格架内储层的连通性及油水界面, 并且通过MDT测井资料进行了验证.在此等时地层格架内, 层组的发育顺序、叠置关系、空间展布形态、以及彼此之间的连通性都被定性、定量的表征出来.      

非常规电测深法在工程地质勘查中的应用

本文提出了“非常规电测深法”的概念及实际操作过程,阐述了其应用条件和效果.存在高阻屏蔽层时电法解释较为困难.针对这一情况,本文提出了高阻屏蔽层影响的校正方法,提高了电法解释的精度和效果.     

综合物探方法在堤防质量检测中的应用

在堤防质量检测中,地球物理方法能够实现快速、无损的探测,但采用单一物探方法对堤防隐患的判别易形成多解,也很难对堤防质量做出准确分类.本文中应用探地雷达、高密度电法、地震勘探等综合物探方法对大源渡堤防质量进行检测,并以龙荫港以例,通过综合三种物探方法互相参照、相互验证,互为补充,查明了堤防隐患的分布位置与埋深,为堤防质量检测提供一种新的工作方法.     

无线电磁法(WEM)在地球物理勘探中的初步应用

无线电磁法(WEM)是上世纪90年代发展起来的一种新的人工源电磁探测技术,它通过一个固定大功率发射台发射0.1~300 Hz超低频/极低频电磁信号来探测地下地质结构.国内对WEM法的应用已做了大量的理论和实际试验工作,例如,大功率发射台辐射的电磁场计算,不同距离电磁信号发射接收试验,油田深部结构探测试验等.从试验的结果看,WEM法在提高电磁测深数据质量上具有很大的优势.     

井地电阻率法歧离率确定高阻油气藏边界

根据油气藏的特征,抽象出地球物理模型,利用有限元软件FEPG对三维油气藏模型的稳恒电流场进行了数值模拟.根据井地电阻率法计算结果,定义了一种新的参数歧离率,分析了不同深度油气藏和油气藏偏离钻井位置时歧离率的变化规律,并利用该参数及其梯度确定油气藏边界范围.理论分析表明,参数歧离率可很好地突出油气藏异常并确定其横向边界范围.     

高密度电阻率法在三星堆壕沟考古勘探中应用研究

三星堆遗址文化从新石器时代晚期延续发展至商末周初,延续时间近2000年,是迄今在西南地区发现的范围最大、延续时间最长、文化内涵最丰富的古城、古国、古蜀文化遗址,对三星堆遗址文明的溯源、遗址的发掘研究都具有重要意义.本文是利用高密度电阻率法勘探三星堆壕沟,其研究成果与壕沟情况十分吻合.     

Anticipating the effects of groundwater withdrawal on seawater intrusion and soil settlement in urban coastal areas

Intensive pumping in urban coastal areas is a common threat to water resource quality due to seawater intrusion. In those areas where subsurface water resources are not usually used for human consumption or irrigation, intensive pumping is associated with other activities like the lowering of the water table necessary to support underground structures and building foundations. This activity also increases the likelihood of soil settlement that affects building stability and the corrosion of concrete structures due to groundwater salinity. Under these circumstances, the awareness of a certain municipality (Calonge, NE Spain) of the potential effects of groundwater withdrawal upon foundations has led to an integrated approach to anticipate seawater intrusion related to urban development. Geological mapping and correlation of borehole logs, electrical resistivity tomography, and hydrochemical data provide comprehensive knowledge of the geology and hydrogeology of the area and act as screening tools necessary to discern the influence of hydrological processes in coastal areas. Developing Strack's analytical solution, new comprehensive, dimensionless expressions are herein derived to determine the critical pumping rate necessary to prevent seawater intrusion, as well as to reproduce the evolution of the wedge toe and the water table stagnation point under different withdrawal rates. Furthermore, the Dupuit–Forchheimer well discharge formula allows the estimation of the effects of the water table lowering due to such critical pumping in the surrounding building foundations. Field data from the Calonge coastal plain illustrate this approach and provide assessment criteria for future urban development and planning. Copyright © 2012 John Wiley & Sons, Ltd.     

Subsoil zoning of Mexico City using qualitative relationships between soil strength and electrical resistivity

Summary The seismic events occurring on 19 and 20 September 1985, whose epicentre was located in the coastal region of Michoacan, Mexico, produced tremendous damage in Mexico City. As a result of these losses the civil authorities of the city decided to study and evaluate the mechanical characteristics of the subsoil. To achieve this, it was necessary to drill several boreholes to obtain needed geophysical and geotechnical information. The geophysical method of electrical resistivity was the most appropriate to the research. This method enabled us to understand the structure and soil characteristics of the Mexican Valley.