乌鲁木齐碗窑沟断层电阻率成像探测与探槽剖面的对比研究

利用电阻率二维层析成像方法对碗窑沟断层进行了试验探测,获得了该断层典型的电阻率成像异常特征:地层电性结构存在强间断面,呈现明显的"二分"现象,高、低阻间的梯度界线倾向低阻区。在对乌鲁木齐地区其它具有类似构造特征的断层进行探测时,电阻率成像剖面呈现出相似的异常特征,说明这一异常特征可以作为乌鲁木齐地区判定断层的重要标志和依据。乌鲁木齐地区多为高角度的逆冲断层,此类构造电阻率成像剖面中高、低阻之间的界线与断层并不重合,断层处于高阻区域,倾向与视电阻率衰减梯度线倾向相反,断层的真实位置与图像最上部高、低电阻转折的拐点部位最接近     

高密度电阻率二维层析成像在郯庐断裂带山东潍坊段试验结果的初步分析

在城市活断层调查中,利用电阻率二维层析成像测量方法,对郯庐断裂带山东潍坊段的地震活断层进行了探测试验,取得了较理想的勘探效果。沂水-汤头断裂、刘家庄断裂的二维电阻率反演结果表明,断裂带两侧的电性结构呈现出整体性的差异,正断层的上盘为低阻区和局部高、低阻扰动区;而断层下盘多为均匀的高阻区;断层为高角度断层。试验探测表明:在城市活断层调查中,选用合适的电极装置类型,电阻率层析成像是一种有效的勘探方法     

地球层析成像在减轻灾害中的作用

目的说明地球层析成像一词的含义和它所包括的分支有:地震层析,电阻率层析,大地电磁层析,磁共振成像, 地震破裂面照相以及探地雷达成像等.概括当前这几种手段的成就,所能达到的成像精密度, 用现代的计算方法、反演地下介质速度、衰减Q值、密度、孔隙度分布、介质破裂程度,可提高震源定位精度,再借鉴医学上检测癌细胞发生、发展过程的模式,建立相应的预测模式.判断未来破坏性地震的孕震结构,发展趋势,以及地下水与电阻率图像随季节变化的关系.初步阐明地球层析成像在减轻地震灾害、洪水灾害与火山喷发灾害中的作用.将地电阻率层析与磁共振测深成像相结合应用于探测地下水的一些基本分布特征,判定潜伏断层的特征,追踪电阻率异常区其附近的电性精细结构,分辨率可以达到1米左右.结合起来可探测地下裂隙分布,发现活断层,对高层建筑物(80米以上)和大型桥梁、水坝、堤防的安全性评价具有重要作用,以便及早加固,以减轻损失;结论利用上述地球层析成像的几种手段,可以探测地下活动断层、孕震结构和地下水与电阻率随季节的变动,为判定高楼和堤坝的安全性提供依据,在减轻灾害中发挥日益重要的作用.     

地震监测中的电阻率层析技术

将电阻率层析技术应用于地震监测,由视电阻率值重建出介质的真电阻率图像,取得了较好效果.在宝坻台和昌黎台设立的两个试验点上于1998年4月14日ML5.0和ML4.4唐山两次地震前的6天左右层析图像出现了明显的异常变化:宝坻台的电阻率图像一改通常的在平稳背景上叠加小量随机变化的特点,出现了一种有序性特征的新图样;昌黎台也出现了反差加大、高低阻区集中分布的有序性特征.上述异常图样均在震后消失.层析图像在震前出现的熵值降低可能是这次地震活动的前兆.地层导电结构和孔隙度的变化,是引起电阻率异常的直接原因.研究表明,常规的单一极距的视电阻率测量之所以对真电阻率的变化不敏感且丧失空间分辨能力,是由于该物理量同时具有积分值和位函数这两个固有特征所决定的.在地震监测中,改造现行观测系统,引入层析成像,是发展技术的方向.     

鄂尔多斯盆地苏东南地区盒8段低阻气层识别

上古生界二叠系下石盒子组盒8段是苏东南地区主力产气层段之一,低阻气层相对较发育,其测井响应表现为低自然伽马、高声波时差、低密度和低电阻率特征.根据常规测井处理方法,对苏东南地区50口试气井106个试气层段进行了电阻率与声波时差参数交会图分析,结果发现低阻气层的电阻率数值分布范围与邻近水层的电阻率基本相当,甚至有些含气段的电阻率比水层的电阻率低,在电阻率与声波时差参数交会图中,含气层的分布区与气水同层分布区相混,无法准确区分.另外,低阻气层在深侧向电阻率和声波时差测井曲线重叠图上基本无幅度差,这就可能造成有效含气层的漏失.针对上述这种电阻率相对较低的气层,利用非电阻率测井信号,优选声波孔隙度(ФS)、密度孔隙度(ФD)、中子孔隙度(ФN)测井资料进行重叠图处理(ФS-ФN、ФD-ФN),并增加纵波等效弹性模量差比值参数来综合识别气层.在含气层段,一般具有ФSФN、ФDФN、等效弹性模量差比值大于0.1的特征.上述综合识别含气层的方法,其判别结果不受电阻率的影响,因此在低阻气层发育的部位能够有效识别气层.经对50口试气井106个试气层段试气资料进行处理,气层识别综合符合率达95.8%.     

沿河开发建筑场地之隐伏沙洞的电阻率层析成像

采用电阻率层析成像二维测量的方法,对河南省三门峡市沿河开发的建筑场地进行了勘探,获取了地下隐伏沙洞的准确位置、埋藏深度、含水情况、尺寸大小等。说明电阻率层析成像二维测量的方法在地下隐伏沙洞的探测中是行之有效的;地下隐伏沙洞在没有水体存在时,电阻率层析成像二维测量成果图中反映的一般都是高阻异常封闭圈。如果有水体存在,其异常则表现为低阻异常封闭圈。     

速度差对井间走时层析成像质量的影响及其改进方法

在井间地震初至走时层析成像中，随着相邻地质体速度差的增大，使得射线分布不均匀，以及网格剖分不合适，导致层析成像结果不理想.物理和数值模型的井间走时层析成像表明：当速度差超过300%时，层析结果畸变较大；在300%～150%之间时，层析结果较好；低于150%时，层析结果好.在此基础上，提出了井间多尺度初至走时层析成像方法，即对同一模型采用多种网格剖分来同时进行层析成像，以获得研究区域的速度图像.数学和物理模型的井间多尺度走时层析结果表明：该方法很好地兼顾了层析成像的分辨率和精度，极大地改善了井间地震层析成像的质量.即使速度差超过30%，其多尺度的层析结果仍然较好.因此，这种方法具有实际应用的潜力.     

地球物理方法在含油工业污水管道渗漏探测中的应用

基于含油污水管道渗漏形成土壤污染区的物性改变，利用高密度电阻率法、自然电位法、探地雷达的方法对污染区进行了探测，试图通过污染区的分布特征确定渗漏点的存在.基于异常区布设的钻孔取样分析资料显示，含油污水的侵入会引起地下粘土层的电阻率增高，随着侵入量的增大电阻率越大，相应的探测电剖面异常区表现为高阻特征；相应位置的自然电位曲线显示低电位特征，探地雷达图像则表现为低频，高幅的特征.基于异常区的分布特征可以确定渗漏点的分布位置.研究结果证实了地球物理方法对此类工业污水污染区探测的可行性.     

劣质地下水区地球物理勘查技术模式探讨

在自然界,高氟、高砷、高矿化度劣质地下水(简称"三高地下水")一般多为伴生关系,且多赋存于以黏土、亚黏土等细颗粒为主的沉积岩地层中,细颗粒岩性及高矿化度地下水表现为低电阻率的地球物理特征。因此,通过圈定低电阻率值的分布范围划分出细颗粒岩性地层与高矿化度地下水的分布范围,从而达到在劣质地下水区中圈定出可饮用地下水分布范围的目的。文中通过对地层电阻率、地下水电阻率与地下水孔隙度、地下水矿化度之间数学关系的研究,建立了以高分辨率电法为主的在劣质地下水区勘查可饮用地下水的地球物理勘查模式,并在新疆等地进行了应用,取得了较好的效果,为在劣质地下水区勘查可饮用地下水提供了一种新的技术思路。     

中国大陆地壳上地幔电性特征

根据大地电磁测深调查结果，编制了中国大陆３０，９０，１５０ｋｍ三个深度的电阻率图以及壳内低阻层和上地幔低阻层的顶面深度图。在９０ｋｍ深度的电阻率图上发现了一个自松辽盆地直到扬子地台西南缘的北东－南西向巨大低阻异常带．１５０ｋｍ深度的电阻率图上显示出在低阻的背景上镶嵌着一些高阻块体．中国大陆的壳内低阻层深度国基本上反映了地温场的特征，壳内低阻层上隆区基本上对应于高地温区．中国大陆的上地幔低阻层深度变化大．最浅处仅５０－６０ｋｍ，大多位于构造活动地区；最深处达２００ｋｍ以上，大部分对应于稳定地区．中国大陆的上地幔低阻层平均深度为１００－１２０ｋｍ，东部浅，西部深。     

The Application of Geotomography in Engineering

It seems that electromagnetic tomography is quite suitable to be used in metal and groundwaterexploration. especial for limestone areas where the absorption coefficient of electromagnetic wave is smalland geological body has a large property contrast with country rock it should be pointed out that there exitsome uncertainties in geological interpretation of EM tomogram, corresponding laboratory tests for rockphysical property are always necessary.Resistivity tomography provides us a new useful…     

地下介质和物流运移的综合成像方案

目的：借鉴描述冷暖气流等多科参数(气压、温度和湿度、风速、风向、水蒸汽密度等)的动态三维显示,初步解决了暴雨和天气预报的难题,促进了天气预报的成功,在地球科学中起到了示范作用。从而联想到在地下介质和物流运移过程的综合成像。资料和方法本文总结了地面和地下探测手段的多样性,列举了天然地震CT的精度已能达到l～5km的量级,地震人工曝破作勘探可以达到10～20米的成像分辨率,地下电阻率和电磁成像可以分辨到l—2米的量级;将磁共振(MRI)用于地下成像可得到地下水分布的动态观测深度,概括了这三方面的前沿性进展,并与震源的空间分布和地应力相结合,进而设计出综合性的观测系统。发展地下水、岩浆、地应力和活断层结构和地震破裂面等多种参数的动态显示,设计出一套观测系统,并阐述言的科学意义。结果和结论：将以上三方面的观测方法综合起来;可在有火山喷发危险的区域,具有诱发地震危险的大型水库地区,和在发生了强烈地震的地区,为了抗震救灾,有必要同时进行以上三个系统的观测,引入可视化数字科技,便于了解地下水和岩浆的过移过程及相关参数的变化,并配合当前已有的综合监测系统（震源空间分布、地震应力和其他前兆等）,服务于保障大型水库的安全、促进强震预测,及对火山喷发、矿井塌陷、突出的监测预报。     

The Method for Inferring a Buried Fault from Resistivity Tomograms and Its Typical Electrical Features

Electrical resistivity tomography (ERT) has been used to experimentally detect shallow buried faults in urban areas in the past a few years, with some progress and experience obtained. According to the results from Olympic Park, Beijing, Shandong Province, Gansu Province and Shanxi Province, we have generalized the method and procedure for inferring the discontinuity of electrical structures (DES) indicating a buried fault in urban areas from resistivity tomograms and its typical electrical features. In general, the layered feature of the electrical structure is first analyzed to preliminarily define whether or not a DES exists in the target area. Resistivity contours in resistivity tomograms are then analyzed from the deep to the shallow. If they extend upward from the deep to the shallow and shape into an integral dislocation, sharp flexure (convergence) or gradient zone, it is inferred that the DES exists, indicating a buried fault. Finally, horizontal tracing is be carried out to define the trend of the DES. The DES can be divided into three types-type AB, ABA and AC. In the present paper, the Zhangdian-Renhe fault system in Zibo city is used as an example to illustrate how to use the method to infer the location and spatial extension of a target fault. Geologic drilling holes are placed based on our research results, and the drilling logs testify that our results are correct. However, the method of this paper is not exclusive and inflexible. It is expected to provide reference and assistance for inferring the shallow buried faults in urban areas from resistivity tomograms in the future.     

Image processing of 2D resistivity data for imaging faults

A methodology to locate automatically limits or boundaries between different geological bodies in 2D electrical tomography is proposed, using a crest line extraction process in gradient images. This method is applied on several synthetic models and on field data set acquired on three experimental sites during the European project PALEOSIS where trenches were dug. The results presented in this work are valid for electrical tomographies data collected with a Wenner-alpha array and computed with an l₁ norm (blocky inversion) as optimization method. For the synthetic cases, three geometric contexts are modelled: a vertical and a dipping fault juxtaposing two different geological formations and a step-like structure. A superficial layer can cover each geological structure. In these three situations, the method locates the synthetic faults and layer boundaries, and determines fault displacement but with several limitations. The estimated fault positions correlate exactly with the synthetic ones if a conductive (or no superficial) layer overlies the studied structure. When a resistive layer with a thickness of 6 m covers the model, faults are positioned with a maximum error of 1 m. Moreover, when a resistive and/or a thick top layer is present, the resolution significantly decreases for the fault displacement estimation (error up to 150%). The tests with the synthetic models for surveys using the Wenner-alpha array indicate that the proposed methodology is best suited to vertical and horizontal contacts. Application of the methodology to real data sets shows that a lateral resistivity contrast of 1:5–1:10 leads to exact faults location. A fault contact with a resistivity contrast of 1:0.75 and overlaid by a resistive layer with a thickness of 1 m gives an error location ranging from 1 to 3 m. Moreover, no result is obtained for a contact with very low contrasts (1:0.85) overlaid by a resistive soil. The method shows poor results when vertical gradients are greater than horizontal ones. This kind of image processing technique should be systematically used for improving the objectiveness of tomography interpretation when looking for limits between geological objects.     

Image processing of 2D resistivity data for imaging faults

A methodology to locate automatically limits or boundaries between different geological bodies in 2D electrical tomography is proposed, using a crest line extraction process in gradient images. This method is applied on several synthetic models and on field data set acquired on three experimental sites during the European project PALEOSIS where trenches were dug. The results presented in this work are valid for electrical tomographies data collected with a Wenner-alpha array and computed with an l₁ norm (blocky inversion) as optimization method. For the synthetic cases, three geometric contexts are modelled: a vertical and a dipping fault juxtaposing two different geological formations and a step-like structure. A superficial layer can cover each geological structure. In these three situations, the method locates the synthetic faults and layer boundaries, and determines fault displacement but with several limitations. The estimated fault positions correlate exactly with the synthetic ones if a conductive (or no superficial) layer overlies the studied structure. When a resistive layer with a thickness of 6 m covers the model, faults are positioned with a maximum error of 1 m. Moreover, when a resistive and/or a thick top layer is present, the resolution significantly decreases for the fault displacement estimation (error up to 150%). The tests with the synthetic models for surveys using the Wenner-alpha array indicate that the proposed methodology is best suited to vertical and horizontal contacts. Application of the methodology to real data sets shows that a lateral resistivity contrast of 1:5–1:10 leads to exact faults location. A fault contact with a resistivity contrast of 1:0.75 and overlaid by a resistive layer with a thickness of 1 m gives an error location ranging from 1 to 3 m. Moreover, no result is obtained for a contact with very low contrasts (∼1:0.85) overlaid by a resistive soil. The method shows poor results when vertical gradients are greater than horizontal ones. This kind of image processing technique should be systematically used for improving the objectiveness of tomography interpretation when looking for limits between geological objects.     

Geophysical Investigation of Seepage Beneath an Earthen Dam

A hydrogeophysical survey is performed at small earthen dam that overlies a confined aquifer. The structure of the dam has not shown evidence of anomalous seepage internally or through the foundation prior to the survey. However, the surface topography is mounded in a localized zone 150 m downstream, and groundwater discharges from this zone periodically when the reservoir storage is maximum. We use self‐potential and electrical resistivity tomography surveys with seismic refraction tomography to (1) determine what underlying hydrogeologic factors, if any, have contributed to the successful long‐term operation of the dam without apparent indicators of anomalous seepage through its core and foundation; and (2) investigate the hydraulic connection between the reservoir and the seepage zone to determine whether there exists a potential for this success to be undermined. Geophysical data are informed by hydraulic and geotechnical borehole data. Seismic refraction tomography is performed to determine the geometry of the phreatic surface. The hydro‐stratigraphy is mapped with the resistivity data and groundwater flow patterns are determined with self‐potential data. A self‐potential model is constructed to represent a perpendicular profile extending out from the maximum cross‐section of the dam, and self‐potential data are inverted to recover the groundwater velocity field. The groundwater flow pattern through the aquifer is controlled by the bedrock topography and a preferential flow pathway exists beneath the dam. It corresponds to a sandy‐gravel layer connecting the reservoir to the downstream seepage zone.     

高密度电法在大盈江隐伏断裂探测中的应用

简述了高密度电法基本原理,采用高密度电法对盈江盆地南侧的大盈江断裂隐伏段进行了探测。结果表明,大盈江断裂断错全新统地层,推断大盈江断裂为全新世活动断裂。结合探槽开挖结果对高密度电法揭示的隐伏断裂进行了验证,确定了大盈江断裂的走向、具体位置和活动时代。研究表明,高密度电法对隐伏断裂探测是一种简单易行的方法,同时为盈江县工程建设及防震减灾规划提供了依据。