三河—平谷8级大震区地壳上地幔电性结构特征研究

用电磁阵列剖面法（EMAP），大地电磁测深方法（MT），沿三河－平谷8级大震震源区，作了31.8km长的EMAP探测和两条总长150.05km共36个点的MT探测，获得了研究范围内的地壳上地幔电性结构，高导层特征和陡变带，高导异常体，断裂展布，岩石圈结构等结果，为搞清地震危险区的深浅构造关系，从电性结构特征推测发震模式和预测未来强震的可能地点提供了介质电性的多种参数。     

邢台7.2级地震震源区的电磁阵列剖面法测量与电性特征研究

为了取得邢台地震区地壳细结构,对该区进行了综合地球物理方法探测,其中电磁阵列剖面法（EMAP）测量在我国尚属首次．EMAP剖面穿过邢台7．2级地震区,经过EMAP阻抗求取、空间滤波处理和二维反演解释,剖面显示出清晰的地壳电性细结构特征：4km以上电性简单,4—20km深度电性复杂;震源区电性复杂,非源区简单;发震深度变化复杂;震源区电性突变,显示隐伏高角度断裂,高寻层不连续部位为发震部位．其观测结果对于了解该区的构造背景、发震构造和深部构造的关系有重要意义．     

邢台7.2级地震震源区的电磁阵列剖面法测量与电性特征研究

为了取得邢台地震区地壳细结构,对该区进行了综合地球物理方法探测,其中电磁阵列剖面法（EMAP）测量在我国尚属首次．EMAP剖面穿过邢台7．2级地震区,经过EMAP阻抗求取、空间滤波处理和二维反演解释,剖面显示出清晰的地壳电性细结构特征：4km以上电性简单,4-20km深度电性复杂;震源区电性复杂,非源区简单;发震深度变化复杂;震源区电性突变,显示隐伏高角度断裂,高寻层不连续部位为发震部位．其观测结果对于了解该区的构造背景、发震构造和深部构造的关系有重要意义．     

佳木斯地块及东缘岩石圈电性结构特征

佳木斯地块及东缘是中国东北地区的重要地质构造单元. 为探测该地区地壳深部结构与构造关系，沿桦南—饶河实施了240 km的大地电磁测深的探测研究. 采用光滑模型二维反演方法对桦南—饶河大地电磁剖面的探测数据进行了二维反演和综合地球物理解释. 研究结果揭示了研究区断面域的电性结构：(1)剖面西段具有稳定的高阻特征且具有稳定的岩石圈厚度（约90km），在十几公里深度范围存在壳内高导层，该区段对应佳木斯地块. (2)剖面中部具有明显的电性梯度带，该梯度带反映了佳木斯地块的东界位置及其深部的结构形态. (3)剖面东段电性特征揭示了佳木斯地块以东区段浅部为逆冲推覆体，深部为多个高阻块体和低阻条带相间的电性结构，这些高阻块体可能为早期俯冲的岩石圈残片.     

3D DEMAP数值模拟与观测实验

为推动电磁剖面(EMAP)技术向找矿勘探领域发展,本文针对密集阵列剖面(DEMAP)测量方式,利用三维积分方程法对层状介质中赋存三维地质异常体的电性结构进行了数值模拟,并在青海野马泉铁锌矿集区西部进行了大地电磁(MT)与DEMAP的野外对比观测实验.数值模拟结果显示,DEMAP观测方式获得的结果受偏移距影响,造成的视电阻率和相位误差与偏移距大小和地下电性结构的复杂性密切相关,但在整体上,统计误差≤10%.通过对野马泉矿集区的实验结果分析可得,DEMAP与MT的视电阻率断面和相位断面具有较好的一致性.本文从理论和实验上都表明DEMAP观测技术是一种有潜力的、经济、快速、有效的找矿手段.     

郯庐断裂带中段(沂沭断裂带)电性结构研究与孕震环境

穿过郯庐断裂带中段（沂沭断裂带,36°N）所做的大地电磁测深（MT）剖面长约150km.使用Robust技术和远参考道大地电磁方法处理观测数据.通过分析视电阻率、阻抗相位、Swift二维偏离度和区域走向,定性确定测区的电性结构.二维反演解释中选择非线性共轭梯度（NLCG）方法,使用TE、TM两种模式资料联合反演,沿剖面的二维电性结构显示：自西向东,鲁西隆起、郯庐断裂带、胶莱坳陷及鲁东隆起4个电性区块分别对应,鲁东和鲁西隆起区为高阻,郯庐断裂带电性结构复杂,高、低阻相间,胶莱坳陷为低阻（高导）区.沿MT剖面附近曾发生3个地震,其震源区处在电性变化剧烈部位,并在震源区附近存在高导体.     

青藏高原东边缘冕宁—宜宾剖面电性结构及其构造意义

在青藏高原东边缘沿冕宁—宜宾进行了大地电磁探测研究,剖面西起康滇地轴,向东穿过大凉山地块,终止于四川盆地.利用带地形的NLCG(非线性共轭梯度)方法对资料进行了反演,得到沿剖面的二维电性结构.康滇地轴和大凉山地块地壳中存在向上拱起的高导层(HCL),顶面埋深为10～15 km,最浅处不足10 km,厚度大约15～25 km,最小电阻率小于10 Ωm.四川盆地中下地壳不存在高导层.和该剖面北侧的石棉—乐山剖面的地壳电性结构对比分析表明,高导层在南北方向上可能连续延伸,长度大于100 km.壳内高导层的高导电性与岩石的部分熔融有关,并可能含有百分之几的含盐流体,易于流动和变形.青藏高原东部地壳内的可流动层在向东或东南方向流动过程中,由于受到四川盆地的阻挡,转向南或南南东方向,大体沿着大凉山地块的走向.在东西方向,壳内高导层自川滇地块向东运动,穿过大凉山地块西边界的安宁河断裂和则木河断裂,在大凉山地块东部,向四川盆地深部倾俯.本文对于壳内可流动层的存在及其与青藏高原东边缘的变形和地震活动性的关系进行了探讨.     

邢台地震区大地电磁观测与研究

在邢台地震区进行了大地电磁观测,并对该地区电性结构与地震的关系进行了研究.该地区地下电性结构较复杂,电性在纵向及横向都存在着显著的变化.一维结果表明,该地区电性纵向分布可分五层,第三层为高导层,埋深约10-20 km.在地震震源集中区,高导层深度有较大变化.电性横向分布也有明显变化.总体上看,地震区内电阻较高,可是地震并不发生在电阻率最高的地点,而多发生在电性变化较大地段.     

鲁南地区大地电磁测深结果

本文根据10大个地电磁测深点的探测资料,研究了鲁南地区深部电性结构特征。结果表明,在测区上地幔内存在两个高导层,第一高导层出现在上地幔较浅部位,厚度为3—7公里,电阻率值为8一30Ω·m,该层的埋藏深度横向变化较大,从50公里到80公里;第二高导层出现在230到280公里,电阻率值仅为几Ω·m,深度变化比较小,该区未发现壳内高导层的存在。本文还初步探讨了地壳,上地幔电性结构与区域构造和地震活动之间的关系。     

宁洱地震区深部电性结构及发震构造初析

在2007年6月3日宁洱6.4级地震区进行了宽频带(1000～1/4096Hz)大地电磁观测,采用了远参考道技术和Robust技术对观测数据进行了处理,分析了视电阻率和相位曲线、二维偏离度及区域电性结构方向,采用非线性共扼梯度(NLCG)二维反演技术对实测资料进行了反演,得到了与实测曲线拟合程度较高的反演模型。从二维解释结果可以看出:横向上,以12号测点为界,明显地划分为2个不同的电性分区,推测存在具一定延伸的断裂构造。纵向上,30km深度以上大致可分为4个电性层:1)中、新生代盆地沉积层(Mz—Cz),厚约1km。2)古生代沉积层(Pz),厚约5km。3)壳内高导层(HCL)。4)中、下地壳(MLC)。其中壳内高导层埋深在12号点左右存在较大的差异,推测在12—13号点下高导层顶部存在壳内的滑脱构造。宁洱地震震源深度为5km,文中所推测的滑脱构造位于这一层位上。认为该滑脱构造为本次地震的发震构造     

内蒙古锡林浩特-东乌旗剖面壳幔电性结构研究

为研究二连-东乌旗贺根山一带成矿构造环境,提供矿产资源勘查、预测、评价的地质背景依据,跨贺根山和锡林浩特板块缝合带一线布设了26个超宽频带长周期大地电磁测深点,点距3～6 km,剖面长度100 km,在对获取的资料采用Robust变换、互参考处理的基础上,定性分析了视电阻率和相位曲线、二维偏离度、电性主轴,并采用二维共...     

STUDY ON THE ELECTRICAL STRUCTURE OF THE ANQIU AND JUXIAN ELECTROMAGNETIC STATIONS IN THE TANLU FAULT ZONE

The Yishu fault zone is one of the branch faults of the Tanlu fault zone in its central part. Moderate and strong earthquakes occurred in the Yishu fault zone repeatedly. Due to its complex structure, the Yishu fault zone attracts much attention from earthquake researches. The Anqiu and Juxian electromagnetic stations in Shandong Province locate near the Anqiu-Juxian Fault and Changyi-Dadian Fault, which are branches of the Yishu fault zone, respectively. Geoelectric field and geomagnetic field observation were carried out in these two stations. The Wudi electromagnetic station is in the west of Tanlu fault zone in the Jidong-Bohai block and 230km from Anqiu electromagnetic station. This paper firstly describes the crustal structure near the electromagnetic stations by using magnetotelluric(MT)method. By processing the data carefully, we obtain the MT data in good quality near the stations. The MT data of each electromagnetic station and its nearby area suggests that the electrical structure and geological structure of the station are comparable. This paper applied 1-D and 2-D inversion for MT data and obtained the crustal electrical structure model beneath the Anqiu and Juxian seismic station. The shallow electrical structure from the MT method was compared with the results of symmetrical quadrupole electrical sounding. The model suggests that the electrical structure beneath the Anqiu and Juxian electromagnetic stations is complex and shows the feature of block boundary. The Wudi electromagnetic station is located inside a basin, the crustal structure shows layered feature typical for the stable blocks. Beneath the Anqiu electromagnetic station, there is a 1km-thick relative low resistivity layer in the shallow crust and a high resistivity body beneath it with a depth of 13km. There is a high resistivity structure in the crust beneath the Juxian electromagnetic station. The crustal structures are divided into two different parts by Anqiu-Juxian Fault and Changyi-Dadian Fault, respectively. More conductive layers appear to the west of the two faults. Plenty of fluid possibly exists within the conductive body to the west of Changyi-Dadian Fault, which plays important role in the earthquake generation. There is a relative low resistivity layer in the crust within 1~2km beneath the Wudi electromagnetic station. Beneath the relatively low resistivity layer, a relatively high resistivity layer extends to a depth of around 15km, and the resistivity value decreases with the increase of depth. The electrical resistivity model suggests the seismic activity of the Yishu fault zone around the Anqiu and Juxian electromagnetic stations should be taken into account seriously, and monitoring and research on it need to be strengthened. The results of this paper provide a certain reference value for the crustal structure research to similar stations.     

大地电磁资料精细处理和二维反演解释技术研究(七)——云南盈江——龙陵地震区深部电性结构及孕震环境

本文对一条布设在滇西盈江—龙陵地区的大地电磁剖面(苏典—中山剖面)数据进行了精细处理和二维反演解释,得到了测区较高置信度的二维电性结构.该电性模型纵向上表现为高阻-低阻-高阻的"三明治"式岩石圈电性结构,上地壳为平均厚度约为10km的高阻地层,在约6～16km地壳深度范围发育有电阻率为几欧姆米的显著高导层,下地壳底部和上地幔顶部表现为电性较为均匀的相对高阻层.横向上自西向东划分出以大盈江断裂带、龙陵—瑞丽断裂带为限的3个主要构造区域.壳内分布的高导层沿剖面表现出一定的横向不均匀性,其在龙陵—瑞丽断裂带下方消失,在该处形成了腾冲地块和保山地块的电性构造边界.电性结构表明,大盈江断裂附近高导层顶界面浅,两侧高阻体厚度小,因此难以形成较大规模的相互作用,致其附近浅震源、小震级的地震活跃;龙陵—瑞丽断裂两侧的高阻体较厚,易积累较大的应力,具有大震的深部孕震环境,故其附近发生过多次7级以上强震.     

ELECTRICAL STRUCTURE OF THE 2017 MS7.0 JIUZHAIGOU EARTHQUAKE REGION AND THE EASTERN TERMINUS OF THE EAST KUNLUN FAULT

The East Kunlun Fault is a giant fault in northern Tibetan, extending eastward and a boundary between the Songpan-Ganzi block and the West Qinling orogenic zone. The East Kunlun Fault branches out into a horsetail structure which is formed by several branch faults. The 2017 Jiuzhaigou M_S7.0 earthquake occurred in the horsetail structure of the East Kunlun Fault and caused huge casualties. As one of several major faults that regulate the expansion of the Tibetan plateau, the complexity of the deep extension geometry of the East Kunlun Fault has also attracted a large number of geophysical exploration studies in this area, but only a few are across the Jiuzhaigou earthquake region. Changes in pressure or slip caused by the fluid can cause changes in fault activity. The presence of fluid can cause the conductivity of the rock mass inside the fault zone to increase significantly. MT method is the most sensitive geophysical method to reflect the conductivity of the rock mass. Thus MT is often used to study the segmented structure of active fault zones. In recent years MT exploration has been carried out in several earthquake regions and the results suggest that the location of main shock and aftershocks are controlled by the resistivity structure. In order to study the deep extension characteristics of the East Kunlun Fault and the distribution of the medium properties within the fault zone, we carried out a MT exploration study across the Tazang section of the East Kunlun Fault in 2016. The profile in this study crosses the Jiuzhaigou earthquake region. Other two MT profiles that cross the Maqu section of East Kunlun Fault performed by previous researches are also collected. Phase tensor decomposition is used in this paper to analyze the dimensionality and the change in resistivity with depth. The structure of Songpan-Ganzi block is simple from deep to shallow. The structure of West Qinlin orogenic zone is complex in the east and simple in the west. The structure near the East Kunlun Fault is complex. We use 3D inversion to image the three MT profiles and obtained 3D electrical structure along three profiles. The root-mean-square misfit of inversions is 2.60 and 2.70. Our results reveal that in the tightened northwest part of the horsetail structure, the East Kunlun Fault, the Bailongjiang Fault, and the Guanggaishan-Dieshan Fault are electrical boundaries that dip to the southwest. The three faults combine in the mid-lower crust to form a "flower structure" that expands from south to north. In the southeastward spreading part of the horsetail structure, the north section of the Huya Fault is an electrical boundary that extends deep. The Tazang Fault has obvious smaller scale than the Huya Fault. The Minjiang Fault is an electrical boundary in the upper crust. The Huya Fault and the Tazang Fault form a one-side flower structure. The Bailongjiang and the Guanggaishan-Dieshan Fault form a "flower structure" that expands from south to north too. The two "flower structures" combine in the high conductivity layer of mid-lower crust. In Songpan-Ganzi block, there is a three-layer structure where the second layer is a high conductivity layer. In the West Qinling orogenic zone, there is a similar structure with the Songpan-Ganzi block, but the high conductivity layer in the West Qinling orogenic zone is shallower than the high conductivity layer in the Songpan-Ganzi block. The hypocenter of 2017 M_S7.0 Jiuzhaigou earthquake is between the high and low resistivity bodies at the shallow northeastern boundary of the high conductivity layer. The low resistivity body is prone to move and deform. The high resistivity body blocked the movement of low resistivity body. Such a structure and the movement mode cause the uplift near the East Kunlun Fault. The electrical structure and rheological structure of Jiuzhaigou earthquake region suggest that the focal depth of the earthquake is less than 11km. The Huya Fault extends deeper than the Tazang Fault. The seismogenic fault of the 2017 Jiuzhaigou earthquake is the Huya Fault. The high conductivity layer is deep in the southwest and shallow in the northeast, which indicates that the northeast movement of Tibetan plateau is the cause of the 2017 Jiuzhaigou earthquake.     

河北石家庄地区深部结构大地电磁探测

石家庄位于太行山隆起带和华北平原冀中坳陷盆地接触区,西邻太行山山前断裂带,1966年在其东南曾发生邢台7.2级强震.为研究该区的深部构造背景,并为分析地震活动性趋势提供基础资料,2010年10月采用宽频带大地电磁法对该区的深部结构进行探测研究.大地电磁剖面穿过石家庄南侧区域,长约167km,获得了64个测点数据.采用远...     

MAGNETOTELLURIC IMAGING OF MAGMA DISTRIBUTION BENEATH MA'ANLING AND LEIHULING VOLCANOES OF NORTHEASTERN HAINAN,CHINA

The northeastern Hainan Province is one of the areas subjected to the strongest, most frequent and longest-lasting volcanic activities in China since the Cenozoic era. Under the influence of magma and fault activities, northeastern Hainan Island has experienced many moderate and strong earthquakes in history. The Qiongshan M7.5 earthquake occurred in this region in 1605. The deformation measurement and InSAR data found a subsidence area in the south of the Qiongshan M7.5 earthquake. Small earthquakes frequently occur in this area. It has been inferred by some studies on this subsidence area, namely the Puqianwan-Fengjiawan seismic belt, that the subsidence and frequent seismic activity are related to the development of deep magma systems. Magnetotelluric methods are very sensitive to subsurface fluid, different temperature conditions, and resistivity property of the medium in the molten state. With the development of magnetotelluric three-dimensional inversion technique, using dense array magnetotelluric data in three-dimensional inversion can image the medium resistivity occurrence state and position in the volcanic area. To study the deep structure of the magma system and its relationship with seismic activity, we conducted MT observations on two profiles that cross Leihuling and Ma'anling volcanoes. Phase tensor decomposition was used to analyze the electrical structure. This paper investigates the two MT profiles using three-dimensional electromagnetic imaging technology and obtains the electrical structure of the two profiles. The result reveals the media properties and high conductivity bodies' occurrence range beneath the volcanic area in the northeastern Hainan. There are obvious differences in the electrical structure of the northeastern Hainan. The resistivity values are high in the east and low in the west. In addition, there are two high conductivity bodies in the northeast of Hainan. The high conductivity body C₁ inclines to the west and locates beneath the Chengmai County area in the northwestern Hainan Island(west of the Leihuling-Ma'anling volcanoes). Its resistivity value is less than several Ωm. This low resistive body is 40km long in WE direction and 30km wide in SN direction. Its burial depth is about 2km near the HNL1 profile and 6km near the NHNL1 profile. Its bottom reaches the depth of about 25~30km, which may be close to or through the Moho surface depth of 25~26km in this area. It is speculated that the magma eruption of Leihuling-Ma'anling volcanoes did not migrate vertically from its deep part to the surface. The high conductivity body C₂ locates beneath Longquan. The buried depth of C₂ tends to be shallower from north to south, but there is no exposed surface in the study area, nor is it connected with the shallow low-resistivity layer. It is speculated that the C₂ may be a magmatic sac trapped in the crust, but may have nothing to do with the eruption of Ma'anling-Leihuling volcanoes. The recent volcanic magma in this area comes from the lower crust and upper mantle of the ocean area to the west of Hainan Island. As magma enters the upper and middle crust, it continues to move shallowly and eastward. In this process, it should be blocked by the high resistance structure on the east side of the Changliu-Xiangou Fault and then erupt around this fault, thus forming numerous craters in this area. After the repeated eruption, deep magma channels gradually closed and volcanic activity weakened. The magma in the mid-upper crust cooled consolidated gradually, but the speed was uneven in different areas, resulting in the channels having closed down gradually in some places, and some are in the process of closing. Our results show an uneven rise and fall depth of the low resistivity body in the middle and lower crust. There is no high conductivity body in the deep part of the Puqianwan-Fengjiawan seismic belt and the subsidence area in the northeastern Hainan, which rules out the possibility that the small earthquakes are related to deep magma systems.     

唐山地震区地壳结构和构造:深地震反射剖面结果

1976年7月28日,在唐山地区发生了7.8级大地震.为了研究该区的地壳结构和断裂的深浅构造关系,2009年,我们在唐山市南部的丰南地区,跨唐山断裂带完成了1条道间距40m、炮间距200m、50次覆盖的深地震反射探测剖面.结果表明:研究区的地壳厚度为32 ～ 34km,莫霍面自东向西逐渐加深,在丰南县和宣庄镇之间,中-...