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ELECTRICAL STRUCTURE OF THE 2017 MS7.0 JIUZHAIGOU EARTHQUAKE REGION AND THE EASTERN TERMINUS OF THE EAST KUNLUN FAULT 
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下载免费PDF全文 SUN Xiang-yu ZHAN Yan ZHAO Ling-qiang CHEN Xiao-bin LI Chen-xia SUN Jian-bao HAN Jing CUI Teng-fa 《地震地质》1979,42(1):182-197
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 MS7.0 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 MS7.0 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. 相似文献
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在龙门山断裂带中段于2008年5月12日发生了汶川MS 8.0地震,5a之后于2013年4月20日在其西南侧即龙门山断裂带SW段发生了芦山MS 7.0地震。而在汶川地震前,沿龙门山断裂带主体部分存在7a间未发生4.0级以上地震的相对平静期。因此,汶川地震后人们研究了龙门山断裂带的地壳结构及其与汶川地震的成因关系,仅仅相隔5a时间,就在龙门山断裂带的SW段发生了芦山地震,其深部结构和孕震环境以及与汶川地震的关系又成为人们关注的热点科学问题。为了研究龙门山断裂带西南端附近的地壳结构,布置了一条穿越龙门山断裂带西南端附近的大地电磁探测剖面LS6,该剖面位于芦山地震破裂带的西南端。通过采用先进技术对大地电磁数据的分析和二维反演,发现LS6剖面与其东北侧的穿过芦山地震区汶川地震后完成的LMS4剖面的地壳电性结构既有相似性,但也存在明显的差别,其电性结构更复杂。研究表明,尽管2008年发生了汶川地震,但是龙门山断裂带受到的西北侧松潘-甘孜地块向SE的运动和对龙门山断裂带的推挤作用,以及东南侧四川盆地的阻挡作用仍然存在,同时龙门山断裂带西南端及其附近地区的地壳结构更复杂,而且还受到其西南侧川滇地块和鲜水河断裂等变形作用的影响,因此推测芦山地震与汶川地震既是相互独立的2次地震,但也有一定关联。 相似文献
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在主流的线性最优化大地电磁二维反演中,如何合理构建初始模型是一个亟待解决的问题.常用的是采用均匀半空间或一维反演结果构建初始模型,不易获得稳定可靠的反演效果.实践表明,尽管基于不同初始模型的大地电磁二维反演结果差别较大,但均较初始模型更为接近真实模型.基于这样一种认识,经过反复的理论和实践探索,我们提出构建大地电磁二维反演初始模型的印模法.印模法的基本思想是依据已有反演结果和均匀半空间模型之间的加权来确定下一步二维反演的初始模型,它一方面保留了已有反演结果中关于真实模型的宏观轮廓信息,另一方面,保证了深部电性结构的均匀性,从而满足大地电磁二维正演所要求的底边界条件.基于印模法,本文进一步提出了迭代重构的反演思想.通过多个理论模型和实测数据的反演计算,验证了上述方法可在很大程度上压制初始模型对反演结果的影响. 相似文献
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郯庐断裂带是中国大陆东部一个重要的左行走滑断裂系,对于研究中国大陆的形成演化与构造格局有着十分重要的意义.阿拉善左旗—山东日照超宽频带大地电磁测深剖面在山东莒县附近穿越了郯庐断裂带中段,电性主轴分析结果表明断裂带附近构造走向大致为北东20°;反演电阻率模型表明剖面穿越处郯庐断裂带的宽度约为30 km,断裂带主体是两条切割深度大、陡倾的断裂,西侧断裂切割深度约为60 km,向西倾斜,断面陡立,倾角约为70°,东侧断裂切割深度大于80 km,但小于100 km,界面东倾,陡立,倾角约为60°~80°;这两条断裂都切穿了地壳,但未切穿岩石圈.郯庐断裂带东缘至剖面终端日照,整个地壳为高阻,与断裂带西侧地壳的电性结构差异明显,这表明郯庐断裂带是华北地块与胶辽朝地块的边界断裂. 相似文献
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大地电磁测深二维反演方法求解复杂电性结构问题的适应性研究 总被引:3,自引:1,他引:2
为探讨二维反演方法在三维电性结构中的适应性问题,本研究中设计了一系列的二维/三维正演模型进行实验计算,分析了三维高阻/低阻异常体对模型响应的畸变作用,并从反演模式选择和数据旋转方向两个方面进行模型二维反演的对比分析,与三维反演的结果进行了比较,最后采用了实测数据进一步进行了二维和三维反演的比较实验.实验和研究结果表明,在剖面选择方面,在剖面方向与垂直主构造方向相差不大的情况下,截取剖面方向,将电性主轴旋转到垂直剖面方向的二维反演结果与垂直主构造方向的反演结果都可以较好地还原正演模型,在大的构造的反映上并无太大差异.在地下为二维或近三维条件时,正演模型的主要结构都可以较好地被二维和三维反演解析出来.二维的反演结果可能甚至会比三维的反演结果的边界更清晰,更精确.然而,对于具有较强的三维结构的模型而言,其二维反演结果与原始模型可能仍然存在较大差异,其中TM+TP或TM模式的二维反演结果相对更接近原始模型,而TE模式的结果往往会有较大误差,需要在解释时特别注意以免得出错误结论. 相似文献
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WENG Ai-hua LI Jian-ping FAN Xiao-ping LI Si-rui HAN Jiang-tao LI Da-jun LI Ya-bin ZHAO Xiang-yang TANG Yu 《地震地质》2018,40(2):396-409
In order to understand the mechanism of the 1668 MS8.5 earthquake occurred in Tancheng, it is important to probe the fine deep geological structure beneath the epicenter. A MT profile 20km south of the epicenter has been deployed. There are 17 sites along the profile, with a 3km average separation. Signals in Ex, Ey, Hx and Hy were measured in a cross manner, with x-axis orientated to the north. Record length for each site was at least 20h. The impedance and phase at sites in high cultural noisy environment were estimated by remote reference technique. As the Tanlu Fault Zone(TLFZ)is in NNE, nearly northerly, thus YX mode was considered as TM mode. Gauss-Newton inversion was done in 2-D mode with only the TM impedance and phase as input data. The electrical sections of 10km and 40km depth were respectively obtained after 8 iterations. The both initial models were created by Bostic approximation. The sections reveal the following features.
The TLFZ consists of five faults, from east to west numbered as F0 to F4. F1 is the primary fault, steeply dipping west down to mantle, which has turned into a buried one overthrust by the east dipping Fault F0. F2 and F3 dip east at 45 degrees, parallel to F4, truncated by F1 at depth. F4 dips east in the shallow subsurface and gradually dips to west toward depth through the entire crust merging with F1 to form a bigger one. These four faults constitute a flower-shaped structure, showing the nature of strike-slip of the TLFZ, associated with normal faulting in the late Yanshanian to early Himalayan. F1 dips west, overthrust by east-dipping F0, implying the compression from the westward subduction of the Pacific plate, thus present-day compression is superposed on the early tensile and strike-slip feature.
Based on MT data, it is inferred that the 1668 Tancheng M8.5 earthquake occurred at the junction of F1 and F3 about 15km deep. Thus it was likely resulted from westward compression of the Pacific plate, leading to thrust of the Sulu uplift along F0, inducing activity of F1 at depth, reactivated F3, and adjusting the stress distribution in the region. 相似文献
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Deep structure of the northeastern margin of the Parnaiba Basin, Brazil, from magnetotelluric imaging 总被引:1,自引:0,他引:1
The magnetotelluric (MT) method has been applied to the determination of the deep resistivity structure of the northeastern margin of the Parnaiba Basin. Transient electromagnetic (TEM) and MT data were collected in early 1999 along a 95 km long N–S line, extending from the coast across the projected subcrop position of a discontinuous fault found to the west of the study area that is believed to be a possible basin‐bounding fault. The MT data were processed to yield the TE‐ and TM‐mode responses and then corrected for static shift using central‐loop and single‐loop TEM data, respectively. Regularized 2D MT inversion was subsequently undertaken using a structured initial model with the near‐surface constrained by TEM inversion results. As a consistency check, we performed another set of 2D inversions using different smooth initial models. The various optimal 2D inversion models show clearly the presence of a major basement trough, over 2 km deep, located about 70 km from the coast. We interpret it as possibly marking the main basin margin and suggest that it may have implications for groundwater resource development in the area. 相似文献
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稀疏测线大地电磁资料三维反演研究:合成算例(英文) 总被引:2,自引:1,他引:1
受勘探成本和工区环境等因素的影响,当前大多数大地电磁实际工作采取布置稀疏测线采集数据和使用二维反演方法解释这些稀疏测线数据的方式。然而,二维反演方法在解释三维地电构造数据时存在局限性,有时甚至做出错误的地质解释。本文尝试了使用三维反演方法对大地电磁稀疏测线数据进行反演解释。使用大地电磁全信息资料三维共轭梯度反演程序对理论模型合成稀疏测线数据进行了三维反演。结果表明:这种反演方案是可行与有效的。同时,我们发现在不同数据的三维反演结果中,四个张量阻抗元素和两个倾子数据同时反演的结果相对更为准确,更接近理论模型。 相似文献
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Yan-Ling Shi Zu-Zhi Hu Wen-Hui Huang Qiang Wei Sheng Zhang Cui-Xian Meng Lian-Sheng Ji 《应用地球物理》2016,13(3):469-479
The coal-bearing strata of the deep Upper Paleozoic in the GS Sag have high hydrocarbon potential. Because of the absence of seismic data, we use electromagnetic (MT) and gravity data jointly to delineate the distribution of deep targets based on well logging and geological data. First, a preliminary geological model is established by using three-dimensional (3D) MT inversion results. Second, using the formation density and gravity anomalies, the preliminary geological model is modified by interactive inversion of the gravity data. Then, we conduct MT-constrained inversion based on the modified model to obtain an optimal geological model until the deviations at all stations are minimized. Finally, the geological model and a seismic profile in the middle of the sag is analysed. We determine that the deep reflections of the seismic profile correspond to the Upper Paleozoic that reaches thickness up to 800 m. The processing of field data suggests that the joint MT–gravity modeling and constrained inversion can reduce the multiple solutions for single geophysical data and thus improve the recognition of deep formations. The MT-constrained inversion is consistent with the geological features in the seismic section. This suggests that the joint MT and gravity modeling and constrained inversion can be used to delineate deep targets in similar basins. 相似文献
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Through simultaneous inversion of earthquake hypocenters and velocity structure, we obtained the precise locations of earthquakes occurring from 1981 to 2013 in northern Shanxi and the 3D velocity structure, and analyzed emphatically the Kouquan Fault. The result of earthquake relocation shows that earthquakes are concentrated in the central-north segment of Kouquan Fault and the distribution is sparse towards both south and north end of the fault, which indicates that the strong activity is in the central-north segment of Kouquan Fault and the seismicity becomes weaker towards both ends. The result of velocity structure shows that the earthquake concentrated segment of Kouquan Fault is on the side of relative low-velocity area in the high-velocity body, and the south segment of Kouquan Fault is the continuous low velocity. We can recognize the velocity gradient zone from the obvious depression near the Kouquan Fault, which, as we preliminarily speculate, may be the evidence of the presence of Kouquan Fault(or basement detachment)at the deep part. The parallel velocity profile (velocity ratio profile) to Kouquan Fault shows that the earthquake cluster in the central-north segment of Kouquan Fault is located in the abrupt change zone from high to low velocity(from high to low velocity ratio). 相似文献
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Since the true Earth is 3-D in nature, a three-dimensional (3-D) inversion has clear advantages over lower dimensional inversions. We utilized a 3-D magnetotelluric (MT) inversion code, WSINV3DMT, to obtain a realistic resistivity model using a long period MT data set collected in the Northwest Sabalan geothermal field in Ardabil, Iran. The apparent resistivity and phase curves, the magnetic induction vectors, the impedance polar diagrams and the rotational invariant of impedance tensor, indicate a complex 3-D conductivity structure. After setting up the model parameters and designing the appropriate block discretization, we performed the 3-D inversions for two sets of observed data; one set includes the full MT impedance tensor and another set contains only off-diagonal elements of the MT impedance. The final model was selected according to the relative magnitude of the data misfit and the model norm with respect to various Lagrangian multipliers. The results of this study illustrate the 3-D inversion of the off-diagonal elements of MT impedance tensor is precisely enough to explain the structures related to the geothermal source. The obtained results were compared with the results of available 2-D models and they are then interpreted using all of the geological and drilling data of the area. The main outcome of this study is the precise delineation of the geometry of geothermal source that is located at the center of the study area with a surface coverage of about 7 km2. 相似文献
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《Journal of Applied Geophysics》2006,58(3):218-231
This study deals with two-dimensional (2D) inversions of synthetic and observed radiomagnetotelluric (RMT) data on typical buried conductive waste sites in Europe, and with the practical aspects of different inversion algorithms. In the inversion calculations, we used smoothing and L2-norm stabilizers and compared the results. The resolution of the geometry of the highly conductive waste site, in particular, was investigated. In the inversion with the L2-norm stabilizer, we used the least-squares solution with singular value decomposition (LSSVD) and conjugate gradient (CG), whereas only the conjugate gradient solver was used in the 2D-inversion with the smoothing stabilizer. The inversion results of the synthetic data showed a better resolution of the geometry of the highly conductive waste site when a L2-norm stabilizer was applied in the inversion; in particular, a better detection of the bottom of the waste deposit was achieved. Additional model studies were carried out using synthetic RMT data in order to investigate the 2D inversion of RMT data observed on a 3D structure; these studies showed that the use of TM mode data yields a better resolution of the structure than joint inversion of TE and TM modes.2D inversions of RMT data on a waste site near Cologne showed that the inversion of the TM mode could resolve well the geometry, especially the bottom of the waste site, if information about the background conductivity structure was available. In this case study, inversion with the L2-norm stabilizer produced a sharper image of the waste site than inversion with the smoothing stabilizer, as indicated also by the inversion study that used synthetic data. 相似文献
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THE DIFFERENCE OF DEPOSITION RATE IN THE BOREHOLES AT THE JUNCTION BETWEEN NANKOU-SUNHE FAULT AND HUANGZHUANG-GAOLIYING FAULT AND ITS RESPONSE TO FAULT ACTIVITY IN THE BEIJING AREA 下载免费PDF全文
下载免费PDF全文 ZHANG Lei BAI Ling-yan ZHAO Yong ZHANG Xiao-liang YANG Tian-shui CAI Xiang-min HE Fu-bing 《地震地质》2017,39(5):1048-1065
Beijing plain area has been always characterized by the tectonic subsidence movement since the Pliocene. Influenced and affected by the extensional tectonic environment, tensional normal faulting occurred on the buried NE-trending faults in this area, forming the "two uplifts and one sag" tectonic pattern. Since Quaternary, the Neocathaysian stress field caused the NW-directed tensional shear faulting, and two groups of active faults are developed. The NE-trending active faults include three major faults, namely, from west to east, the Huangzhuang-Gaoliying Fault, Shunyi Fault and Xiadian Fault. The NW-trending active faults include the Nankou-Sunke Fault, which strikes in the direction of NW320°~330°, with a total length of about 50km in the Beijing area. The northwestern segment of the fault dips SW, forming a NW-directed collapse zone, which controls the NW-directed Machikou Quaternary depression. The thickness of the Quaternary is more than 600 meters; the southeastern segment of the fault dips NE, with a small vertical throw between the two walls of the fault. Huangzhuang-Gaoliying Fault is a discontinuous buried active fault, a boundary line between the Beijing sag and Xishan tectonic uplift. In the Beijing area, it has a total length of 110km, striking NE, dipping SE, with a dip angle of about 50~80 degrees. It is a normal fault, with the maximum fault throw of more than 1 000m since the Tertiary. The fault was formed in the last phase of Yanshan movement and controls the Cretaceous, Paleogene, Neogene and Quaternary sediments.There are four holes drilled at the junction between Nankou-Sunhe Fault and Huangzhuang-Gaoliying Fault in Beijing area. The geographic coordinates of ZK17 is 40°5'51"N, 116°25'40"E, the hole depth is 416.6 meters. The geographic coordinates of ZK18 is 40°5'16"N, 116°25'32"E, the hole depth is 247.6 meters. The geographic coordinates of ZK19 is 40°5'32"N, 116°26'51"E, the hole depth is 500.9 meters. The geographic coordinates of ZK20 is 40°4'27"N, 116°26'30"E, the hole depth is 308.2 meters. The total number of paleomagnetism samples is 687, and 460 of them are selected for thermal demagnetization. Based on the magnetostratigraphic study and analysis on the characteristics of sedimentary rock assemblage and shallow dating data, Quaternary stratigraphic framework of drilling profiles is established. As the sedimentation rate of strata has a good response to the activity of the basin-controlling fault, we discussed the activity of target fault during the Quaternary by studying variations of deposition rate. The results show that the fault block in the junction between the Nankou-Sunhe Fault and the Huangzhuang-Gaoliying Fault is characteristic of obvious differential subsidence. The average deposition rate difference of fault-controlled stratum reflects the control of the neotectonic movement on the sediment distribution of different tectonic units. The activity of Nankou-Sunhe Fault shows the strong-weak alternating pattern from the early Pleistocene to Holocene. In the early Pleistocene the activity intensity of Huangzhuang-Gaoliying Fault is stronger than Nankou-Sunhe Fault. After the early Pleistocene the activity intensity of Nankou-Sunhe Fault is stronger than Huangzhuang-Gaoliying Fault. The activity of the two faults tends to consistent till the Holocene. 相似文献
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本文对位于青藏高原东缘川滇构造区的贡山一绥江大地电磁测深(MT)剖面数据进行反演,获得沿剖面的深部电性结构,为研究喜马拉雅东构造结、川滇菱形地块与华南地块的构造变形特征、壳幔耦合关系、地块间接触关系以及相互作用等问题,提供电性结构的依据.研究发现:(1)电性结构揭示澜沧江断裂带和小金河断裂带为深大断裂带,控制着研究区的深部结构特征和形变机制;(2)澜沧江断裂带和金沙江断裂带之间的高阻体,可能是扬子古地块的残留部分;小金河断裂带和安宁河断裂带之间的高阻体,则是峨眉山大火山省喷发形成的冕宁一越西杂岩带;(3)在滇西地块、川滇地块和大凉山地块均存在低阻层,它们的介质属性有所不同,滇西地块下的低阻层"疑似"高热状态的岩浆囊,主要由缅甸弧向东俯冲运动引起的,中上地壳的高热状态使地块的活动性增强;川滇地块内部的壳内低阻层的成因为:理塘断裂带和小金河断裂带之间的地表低阻层由破碎带充水所致,而金沙江断裂带和理塘断裂带之间的中地壳低阻层可能是由局部熔融物质或含盐流体导致的,其为壳内物质运移的通道.从而在地下物质发生大规模走滑运动的过程中起到引导作用;川滇地块东部和大凉山地块西部的壳内低阻层可能与地慢物质的上涌有关;马边断裂带附近的低阻体可能与破碎带变宽和破碎带内的流体有关. 相似文献
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藏北高原主要断裂带电性结构特征 总被引:8,自引:4,他引:4
对600线的部分测点及2100线的全部测点构成的五道梁-绿草山大地电磁深探测剖面进行了二维非线性共轭梯度反演,得到青藏高原中北部二维电性结构模型.根据该电性结构模型,结合研究区域重、磁及区域地质资料推断了青藏高原中北部主要断裂的位置、产状和切割深度等信息.研究结果表明,青藏高原中北部发育有F1-F16一系列深断裂.其中,F1(苟鲁山克错-囊谦断裂带)和F9(乌兰乌拉湖-玉树断裂带)共同构成金沙江缝合带的北界,是松潘-甘孜-可可西里地块与羌塘-唐古拉地块的分界线;F4、F10-F12共同构成昆仑断裂带,F4(阿尼玛卿断裂带)是南部松潘-甘孜-可可西里地体和北部北昆仑-柴达木地体的分界线;F6、F13-F16为柴北缘断裂带,由南倾的岩石圈深断裂F6和一系列产状相背、北倾的逆冲断裂F13-F16所构成;F7和F8可能反映岩石圈内产状平缓、隐伏的滑脱构造形迹. 相似文献
19.
Yanling Shi Zhanxiang He Zuzhi Hu Qiang Wei Dechun Li Cuixian Meng Liansheng Ji Sheng Zhang 《Studia Geophysica et Geodaetica》2018,62(1):167-185
Mapping deep geological hydrocarbon targets is of significant importance in basin exploration. In areas lacking reliable seismic data, magnetotelluric (MT) and gravity explorations are helpful to delineate the distribution of potential deep geological hydrocarbon targets. Here we investigate the effectiveness of the integrated 3D MT and gravity explorations for mapping the potential deep hydrocarbon source rocks. The result based on the data from the W Basin (part of the Ordes Basin) of China demonstrates that the method is efficient and economical for basin exploration. The method is particularly useful in target areas which are of great interest for oil and gas exploration but lack high quality seismic data. In our method, we first use the high-precision 3D small-bin MT data acquisition to improve the data accuracy. Then we perform datum static correction method and apply 3D inversion to obtain the3D resistivity distribution. We also develop a layered resistivity model based on resistivity logging to assist the interpretation of the inverted 3D resistivity data so as to derive an initial 3D geological model. Starting from the initial model, we use 2D gravity data to update the model via 2D inversion line by line, and then pass the updated model for the next round of the 3D MT inversion. The integrated inversion is implemented iteratively so the model converges to satisfy the need of final geological analysis. The application to the W Basin shows that we could successfully delineate the geological distribution of the potential deep hydrocarbon source rocks within the basin and map the thickness of the upper Paleozoic. 相似文献
20.
栟茶河断裂自20世纪50年代石油部门勘探发现以来,由于缺乏确凿的证据,地学家们对其活动性一直存在争议。目标断裂所在测区基岩顶面埋深约在800~1 600m,单一的地震勘探方法难以深浅兼顾且单波勘探经常存在局限性。为了调查栟茶河断裂的空间位置、产状及性质,重新厘定其活动性,在同一条测线上同时进行高分辨率的浅层地震P波和SH波勘探,通过采用不同的地震波激发震源和观测系统参数,获得沿测线不同埋藏深度的地下细结构图像,揭示栟茶河断裂的形态和特征,尤其SH波地震剖面更加清晰地反映出超浅层地层和构造空间特征。结果表明,测线控制范围内的栟茶河断裂为近东西走向、视倾角约为60~75°、倾向N的正断层,该断层错断了新近纪和早第四纪地层,有可能断错了晚更新世地层。本文的纵、横波联合勘探实例证实了多波勘探的优越性。 相似文献