松潘-阿坝地区深部电性特征

针对青藏高原东部特殊的“三角形”区域——松潘-阿坝地区,通过两条测线的MT资料分析和反演,对其深部电性特征进行了揭示,发现松潘-阿坝区中深层构造较为稳定,层状特点明显,地下电性横向变化小,具有稳定地块的特点.这里存在壳内低阻层,厚度近10~20km;深部(岩石圈地幔内部)的电性结构也有两种类型:高阻异常区和具有幔内低阻层的次高阻异常区,全区岩石圈厚度在120km左右,其四周由深断裂与邻区接触.该区深部电性特征不同于龙门山隆起的电性结构,也不同于西秦岭构造带,后者具有高阻基底,岩石圈厚度或更薄或加厚.     

宁南弧形构造带甘肃靖远-宁夏盐池剖面中上地壳电性结构特征

对垂直于宁南弧形构造带的一条大地电磁测深剖面数据的处理和反演解释,揭示了沿剖面的中祁连隆褶带、靖远-西吉坳陷、西华山-六盘山隆褶带、兴仁堡-海原坳陷、中卫-同心断陷、卫宁北山-罗山坳陷、鄂尔多斯西缘隆褶带及天环坳陷30 km深度的电性结构特征及相互关系; 推断出祁连山碰撞造山带存在自南西向北东的逆冲,鄂尔多斯西缘隆褶带从东向西依次叠置形成逆冲叠瓦式断裂构造格局。电性分布特征表明：宁南弧形构造带内壳内低阻层主要在北祁连碰撞造山带及兴仁堡-海原坳陷内呈不连续分布,祁连山造山带内的壳内高导层往北终止于兴仁堡-海原坳陷内;兴仁堡-海原坳陷内的壳内高导层往北东终止于鄂尔多斯西缘逆冲褶皱带,与鄂尔多斯西缘逆冲推覆体下的晚古生代、早中生代滑脱面相交汇,沿剖面方向宁南弧形构造带内的壳内低阻层总体表现为西南深北东浅的特征。     

藏北羌塘盆地西部查桑地区结构及构造特征

通过对近年新获得的航磁、重力、大地电磁测深和地质等资料的综合研究揭示,羌塘西部隆起查桑段具有明显的南北分带、东西分块和垂向分层的结构、构造特征。该区总体由两(东部)、三(西部)个东西向展布的大型南倾构造块体推覆叠置而成,其间又被数条近南北向断裂分割为若干个断块。各块带出露地层时代、结构构造和地球物理场特征有较大差别。在查桑段及邻区,地壳中上部有两个低阻层,所在的深度分别为15±5km和约40km之下。壳内上部低阻层主要分布在查桑段及其以南,为各块体总体向北运动和逆掩叠覆之底部主拆离推覆面,该区各南倾大断裂均向下收敛并交会到该层。下部低阻层的展布超出了查桑段,向北已达北羌塘坳陷,其影响的范围可能更为广阔。此南北分带、多块叠置的结构和复杂多变的地球物理场特征,仅孤零零地出现在双湖—绒马之间,不具区域意义。其形成与该区东、西两侧中生代始存在的近南北向转换断层和晚古生代可能曾发育有裂谷之背景密切相关。该区段挤压变形和叠覆隆升,始于早白垩世羌塘盆地反转期;始新世以来,印度板块碰撞遂继续向北推挤,又得到进一步的发展、加强及改造。     

深反射地震成像揭示的班公湖 怒江缝合带中段Moho断阶及其大地构造意义

揭示班公湖- 怒江(班怒)缝合带Moho(莫霍面)结构对于认识中特提斯洋壳俯冲和南羌塘坳陷成因具有重要地球动力学意义。基于横跨班怒缝合带的深反射地震数据(88°30′E),本文采用了中长波长静校正、噪声压制、优化叠加和叠前深度偏移(PSDM)等地震处理技术,获得了深度域地震反射偏移剖面、层速度场和高分辨率Moho结构。由深度域剖面显示,班怒缝合带Moho位于地表以下65～80 km,呈不连续北向抬升趋势,指示在拉萨地块与南羌塘地块之间存在岩石圈上地幔断阶,最大阶步可达15 km。综合分析缝合带两侧的Moho形态认为,这些断阶受南侧拉萨地体的岩石圈上地幔以19. 5°北倾俯冲与北侧南羌塘地块的上地壳抬升驱动,可能与深部存在局部熔融相关。班怒缝合带下的Moho结构表明,随着晚侏罗世—早白垩世中特提斯洋闭合,南羌塘地体由边缘海沉积向前陆盆地转换,形成南羌塘坳陷。     

太康隆起东段地热资源远景区调查评价与研究

应用大地电磁测深法(MT)对太康隆起东段深部地层结构及隐伏断裂进行探测研究,共布设了4条MT剖面,获得了97个测深点,并对所获得的MT数据的二维偏离度、构造走向等进行计算和分析,采用非线性共轭梯度(NLCG)二维反演方法对TE和TM模式的数据进行联合反演,得到了可靠的地下介质二维地电模型。研究结果表明,商丘凸起电性结构纵向上具有典型的分层特征,从上到下可分为三层,即低阻层-中高阻层-高阻层。根据该电性结构模型,结合研究区域重力、航磁、地震及区域地质资料,绘制了商丘凸起基岩地质图,同时根据深部基底隆起形成的高阻异常与区域地温场高值区具有较好的对应关系,据此圈定了2处地热异常远景区。     

青藏高原西缘壳幔电性结构与断裂构造: 札达-泉水湖剖面大地电磁探测提供的依据

青藏高原西缘札达至泉水湖剖面大地电磁探测结果表明, 研究区被雅江缝合带、班公-怒江缝合带划分为3个构造区域, 由南至北分别为喜玛拉雅地体、冈底斯地体和羌塘地体.研究区内普遍存在中下地壳高导层, 高导层的顶面埋深起伏较大, 冈底斯内的高导层埋深大, 羌塘和喜玛拉雅地体内的高导层埋深较浅.在班公-怒江缝合带南侧高导层埋深最大, 班公-怒江缝合带南北两侧高导层埋深存在一个约20km的错动.冈底斯地体内的地壳高导层呈北倾形态, 南羌塘的地壳具有双高导层.沿剖面的上地壳存在多组规模不等、产状不同的电性梯度带或畸变带, 反映了沿剖面地区的缝合带与断裂带分布情况.根据电性结构特征, 推断了雅江缝合带、班公-怒江缝合带以及龙木措、噶尔藏布等主要断裂的构造特征与空间分布.      

大地电磁测深法在冀中坳陷深部碳酸盐岩热储调查评价中的应用

地热资源作为一种清洁能源,在“双碳”背景下,其开发和利用越来越受到重视。为了探查渤海湾盆地的冀中坳陷深部碳酸盐岩的热储条件,笔者等利用3条大地电磁测深剖面,进行了数据处理、分析和反演,获得可靠的二维电阻率模型和电阻率等深度平面图。分析研究区深部电性结构特征及主要断裂构造特征,同时根据基底隆起形成的高阻异常对深部碳酸盐岩分布和埋深进行了推断,并对冀中坳陷深部碳酸盐岩热储进行评价,以圈定地热异常远景区。分析认为：① 研究区电性结构可以被划分为5层,其中第5电性层为高阻标志层,对应深部碳酸盐岩基底;② 据此圈定了3类深部地热远景区：基岩埋深小于4000 m,如高阳低凸起地热远景区、黑龙口低凸起地热远景区（徐水凹陷）和河间潜山地热远景区（饶阳凹陷）,基岩埋深4000~5000 m,如雁翎潜山地热远景区（霸县凹陷）,基岩埋深5000~5500 m,如肃宁潜山地热远景区和留路潜山地热远景区;③ 大地电磁测深方法适用于冀中坳陷深部碳酸盐岩热储远景区的探查。深部热储远景区的圈定,可为后期的地热资源评价和开发利用建立基础。     

兴蒙、吉黑地区岩石圈电性结构特征

采用具有国际先进水平的二维连续自动反演技术对收集的MT资料进行了二维反演和综合解释。得到了不同地区MT剖面的二维电性结构断面。通过二维反演断面发现了松辽盆地的东西边界较陡,而南部边界较缓的电性结构;发现在火山地区12～30km深度普遍存在低阻物体,为解释火山地区深部存在岩浆囊提供了依据。另外,于桦南—饶河重新实施的MT剖面,其二维反演断面也较清楚地揭示出:剖面西段为高阻特征且具有稳定的岩石圈厚度(80～90km),该区段对应佳木斯地块;剖面中部具有明显的电性梯度带,该梯度带为确定佳木斯地块的东界位置及其深部结构形态提供了依据;剖面东段则揭示了佳木斯地块以东地区浅部为逆冲推覆体,深部为多个高阻块体与低阻条带相间的电性结构。     

青藏高原北部巴颜喀拉构造带基底隆起的地震学证据

过去曾笼统地认为巴颜喀拉构造带上万米的堆积主要是三叠系的复理石沉积。通过对沱沱河-格尔木深地震剖面资料的再认识发现，巴颜喀拉构造带的结晶基底埋深仅5km左右，比金沙江断裂带以南的羌塘地块北缘和昆仑山南缘的基底埋藏深度都要浅。进一步对青藏公路以东横穿巴颜喀拉构造带的几条深地震测深剖面进行分析，发现该基底隆起一直顺构造走向延伸，向东贯穿了整个构造带，推测它是扬子古陆块的残余。     

羌塘盆地高精度航空重磁调查对盆地基底性质与构造格局的启示

羌塘盆地是我国陆域面积最大的中生代海相沉积盆地,该盆地基底属性和深部构造特征尚未形成统一认识.最新获取的高精度航空重、磁资料发现北羌塘整体表现为"磁力高、重力低",南羌塘与之相反,并且北羌塘基底磁性明显强于南羌塘;基于航磁数据计算的基底深度显示出南、北羌塘具有明显差异,北羌塘基底深度普遍在7.0～15.0 km,凹陷中心多达6个;南羌塘基底深度稍浅,多在5.0～13.0 km,凹陷中心只有3个.南、北羌塘截然不同的重磁场特征表明羌塘盆地并不存在统一的前寒武系变质基底,南、北羌塘是两个完全不同的构造单元.E—W向的"中央隆起带"将羌塘盆地一分为二,使其整体呈现"两坳夹一隆"的构造格局,并可以进一步划分为31个凸起区和9个凹陷区.     

Research achievements of the Qinghai-Tibet Plateau based on 60 years of aeromagnetic surveys

The Qinghai-Tibet Plateau (also referred to as the Plateau) has long received much attention from the community of geoscience due to its unique geographical location and rich mineral resources. This paper reviews the aeromagnetic surveys in the Plateau in the past 60 years and summarizes relevant research achievements, which mainly include the followings. (1) The boundaries between the Plateau and its surrounding regions have been clarified. In detail, its western boundary is restricted by West Kunlun-Altyn Tagh arc-shaped magnetic anomaly zone forming due to the arc-shaped connection of the Altyn Tagh and Kangxiwa faults and its eastern boundary consists of the boundaries among different magnetic fields along the Longnan (Wudu)-Kangding Fault. Meanwhile, the fault on the northern margin of the Northern Qilian Mountains serves as its northern boundary. (2) The Plateau is mainly composed of four orogens that were stitched together, namely East Kunlun-Qilian, Hoh-Xil-Songpan, Chamdo-Southwestern Sanjiang (Nujiang, Lancang, and Jinsha rivers in southeastern China), and Gangdese-Himalaya orogens. (3) The basement of the Plateau is dominated by weakly magnetic Proterozoic metamorphic rocks and lacks strongly magnetic Archean crystalline basement of stable continents such as the Tarim and Sichuan blocks. Therefore, it exhibits the characteristics of unstable orogenic basement. (4) The Yarlung-Zangbo suture zone forming due to continent-continent collisions since the Cenozoic shows double aeromagnetic anomaly zones. Therefore, it can be inferred that the Yarlung-Zangbo suture zone formed from the Indian Plate subducting towards and colliding with the Eurasian Plate twice. (5) A huge negative aeromagnetic anomaly in nearly SN trending has been discovered in the middle part of the Plateau, indicating a giant deep thermal-tectonic zone. (6) A dual-layer magnetic structure has been revealed in the Plateau. It consists of shallow magnetic anomaly zones in nearly EW and NW trending and deep magnetic anomaly zones in nearly SN trending. They overlap vertically and cross horizontally, showing the flyover-type geological structure of the Plateau. (7) A group of NW-trending faults occur in eastern Tibet, which is intersected rather than connected by the nearly EW trending that develop in middle-west Tibet. (8) As for the central uplift zone that occurs through the Qiangtang Basin, its metamorphic basement tends to gradually descend from west to east, showing the form of steps. The Qiangtang Basin is divided into the northern and southern part by the central uplift zone in it. The basement in the Qiangtang Basin is deep in the north and west and shallow in the south and west. The basement in the northern Qiangtang Basin is deep and relatively stable and thus is more favorable for the generation and preservation of oil and gas. Up to now, 19 favorable tectonic regions of oil and gas have been determined in the Qiangtang Basin. (9) A total of 21 prospecting areas of mineral resources have been delineated and thousands of ore-bearing (or mineralization) anomalies have been discovered. Additionally, the formation and uplift mechanism of the Plateau are briefly discussed in this paper.©2021 China Geology Editorial Office.     

Structure of the Northwestern Boundary of the Middle Amur Sedimentary Basin (Russian Far East) from Audiomagnetotelluric Sounding Data

This paper reports the data on the structure of the northwestern boundary of the Middle Amur sedimentary basin which were obtained after resumption of audiomagnetotelluric soundings. The geoelectric sections for two profiles across the basin strike are constructed, the sedimentary cover and basement structures are studied, and their electrical properties are determined. The compared data of the earlier and present studies show low-resistivity zones of 50–150 Ohm m beneath high-resistivity rocks of 500–1000 Ohm m in the northwestern part of the Ul’dura–Churki uplift at a 2–4 km depth, which are absent in the southwestern part of the uplift. This fact is related to strike-slip–overthrust processes due to graben formation in the area of junction with the Jiamusi–Bureya Massif in the Kur fault zone (YYilan–Yitong branch of the Tan-Lu fault zone) and also to global left-lateral strike-slip displacements and volcanic activity.     

Geoelectrical Structure of the Crust and Upper Mantle in the Qinling and Adjacent Regions

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ANISOTROPIC FEATURE OF QIANGTANG MASSIF TEXTURE

ANISOTROPIC FEATURE OF QIANGTANG MASSIF TEXTURE     

大陆岩石圈解耦及块体运动讨论——以青藏高原—川滇地区为例

块体构造理论的发展不断地深化着人们对现今大陆岩石圈运动 ,尤其是大陆强震的孕育和发生规律的认识。块体底部边界的构造性质是块体运动的核心问题之一 ,同时也是块体构造理论研究中的薄弱环节。确定块体底部边界的岩石物理性质是利用地球物理方法探测和识别块体底部边界的前提。文中依据现代实验岩石学、实验岩石物理学、地球物理学、地质学等的研究成果 ,对块体底部边界之成因属性和岩石物理性质进行了分析。将大陆块体划分为两种基本类型———地壳型块体和岩石圈型块体。地壳型块体是由大陆上部地壳所构成的“薄板” ,壳内软弱带的顶面为其底部边界和潜在的解耦带。岩石圈型块体在岩石圈尺度上是力学耦合的 ,以上地幔软流圈的顶面为其底部边界。壳内软弱带具有垂直方向低速和各向异性的基本特征 ,联合多种地震测深方法有望确定块体的底界。在现今构造活动区内 ,地壳型块体的潜在解耦带可能由壳内部分熔融带承担。青藏高原南部—川滇地区 2 0 35km的深度上广泛存在低速带。地热、岩石学、实验岩石学和模拟均显示该地区的低速带具有部分熔融的成因属性。块体沿着该壳内低速层与下伏地壳发生某种程度解耦。     

The Deep Structure Feature of the Sichuan Basin and Adjacent Orogens

The basin-mountain system in the Sichuan Basin(SCB) reflects the main tectonic activity and the orogenic denudation in this region. The seismic probing work reveals the deep structure of the basin-mountain system. The seismic work was re-sampled to the Moho depth and the sedimentary thickness as well as the P-wave velocity-depth function to analyze the deep structure of the SCB and adjacent orogens. The results show two deposit centers in the SCB: the Deyang area in the west and the Nanchuan area in the east and depression uplift exists in the southwestern part of the SCB; the Moho shallowers gradually from the west to east(ca. 62-36 km deep),the South-North seismic belt(SNSB) is very distinctive: the Moho depth is much shallower( 50 km)to the east of the SNSB, whereas it is much deeper(50 km)to the west of the SNSB, suggesting that the SNSB rather than the Longmen Shan tectonic belt is a main Moho transition belt; the topography and the top interface of the basement have the same undulation trend when the sedimentary thickness and the Moho depth have a mirror relationship; the low velocity zone developed in the Kangdian thrust and fold belt and Songpan-Garzê belt implied a soft, weak and thick crust there showing tectonic activity in these areas.     

准噶尔盆地基底构造

我们已完成了穿越准噶尔盆地及其周边地区的I-I、II-II、III-III、IV-IV和额敏—哈密剖面5条综合地球物理剖面。通过综合研究,初步了解准噶尔盆地及邻近地区的地球动力学问题:准噶尔盆地基底由北部的乌伦古地体和南部的玛纳斯地体组成。两者的分界为西西北方向的滴水泉—三个泉缝合线。其西部与北东向Dalbutte缝合带相连,东部与北西向的Cranamary缝合带相连。准噶尔盆地北部的乌伦古地体基底为双层构造,上层为泥盆系和下石炭统组成的褶皱基底,大致表现为北厚(3~5 km)、南薄(1~2 km)。缝合线以南的玛纳斯地体为单层基底,即新元古代结晶基底。准噶尔盆地地壳厚度为44~52 km,北薄南厚。周边山区地壳厚度高于盆地地区。盆地及邻近地区地壳分为上、中、下层,并且中地壳一般较薄。盆地地区的地壳存在多条深断裂。南北方向发育了6条主要深断裂,分别为红车、德伦山、石溪、呼图壁、彩南和阜康。这些断层倾角较大,向上延伸至上地壳下部,向下切入地壳基底界面。壳内水平构造和构造面无明显垂向断层,似有“开放断层”特征。这些断层是上地幔物质挤入地壳的良好通道。此外,该地区还有两条主要的横向深断层。一是北西西走向的滴水泉—三个泉深断裂,它向南倾斜,具有逆断层性质,可能会破坏滴水泉—三个泉缝合带。另一条是近东西向的昌吉—玛纳斯深断裂,向南倾斜,主要发育在中下地壳,具有逆断层性质。这些深断裂对盆地构造发育具有一定的控制作用。准噶尔盆地西部的莫霍面基本连续地延伸到了天山的莫霍面,并且后者的莫霍面深度明显大于前者。但是,盆地东部的莫霍面与博格达山脉的莫霍面并不连续。前者以叠加关系延伸到后者之下,表明盆地东部的地壳向博格达山脉俯冲。这有助于解释天山东部构造活动相对减弱而博格达山脉向北推高的构造地貌现象。周边准噶尔盆地具有挤压盆地-山地构造耦合格局,尤其是南部边界东部博格达—准东盆地的山地-盆地构造耦合。现在将准噶尔盆地与吐哈盆地分开的博格达山脉是年轻的、仍在上升的山脉。博格达山的隆升是印支运动以来多次推覆造山运动的反映,其现貌是新近纪以来新构造运动的结果。准噶尔盆地盖层发育经历了3个阶段:与天山和松潘—甘孜造山带形成有关的二叠纪—三叠纪前陆盆地阶段,区域压缩较弱的侏罗纪—早始新世陆内坳陷阶段,以及新近纪晚期以来与天山抬升有关的活化前陆盆地阶段。     

Structural Characteristics of the Basement beneath Qiangtang Basin in Qinghai-Tibet Plateau: Results of Interaction Interpretation from Seismic Reflection/Refraction Data

The studies on configuration, character/property of the basement of Qiangtang basin is helpful for evaluating petroleum and nature gas resources as well as understanding the basin evolvement. Recently a moderate to high-grade metamorphic gneiss rock was found underlying beneath very low metamorphic Ordovician strata in Mayer Kangri to the north of the central uplift. That fact actually proved existence of the crystalline basement just the distribution and structures of pre-Paleozoic crystalline basement still remain puzzle. In recent years a number of active sources deep seismic profiling, to aim at lithospheric structure of northern Tibet and petroleum resources of the Qiangtang basin, had been conducted that make it possible to image the structure of the basement of the Qiangtang. Near vertical reflection profiles, included those acquired previously and those during 2004 to 2008, have been utilized in this study. By through the interaction process and interpretation between the reflection profiles and the wide-angle profile, a model with the detailed structure and velocity distribution from surface to the depth of 20 km of Qiangtang basin has been imaged.Based on the results and discussions of this study, the preliminary conclusions are as follows: (1) The velocity structure section (~20 km) that is interactively constrained by the refraction and reflection seismic data reveals that the sedimentary stratum gently lie until 10 km in the south Qiangtang basin. (2) The basement consists of fold basement (the upper) and crystalline basement (the lower).The fold basement buried at the average depth of 6 km with a velocity of 5.2–5.8 km/s. The shallowest appear at range of the central uplift. The crystalline basement is underlying beneath the fold basement at the average depth of 10 km with a velocity of 5.9–6.0 km/s except near Bangong-Nujiang suture. (3) The high-velocity body at the depth range of 3–6 km of the central uplift is considered as a fragment of the crystalline basement that perhaps was raised by Thermal or deformation. (4) The lower-consolidated fold basement show more affinity of Yangtze block but the crystalline basement seems more approximate to Lhasa terrene in geophysical nature. We have attempted to improve the resolution and reliability by interaction of the active seismic data and prove it effective to image complex basement structure. It will be a potential to process the piggy-back acquisition data and has wide prospects.     

Seismic profiles across the middle Tan-Lu fault zone in Laizhou Bay,Bohai Sea,eastern China

The stratigraphic architecture, structure and Cenozoic tectonic evolution of the Tan-Lu fault zone in Laizhou Bay, eastern China, are analyzed based on interpretations of 31 new 2D seismic lines across Laizhou Bay. Cenozoic strata in the study area are divided into two layers separated by a prominent and widespread unconformity. The upper sedimentary layer is made up of Neogene and Quaternary fluvial and marine sediments, while the lower layer consists of Paleogene lacustrine and fluvial facies. In terms of tectonics, the sediments beneath the unconformity can be divided into four main structural units: the west depression, central uplift, east depression and Ludong uplift. The two branches of the middle Tan-Lu fault zone differ in their geometry and offset: the east branch fault is a steeply dipping S-shaped strike-slip fault that cuts acoustic basement at depths greater than 8 km, whereas the west branch fault is a relatively shallow normal fault. The Tan-Lu fault zone is the key fault in the study area, having controlled its Cenozoic evolution. Based on balanced cross-sections constructed along transverse seismic line 99.8 and longitudinal seismic line 699.0, the Cenozoic evolution of the middle Tan-Lu fault zone is divided into three stages: Paleocene–Eocene transtension, Oligocene–Early Miocene transpression and Middle Miocene to present-day stable subsidence. The reasons for the contrasting tectonic features of the two branch faults and the timing of the change from transtension to transpression are discussed.