塔里木盆地塔中北坡走滑断裂特征与奥陶系油气勘探

通过二维、三维地震资料解释与构造解析,明确了塔里木盆地塔中北坡发育多条北东向、北东东向走滑断裂带,在平面和剖面上识别出了6种走滑断裂活动的标志。研究表明,塔中北坡走滑断裂在剖面上呈直立断层、花状构造,北东向走滑断裂下部表现为明显挤压隆升,而上部则表现为继承性张扭负花状构造,具有"下拱上掉"的特征,表明了断裂的多期走滑活动。总体上可划分为中奥陶世末—志留纪压扭走滑断层、晚泥盆世—早石炭世张扭走滑断层和晚二叠世末逆冲断层三期,它们在空间上相互叠置。研究认为走滑断裂的变形强度控制了奥陶系裂缝及缝洞型储层发育范围,走滑断裂的分段性对优质缝洞型储层发育具有较强的控制作用。提出了在变形强度大的裂缝发育区、走滑断裂拉张部位的断洼区,以及受后期张扭走滑断裂叠加改造的断槽部位的串珠状地震反射异常体发育区,是下步寻找天然气规模储量的有利勘探方向。     

辽东湾北部地区走滑构造特征与油气富集规律

辽东湾北部地区右行走滑构造特征较为典型,主要表现为:沿走滑断裂带发育雁行式伸展断裂;剖面上发育花状构造;走滑断裂沿走向呈“S”型或反“S”型波状弯曲;沿走滑断裂带断槽与断鼻构造相间分布。分析认为,渐新世晚期,辽东湾北部地区南北向拉张、东西向挤压的区域应力场控制了右行走滑构造的形成,断槽与断鼻构造相间分布是由于沿走滑断裂带局部应力场性质发生改变所致。右行走滑断裂的“S”型弯曲部位为增压弯部位,走滑断裂两侧断块在此汇聚,地层因应力集中而形成断鼻构造;右行走滑断裂的反“S”型弯曲部位为释拉张部位,走滑断裂两侧断块在此离散,地层因拉张而发生断陷形成断槽。受走滑构造所控制,油气沿走滑断层自断槽向断鼻方向运移、聚集而成藏。研究走滑构造发育特征,对于预测圈闭分布以和研究油气富集规律具有重要意义。     

塔里木盆地富满大型碳酸盐岩油气聚集区走滑断裂控储模式

塔里木盆地台盆区深层海相油气勘探目标由层间岩溶向断控岩溶转变,并在处于坳陷区的富满地区发现了以走滑断裂为主控因素的断控型油田。富满地区储层特征与盆地内古隆起区、斜坡区均有不同,因此需要建立适合研究区的走滑断裂控储模式。本次研究通过高密度三维地震资料刻画了研究区走滑断裂的分布,利用岩心、测井、试井资料以及缝洞体识别技术明确了不同类型的储层分布,分析了研究区走滑断裂样式与差异变形对储层发育的影响,建立了走滑断裂控储模式。研究结果表明:(1)富满大型碳酸盐岩油气聚集区储集空间主要由多期走滑构造破裂作用与岩溶作用形成的洞穴型、裂缝-孔洞型、裂缝型与孔洞型空间组成;(2)走滑断裂活动性越强,断裂带宽度越大,储层发育规模越大,张扭段与压扭段断层破碎带型储层较平移段平面分布范围更广,纵向发育深度更大;(3)张扭段为汇水区,断裂联通性好,有利于大气流体下渗以及热流体上涌从而对储层进行溶蚀改造;压扭段为分流区,岩溶储层多发育于断裂带两侧,断裂开启程度低,受流体改造程度低于张扭段。     

四川盆地东部走滑断裂识别与特征分析及形成演化：以涪陵地区为例

近年来的国内外油气勘探实践表明含油气盆地内的基底走滑断裂带为一种新的高产油气富集带,油气勘探开发前景广阔。对基底走滑断裂的识别、几何学和运动学特征分析及“控储、控藏”作用方面的研究越来越引起高度关注。本文利用四川盆地东部涪陵地区的高精度三维地震剖面的断裂构造精细解析、相干体属性和水平时间切片分析、野外露头断裂特征观测等多种资料,基于走滑构造理论,在研究区新发现了规模较大的北西向和北东向基底走滑断裂带的分布,并建立了川东地区走滑断裂在剖面上直立断层和花状构造、平面上线性延伸和地质界线错开、空间上的“丝带效应”和“海豚效应”及主干断裂产状和力学性质“明显分段性”的识别标准。并提出了基于走滑断裂垂直位移量变化和两侧构造活动强度差异性对比分析厘定走滑方向的新方法;依据地震水平时间切片地层界线错开、走滑断裂两侧厚度差异估算走滑距离的方法,实际应用结果表明,NW向基底走滑断裂带现今整体呈现左行走滑特征,但不同时期走滑性质多变,自形成期以来至少经历了5次左行滑动与3次右行滑动,总体表现出“深部左行,浅部右行,北部活动强度大,南部活动强度小”的特点,左行走滑距累积可达到1 400～3 400 m。北东...     

塔中西部走滑断裂破碎带结构及与油气关系

塔中Ⅰ号气田西部是塔中油气上产的重要领域,利用最新处理的叠前深度偏移资料,在断裂控储控藏认识指导下,开展走滑断裂解剖,落实富油气区域。研究区断裂可划分为两期三级3组断裂,形成于加里东期的北东向走滑断裂及其伴生裂缝是本区的控储控藏断裂,沿走滑断裂走向一般为非线性结构,通常可分为应力转换区和应力释放区。应力转换区包括岩桥、拉分地堑、地垒、局部鼻状构造等;应力释放区包括羽状、斜列破碎带等。应力转换区和应力释放区是油气最富集的区域,走滑断裂破碎带规模越大,储层越发育,油气越富集。     

塔里木盆地哈拉哈塘地区走滑断裂带油气分布与油藏模式

塔里木盆地哈拉哈塘地区石油勘探开发进入深度高达8 000 m的坳陷区,油气主要沿走滑断裂带分布,研究超深层断控油气藏分布规律对油气勘探开发具有重要意义。通过大量勘探开发资料分析与油藏解剖表明,哈拉哈塘地区奥陶系碳酸盐岩油气沿主断裂带1.8 km范围内条带状分布,高效井主要分布在距主断裂带600 m范围内。油气沿断裂带分布具有分段性,断裂的类型、规模与性质影响油气运聚成藏,油气富集主要受控于主断裂带的规模。高效井一般距主断裂近、储层规模大、侧向封闭好,为断控缝洞型碳酸盐岩油藏。走滑断裂断控油气藏不同于礁滩体与风化壳“相控”油气藏,对复杂碳酸盐岩油气藏评价开发具有重要意义。     

塔里木盆地塔中隆起及北围斜区断裂体系与油气成藏关系

笔者探讨了断裂在油气聚集中的作用,它是制约塔中隆起及北围斜区油气分布规律的关键因素。基于地震资料断裂解析,塔中隆起及北围斜区断裂体系主要由北西—南东延伸的压扭性断裂带与北东—南西延伸的走滑断裂构成。断裂体系主要形成于中晚加里东中期,此后经历了晚加里东、晚海西和喜山期的继承性活动与改造。中加里东中期构造是该区构造的主要定型期,断裂不仅控制了构造带发育,也是风化壳岩溶储层、礁滩相储层、热液溶蚀碳酸盐岩储层形成关键因素。断裂带后期活动为油气运聚提供了通道,北北东断裂是油气由北部坳陷向隆起长距离运聚的主要通道。断裂带的复杂性造就了研究区油气具有沿断裂带分布,成藏模式多样,差异富集特征。     

塔中Ⅰ号气田TZ83井区环状断溶体储层发育特征及油气聚集规律

TZ83井区鹰山组缝洞型碳酸盐岩凝析气藏是塔里木盆地塔中I号气田奥陶系大型碳酸盐岩凝析气藏的重要组成部分。通过井-震标定、地震资料精细解释,利用曲率、相干和波阻抗等地震属性识别研究TZ83井区环状断溶体储层。研究表明:(1)环状断溶体储层主要发育于鹰山组一段—良里塔格组五段,为环状洞穴层;(2)加里东中期广泛发育的不整合岩溶形成了环状断溶体的雏形,加里东晚期—海西期形成的X剪切断裂控制了环状断溶体储层发育的规模;(3)油气分布主要受环状断溶体储层发育规模的控制,可划分为3个相对独立的油气藏,这3个油气藏的硫化氢含量、气油比和开发特征均表现出极大的差异性。指出TZ83井区环状断溶体是在弱走滑条件下受X剪切断裂影响而形成,储层发育具有选择性、受控性、继承性和不均匀性的特点,这与塔里木盆地其他地区受大型区域性走滑断裂控制的断溶体,在储层形成机理及油气分布等方面存在较大差异。     

张扭性盆地隐性断裂带识别、演化及控藏作用——以苏北盆地金湖凹陷为例

隐性断裂带是由区域或局部应力场或基底断裂活动影响下, 在凹陷沉积盖层中产生的断裂趋势带。重磁、三维地震资料处理解释成果证实苏北盆地金湖凹陷存在北东、北西两组基底断裂。部分北东向的基底断裂活动强烈, 控制了凹陷形成和演化; 北西向和部分北东向的基底断裂活动性较弱, 沉积盖层中形成了隐性断裂带。它们表现为成带分布的雁列式小断层、断断续续沿固定方向分布的小断层、一系列沉积扇体或油气圈闭成带成串分布等线状构造。随机测线的剖面上表现为地震同相轴没有明显错断或呈现杂乱反射。除上述两组隐性断裂带, 区域右行应力场在凹陷内部产生的东西方向的挤压应力分量也形成了断续状、串状的南北向隐性断裂带。研究表明, 隐性断裂带由"隐性"逐渐向"显性"过渡。经历了早期弱雁列式隐性期、早中期强雁列式隐性期、中期断续状隐-显期、中后期串状显-隐期4个隐性阶段, 最终演化为"显性"张扭性走滑断裂。沉积盖层中形成的这些隐性断裂带控制了储集砂体分布、改善了储层物性、使隐性圈闭成带成串分布, 是油气聚集成藏的有利区带。     

走滑断裂和裂缝发育带的地震地质综合识别——以准噶尔盆地西北缘玛南地区为例

走滑断裂及其伴生的裂缝,是准噶尔盆地西北缘玛南斜坡区三叠系百口泉组储层的重要控制因素,走滑断裂及裂缝的识别与预测对于该地区高产目标的识别有着重要意义。然而走滑断裂垂向断距小甚至无断距,断层识别和组合比较困难;与断裂伴生的裂缝发育与地震资料分辨率不在同一尺度,以地震资料识别和预测裂缝发育带的可靠性受到较多质疑。针对这些问题,采取地震地质综合识别技术,1充分运用构造导向滤波、多尺度边缘检测、方向加权相干、体曲率分析等手段,尽量精确可靠地提取构造变形引起的地震响应特征;2利用走滑断裂的Sylvester剪切模式与断层裂缝相关等地质理论进行地质约束,对地震识别和预测结果进行合理解释和推断,从而较好地解决了这一地区走滑断裂和裂缝发育带的识别与预测问题。     

发刊词

在党的鼓足干勁、力争上游、多次好省地建設社会主义总路線照耀下,全国各項建設事業都处在躍进的高潮中。在这种形势推动下,地質科学事业正以万馬奔騰之势向前發展。“向深山要宝,向地球开战”的口号正响徹祖国的原野和边疆。这种波瀾壯閥的新局面,使我們相信,經过各方面的努力,在不久的將来,埋藏在地下几亿年的矿藏要被唤醒,要听我們使唤,为我們服务。那时,地质工作將会为国家生产建設准备更充足的矿产资源,和为地区开發提供必要的数据,“地质工作落后”的帽子就要丢掉,从而赶上和超过英、美等先进资本主义国家的水平。     

Discussion of tectonic models for Cenozoic strike-slip fault-affected continental margins of mainland SE Asia

Understanding the roles of Cenozoic strike-slip faults in SE Asia observed in outcrop onshore, with their offshore continuation has produced a variety of structural models (particularly pull-apart vs. oblique extension, escape tectonics vs. slab-pull-driven extension) to explain their relationships to sedimentary basins. Key problems with interpreting the offshore significance of major strike-slip faults are: (1) reconciling conflicting palaeomagnetic data, (2) discriminating extensional, and oblique-extensional fault geometries from strike-slip geometries on 2D seismic reflection data, and (3) estimating strike-slip displacements from seismic reflection data.Focus on basic strike-slip fault geometries such as restraining vs. releasing bends, and strongly splaying geometries approach the gulfs of Thailand and Tonkin, suggest major strike-slip faults probably do not extend far offshore Splays covering areas 10,000’s km² in extent are characteristic of the southern portions of the Sagaing, Mae Ping, Three Pagodas and Ailao Shan-Red River faults, and are indicative of major faults dying out. The areas of the fault tips associated with faults of potentially 100 km+ displacement, scale appropriately with global examples of strike-slip faults on log–log displacement vs. tip area plots. The fault geometries in the Song Hong-Yinggehai Basin are inappropriate for a sinistral pull-apart geometry, and instead the southern fault strands of the Ailao Shan-Red River fault are interpreted to die out within the NW part of the Song Hong-Yinggehai Basin. Hence the fault zone does not transfer displacement onto the South China Seas spreading centre. The strike-slip faults are replaced by more extensional, oblique-extensional fault systems offshore to the south. The Sagaing Fault is also superimposed on an older Paleogene–Early Miocene oblique-extensional rift system. The Sagaing Fault geometry is complex, and one branch of the offshore fault zone transfers displacement onto the Pliocene-Recent Andaman spreading centre, and links with the West Andaman and related faults to form a very large pull-apart basin.     

塔里木盆地顺南地区走滑断裂发育特征及演化

顺南地区位于塔里木盆地塔中隆起北部.受多期构造应力影响,该地区以走滑断裂大量发育为典型特征.对三维地震资料的精细解释和深入分析结果表明,研究区走滑断裂具有垂向分层、平面分段、多期次构造叠加的特征.顺南地区主要发育北东、北东东和北西向3组走滑断裂.北东向断裂活动性强,平面上发育雁列式断层及马尾状构造,剖面上主要发育对称花状、正花状与负花状上下分层叠置的复合花状构造.北东东和北西向断裂活动性较弱,剖面上以单条直立走滑断裂为主,平面上呈线性延伸或由多段同向走滑断层连接而成.根据断层构造样式和受力性质,将顺南1断裂沿走向划分为4段：2个复合花状-拉张段和2个简单花状-挤压段,拉张段和挤压段沿走向交替出现.顺南走滑断裂的形成主要经历了5期构造运动：加里东早期、加里东中期Ⅰ幕、加里东中期Ⅲ幕、加里东晚期-海西早期和海西晚期.其中,加里东中期Ⅰ幕和加里东中期Ⅲ幕为该区主要断层活动期.     

Structural evidence for superposition of transtension on transpression in the Zagros collision zone: Main Recent Fault,Piranshahr area,NW Iran

The Main Recent Fault of the Zagros Orogen is an active major dextral strike-slip fault along the Zagros collision zone, generated by oblique continent–continent collision of the Arabian plate with Iranian micro-continent. Two different fault styles are observed along the Piranshahr fault segment of the Main Recent Fault in NW Iran. The first style is a SW-dipping oblique reverse fault with dextral strike-slip displacement and the second style consists of cross-cutting NE-dipping, oblique normal fault dipping to the NE with the same dextral strike-slip displacement. A fault propagation anticline is generated SW of the oblique reverse fault. An active pull-apart basin has been produced to the NE of the Piranshahr oblique normal fault and is associated with other sub-parallel NE-dipping normal faults cutting the reverse oblique fault. Another cross-cutting set of NE–SW trending normal faults are also exist in the pull-apart area. We conclude that the NE verging major dextral oblique reverse fault initiated as a SW verging thrust system due to dextral transpression tectonic of the Zagros collision zone and later it has been overprinted by the NE-dipping oblique normal fault producing dextral strike-slip displacement reflecting progressive change of transpression into transtension in the collision zone. The active Piranshahr pull-apart basin has been generated due to a releasing damage zone along the NW segment of the Main Recent Fault in this area at an overlap of Piranshahr oblique normal fault segment of the Main Recent Fault and the Serow fault, the continuation of the Main Recent Fault to the N.     

Analysis of the Wenchuan Ms8.0 Earthquake’s Co-seismic Stress and Displacement Change by Using the Finite Element Method

The variation of in situ stress before and after earthquakes is an issue studied by geologists. In this paper, on the basis of the fault slip dislocation model of Wenchuan Ms8.0 earthquake, the changes of co-seismic displacement and the distribution functions of stress tensor around the Longmen Shan fault zone are calculated. The results show that the co-seismic maximum surface displacement is 4.9 m in the horizontal direction and 6.5 m in the vertical direction, which is almost consistent with the on-site survey and GPS observations. The co-seismic maximum horizontal stress in the hanging wall and footwall decreased sharply as the distance from the Longmen Shan fault zone increased. However, the vertical stress and minimum horizontal stress increased in the footwall and in some areas of the hanging wall. The study of the co-seismic displacement and stress was mainly focused on the long and narrow region along the Longmen Shan fault zone, which coincides with the distribution of the earthquake aftershocks. Therefore, the co-seismic stress only affects the aftershocks, and does not affect distant faults and seismic activities. The results are almost consistent with in situ stress measurements at the two sites before and after Wenchuan Ms8.0 earthquake. Along the fault plane, the co-seismic shear stress in the dip direction is larger than that in the strike direction, which indicates that the faulting mechanism of the Longmen Shan fault zone is a dominant thrust with minor strike-slipping. The results can be used as a reference value for future studies of earthquake mechanisms.     

古新世以来郯庐断裂的位移量及其对莱州湾凹陷的控制

高分辨三维地震可视化及方差切片分析显示,郯庐断裂渤海海域莱州湾段北北东向断裂系发育。断层在水平方差切片上的拖拽现象、断裂带内部断层的组合关系以及凹陷沉积中心的迁移等,表明古新世以来该区存在右旋走滑运动。假设在东、西两支断层的走滑拉分作用下,根据可容纳空间不变原理,设计了三角形模型、长方形模型、半地堑型模型以及地堑型模型共四种模型,计算莱州湾凹陷南北长度和凹陷深度的关系,其中半地堑模型计算得到的郯庐断裂的水平位移为7km。结合断层的平面分布和断层的切割关系,表明古新世以来郯庐断裂的走滑拉分作用难以控制莱州湾凹陷的形成,走滑拉分作用只是在走滑断裂带内部形成了局部小型洼地,其规模很小,影响非常有限。     

沿阿穆尔板块西边界的活动断层(蒙古领土)

阿穆尔板块西部边界在蒙古境内的空间位置尚不清楚,并且活动断层构造及其沿线地壳的应力状态研究较少。本文在沿此边界的三个区域——杭爱—肯特构造鞍部、布尔古特地块(鄂尔浑—土拉交汇处)和色楞格地块(包括色楞格凹陷和布伦—努鲁隆起),利用空间图像解译、地形起伏度分析、地质构造资料以及构造压裂和沿裂缝位移资料重建构造古应力,对活动断层进行研究。研究表明,活动断裂继承了古生代和中生代古构造的非均质性。这些断层沿着板块边界并不是单一的带,而是成簇的。它们的运动取决于走向:亚纬向断层是具有一定逆分量的左旋走滑断层,北西向断层是逆断层或逆冲断层,通常具有右旋走滑分量,海底断层是右旋走滑断层,北东向断层是正断层。位于色楞格凹陷和杭爱东部的断裂构造的活动始于上新世。逆断层和走滑断层与上新世情况不符,但多与更新世地貌相符,表明其活动年代较晚,为更新世时期。利用构造断裂和沿断裂的位移,重建活动断裂带变形末阶段的应力应变状态,结果表明断裂在最大挤压轴的北北东和北东方向上以压缩和走滑为主。只有在色楞格凹陷内,以扩张和走滑类型的应力张量为主,且在最小挤压轴的北西走向尤为显著。在南部,杭爱东部(鄂尔浑地堑)内有1个以扩张机制为主的局部区域,说明蒙古中部断裂在更新世—全新世阶段的活动以及现代地震活动主要受与印度斯坦和欧亚大陆汇聚过程相关的东北方向的附加水平挤压的控制。使研究区地壳产生走滑变形、贝加尔湖裂谷发散活动以及阿穆尔板块东南运动的另一个因素是东南方向软流圈流动对岩石圈底部的影响。阿穆尔板块和蒙古地块之间的边界在构造结构上是零碎的,代表了覆盖整个蒙古西部变形带的边缘部分。     

Seismic faults in the Aegean area

Reliable fault plane solutions of shallow earthquakes and information on surface fault traces in combination with other seismic, geomorphological and geological information have been used to determine the orientation and other properties of the seismic faults in the Aegean and surrounding area.Thrust faults having an about NW-SE strike occur in the outer seismic zone along western Albania-westernmost part of mainland of Greece-Ionian Sea-south of Crete-south of Rhodes.The inner part of the area is dominated by strike-slip and normal faulting. Strike-slip with an about NE-SW slip direction occurs in the inner part of the Hellenic arc along the line Peloponnesus-Cyclades-Dodecanese-southwest Turkey as well as along a zone which is associated with the northern Aegean trough and the northwesternmost part of Anatolia. All other regions in the inner part of the area are characterized by normal faulting. The slip direction of the normal faults has an about SW-NE direction in Crete (N38°E) and an about E-W direction (N81°E) in a zone which trends N-S in eastern Albania and its extension to western mainland of Greece. In all other regions (central Greece-southern Yugoslavia and Bulgaria, western Turkey) the slip of the normal faults has an about N-S direction.     

GPS-measurements of recent crustal deformation in the junction zone of the rift segments in the central Baikal rift system

Based on multiyear measurements of present-day motions in the central area of the Baikal rift system, new data on the kinematics of horizontal motions, relative horizontal deformation rates, and rotation velocities in the area of junction of the South Baikal, North Baikal, and Barguzin rift basins have been obtained. This area is an intricate structure with two transfer zones: Ol’khon–Svyatoi Nos and Ust’-Barguzin.It is shown that crustal blocks are moving southeastward, normally to the structures of transfer zones and at an acute angle to the Baikal Rift strike, which corresponds to the right-lateral strike-slip extensional faulting along the major structure. The average horizontal velocities increase from 3.0 mm yr–1 in the northern South Baikal basin to 6.5 mm yr–1 in the Barguzin basin. The elongation axes prevailing in the study region are mainly of NW–SE direction. The areas of intense deformations are confined to structures with high seismic activity in the South Baikal and, partly, Barguzin basins. This confirms the existence of a present-day zone of the Earth’s crust destruction in the Baikal rift system, which is the most likely source of strong earthquakes in the future. Two zones with rotations in opposite directions are recognized in the rotation velocity field. Clockwise rotation is typical of structures of N–NE strike (Maloe More basin, southern North Baikal basin, Barguzin Ridge rise). Counterclockwise rotation is determined for NE-striking structures (northern South Baikal basin, southern Barguzin basin). In general, the obtained data show an intricate pattern of present-day horizontal dislocations and deformations in the area of junction of NE- and N–NE-striking rift structures. This suggests left- and right-lateral strike-slip faults, respectively, within them.