震积构造特征

震积岩是地质历史中地震事件的岩石学记录,具有特征的震积构造.识别震积岩,对于研究地震历史、区域构造发展史和进行盆地分析、地层对比等,都具有重要意义.本文以作者等所发现的峨眉震积岩为基础,描述了震积岩和震积构造的特征,总结了震积构造与滑塌构造、冰缘构造、沙丘塌落和流沙构造、巷曲层理等易混淆构造的区别。

湖南慈利溪口震旦系陡山沱组震积岩的发现及其地质意义

湘西慈利溪口地区震旦系陡山沱组地层中首次发现碳酸盐岩原地震积岩。笔者通过剖面实测,详细观察和描述,结合构造背景,识别出阶梯状层内断层、液化碳酸盐岩脉、液化角砾岩、负荷构造以及微褶纹理等典型的震积软沉积变形构造的地质记录;震积序列在剖面结构上显示自下而上由下伏未震动层—阶梯状层内断层—微褶皱层—液化碳酸盐岩层—液化角砾岩层—上覆未震动层的渐变过程及震积作用逐渐衰减的趋势。震积岩发育的层位在时空上显示良好的可对比性,反映陡山沱期晚期构造活动强烈,并具备多旋回、多周期的特点。构造的活跃加速了有机碳库的氧化,为该时期多细胞生物的繁盛和大规模的成磷成矿作用奠定了基础;同时保存完好的震积地层记录对推断研究区的古沉积环境也具有重要意义。

松辽盆地青山口组震积岩特征及油气地质意义

通过大量岩芯观察,结合构造背景研究,在松辽盆地白垩系青山口组中识别出震积岩。将震积岩变形构造划分为固结地层震积变形构造和未固结地层震积变形构造两大类。研究区所见固结地层震积变形构造主要有裂缝、微型断层、龟裂式地层破碎及内碎屑角砾岩等,未固结地层震积变形构造主要有液化砂岩脉、石香肠构造、同沉积塑性变形构造、环状层理、震积枕状及伴生构造等。总结震积岩的沉积特征并讨论了其油气地质意义:由地震活动引发三角洲前缘砂体垮塌沉积而成的滑塌浊积岩、高能波浪带形成的滨浅湖滩坝砂体都为良好的储集层;震裂缝附近发育溶孔和微裂缝。溶孔的发育程度无疑对改善储层的储集性能起到建设性作用;已固结地层中发生地震的断裂系统为油气运移提供通道;强烈的地震活动会造成固结的致密泥岩盖层的破裂,大量裂缝会导致油气的快速散失。

贵州雷山一带的震积岩

贵州雷山一带的震积岩见于清水江组中、上部,发育液化变形层理、微断层、微褶皱、震裂岩、震塌岩及砂枕构造等。根据野外实际观察,分别建立了变余沉凝灰岩、凝灰质板岩和变余凝灰质砂岩中完整的地震扰动序列。

高邮凹陷富民油田戴南组震积岩特征

高邮凹陷富民油田戴南组沉积时期,受到中-新生代构造运动的影响,古地震活动强烈,在岩心的观察过程中发现了很多震积岩构造,例如液化砂岩脉、阶梯状小断层、震皱岩等。通过对其单井垂向特征的观察和研究,总结前人的研究成果,得出了研究区的震积岩垂向序列,并得出古地震作用下的碎屑流沉积普遍发育在震积构造的顶部的结论。

准噶尔盆地南缘上侏罗统-下白垩统沉积序列及沉积环境演化

准噶尔盆地南缘上侏罗统-下白垩统的沉积相,可以分为曲流河相、冲积扇相、湖水改造冲积扇相和滨浅湖亚相。根据构型要素分析法,划分出10种主要典型岩石相。其中Gm1为褐红色块状砾岩,复成分,粒度为细-粗砾,分选、磨圆差,主要为杂基支撑;Gm2为褐色块状砾岩,复成分,粒度为细-中砾,分选和磨圆一般-差,主要为颗粒支撑;Gm3为灰绿色、橘红色块状细砾岩,分选、磨圆较好,颗粒支撑。Gm1和Gm2沉积期,多处发育震积构造。中-晚侏罗世,气候干旱,北天山构造活动,盆地快速充填,可容纳空间减小,上侏罗统齐古组主要发育曲流河沉积。受蒙古-鄂霍次克洋快速闭合的影响,张性环境演变为局部挤压环境,北天山继续构造活动,盆地收缩,可容纳空间减小,盆地边界由早—中侏罗世的中天山退至北天山,上侏罗统喀拉扎组沉积期,准噶尔盆地南缘广泛发育褐红色冲积扇沉积,侏罗纪盆地充填结束;在下白垩统清水河组沉积期,蒙古-鄂霍次克洋闭合完成,构造相对稳定,盆地扩张,可容纳空间增大,大范围快速湖侵,气候转为湿润,准噶尔盆地南缘发育湖水改造冲积扇沉积,之后广泛发育滨浅湖沉积,发育灰绿色、橘红色滨湖砾岩及细粒沉积,白垩纪盆地充填开始。

济南南部山区的古地震事件岩石学识别

通过野外调查、室内鉴定和对比研究,从济南南部下寒武统李官组和朱砂洞组中识别出了一系列由古地震引起的同沉积变形构造,并在一定程度上分析了其形成机理。在朱砂洞组中发育多种震积岩构造,包括卷曲变形、微断层、不协调岩块、震裂隙、震碎角砾及震裂缝充填构造等,李官组中发育震滑塌构造。它们是早寒武世沧浪铺期至龙王庙期的地震事件记录,与大连大林子组及洛南朱砂洞组中的地震记录的地质时代一致。

榆社群高庄组中震积泄水构造及成因模式

位于华北克拉通中部、沁水含煤构造盆地核心部位的榆社盆地,是一个上新世至早更新世河湖相沉积的内陆小型盆地,浊漳河的侵蚀导致大量新生界剖面出露地表.野外地质调查发现,榆社群高庄组中发育大量泄水构造,包括砂泥岩脉、砂岩脉、泥岩脉、粘土质团块、片状钙质胶结岩脉、结核等,且相互间渐变过渡.基于饱和松散岩土体,在大于一定强度的外动力扰动下,沿岩层软弱结构面发生逃逸,形成泄水构造.基于泄水构造在本区大范围发育的调查结果以及现代地震诱发砂土液化的研究成果类比可知,地质历史时期的高庄组沉积物（地震发生时高庄组沉积物处于饱和松散状态、中值粒径变化范围在0.055 ～0.159mm区间、级配良好且富含CaCO3,FeO和MnO等矿物质）,是在遭受地震震级Ms=5～6的动力扰动下,沿岩层弱面泄水灌入形成了上述泄水构造.地表揭露的各种震积构造关联证据与地震导致饱和松散岩土体液化射流的水动力以及粘粒、砂粒、矿物质等物源供应量变化的形成条件相匹配,构建了表征其成因的“地震液化射流分异模型”.地震液化射流形成不同形态的泄水构造,可作为相变剧烈小型盆地地层识别与对比的良好标志.

柴达木盆地西南区震积作用及其研究意义

研究表明,柴达木盆地西南地区地震活动强烈,深、浅层均发现一系列与古地震有关的震积岩,形成一系列软沉积物变形构造,主要包括震积砂枕、砂球构造、枕状层、液化砂泥岩脉、层内错断、地裂缝、微褶皱纹理、沙侵蘑菇等。研究区震积岩的岩石类型则主要包括震褶岩、震裂岩、震塌岩、自碎屑角砾岩、自碎屑副角砾岩、液化角砾岩及震浊积岩等。地震活动使岩层产生大量的微裂缝,裂缝沟通了原有的孔隙,同时增加了储集层的储集空间,极大地改善了储集层的渗透性,并使原先不具渗透性的砂泥薄互层产生裂缝,成为输导层,这为在地震断裂系统附近寻找低渗透岩层中的高渗储层提供了新的方向。而地震断裂系统上倾的三角洲前缘水下分流河道、河口坝砂岩以及滨浅湖滩坝所构成的岩性圈闭必将成为柴西南地区岩性油气藏勘探的新领域。

A Preliminary Analysis of Relations Between Tectonic Deformation of Sedimentary Cover and Basement in Kuqa Depression

Study of seismic activity in the Kuqa area enables us to infer some possible active faults in basement from the epicentral distribution on different profiles. The relations between active faults in the basement and surface structures are analyzed and the difference between sedimentary cover and basement in their deformation characteristics and the genesis are discussed. The following conclusions have been drawn: (1) the epicentral distribution indicates that, the east Qiulitag and south and north Qiulitag deep faults in the basement correspond to the east and west Qiulitag anticlines, respectively. Moreover, deep faults also exist beneath the Yiqiklik and Yaken anticlines. It indicates that the formation of surface structures is controlled by deep structures; (2) A NE-trending strike-slip fault develops along the line from the western termination of Yiqiklik structure to Dongqiu Well 5 and a NW-trending active fault on the western side of Baicheng. The two active faults across the tectonic strike are the main causes for tectonic segmentation of the Kuqa depression and possibly the cause for the middle segment (Kuqa-Baicheng) of the depression to be more shortened than both its eastern and western terminations; (3) The difference between the sedimentary cover and basement in their deformation characteristics depends mainly on the different properties of media between them. The lithospheric strength of the basement in the basin is fairly high, which determines the basement deformation to be mainly of brittle fracture——seismic activity. While the strength of sedimentary cover is low, where there exist weak thin layers, such as coal and gyps. Under the effect of strong tectonic compression, the sedimentary rocks may undergo strong viscous or plastic flow deformation; meanwhile, an aseismic detachment may take place along the weak layers.

Seismites in the Dasheng Group： New evidence of strong tectonic and earthquake activities of the Tanlu Fault Zone

More than 80 layers of seismites were recognized from the Early Cretaceous Dasheng Group in the Mazhan and Tancheng graben basins in the Tanlu Fault Zone, eastern China. The responsible seismic events took place about 110–100 Ma in the Early Cretaceous. The fault zone was affected at the time by strong tectonics, due to tension-related stretching and scattered squeezing by strike-slip faults. These tectonic activities induced a series of strong earthquakes with Richter magnitudes(M) of 5–8.5. The earthquakes affected saturated or semi-consolidated flood and lake sediments, and produced intra-layer deformations by several processes, including liquefaction, thixotropy, drop, faulting, cracking, filling and folding, which resulted in the formation of various soft-sediment deformation structures, such as dikes and veins of liquefied sand, liquefied breccias, liquefied homogeneous layers, load structures, flame structures, ball-and-pillow structures, boudinage, diapirs, fissure infillings, a giant conglomerate wedge, and syn-sedimentary faults. The seismites are new evidence of tectonic and seismic activities in the Tanlu Fault Zone during the Early Cretaceous; the series of strong seismic events that can be deduced from them must be considered as a response to the destruction of the North China Craton.