新疆及邻区地震构造图简介

简要介绍了新编新疆及邻区地震构造图的主要内容.本图在1:1 000 000新疆地震构造图的基础上,修改扩编而成.比例尺为1:2 500000,采用李廷栋主编的1:2 500000中国西部及邻区地质构造图为底图.编制过程中吸收了大量相关研究成果,查阅相关文献,结合遥感资料的重新判读和解译.建立了图内近300条活动断裂及1...     

阿尔泰—萨彦及邻区地震构造图简介

简要介绍了新编阿尔泰—萨彦及邻区地震构造图的主要内容.该图是在1∶2 500 000新疆及邻区地震构造图的基础上,修改扩编而成.比例尺为1∶5 000 000,采用李廷栋主编的1∶5 000 000亚欧地质图为底图.编制过程中吸收了大量相关研究成果,查阅相关文献,结合遥感资料的重新判读和解译,建立了图内50余条主要活动断裂数据库及相应的档案.图内涉及天山、阿尔泰—西蒙古—萨彦、贝加尔等地震构造带,并对这些地震构造带内的主要地震构造的基本信息作了简要介绍.     

郯庐断裂带池河段的新活动

对郯庐断裂带池河段进行了遥感影像判读，地震地质实地调查，钻孔探测资料分析，样品采集测试，以及结合地震活动特征分析和微观构造解析. 结果表明，郯庐断裂带池河段晚第四纪期间仍具有粘蠕滑交替的变形活动，最新活动方式以蠕滑活动为主.      

临汾大地震破裂形式及未来地震危险性探讨

根据几年的活动断裂填图和新发现的地震地表破裂资料，结合卫星影象判读和地震史料记载，分析和讨论了１６９５年临汾大地震的地质构造背景及发震构造部位和未来地震危险性，指出了该地震的破裂形式与分布范围。     

库车前陆褶皱带盐相关构造样式

塔里木盆地库车前陆褶皱带中段中新生代地层中发育一套下第三系盐岩层, 对该区构造变形起着重要控制作用. 根据野外地质调查、地震资料和钻井资料对盐相关构造研究表明, 库车前陆褶皱带发育盐上、盐间和盐下三套不同的构造样式. 盐上构造样式主要包括逆冲断层及断层相关褶皱、盐推覆构造、三角带构造和盐成凹陷. 盐间构造样式主要包括盐枕构造、盐间断褶构造和盐焊接构造等. 盐下构造样式主要包括叠瓦冲断带、双重构造、背冲断块或断褶构造. 研究表明, 库车前陆褶皱带盐上、盐间和盐下构造样式形态迥异, 但它们是在统一应力场作用下形成的, 在成因上有着密切联系, 其动力学机制与重力作用、挤压作用和盐岩层塑性流动作用密切相关.     

构造物理模拟实验方法的发展与应用

构造模拟实验是研究和模拟自然界地质构造现象变形特征、成因机制和动力学过程的一种物理实验方法.在查阅大量相关资料的基础上,总结出构造物理模拟实验的发展史、国内外研究现状,以及在实验理论、实验技术和实验材料等方面的研究进展.目前,构造物理模拟实验已被广泛应用于构造地质学和石油构造地质学研究领域以及石油勘探研究领域,是油气勘探研究由定性描述跨入半定量分析乃至定量分析的有效途径.在研究低级序断层组合方法、纯挤压条件下以及俯冲环境中楔体的形成及演化、铲形主拆离断层控制的伸展构造变形等方面取得了很大进展.作为研究构造变形机制的重要手段,构造物理模拟发展在压扭构造研究、盐构造的物理模拟等方面仍存在不足,研究途径的选择也是构造物理模拟实验面临的一个问题.     

基于GIS的构造裂缝综合分析技术及应用

目前虽然有许多种方法可以进行构造裂缝预测,但由于碳酸盐岩发育区裂缝发育的复杂性,需要综合研究构造裂缝定量预测的新方法.本文以哈萨克斯坦扎纳若尔碳酸盐岩凝析油田为研究和应用对象,提出了基于GIS系统的构造裂缝综合分析技术,通过构造DEM滤波分析、综合曲率分析、裂缝地形因子分析以及DEM构造应力场分析,提取与裂缝有关的构造起伏变化和侵蚀程度指标,对于碳酸盐岩储层利用DEM进行古水文地质条件分析,研究古地貌侵蚀和沉积的空间分布情况.根据构造应力场信息,综合分析不同构造部位岩层发生破裂的可能性及破裂程度,预测区域裂缝和局部构造裂缝发育带、发育程度及发育方向,并取得了不错的预测效果.     

面状发震构造在地震构造法中的应用：以大姚—姚安发震构造鉴定为例

核电厂地震安全性评价中的地震构造法,要求鉴定发震构造和划分地震构造区,在以往实践中,发震构造鉴定往往基于地表活动断裂构造,且表征为线状震源.当存在较强非随机分布的地震活动且难以找到清晰的地表活动断裂构造形迹时,地震构造法就难以合理地表现这些地震的危险性.本文以云南滇中大姚—姚安发震构造鉴定为例,探讨了在地表活动构造形迹不清,中强地震活动性较强的滇中大姚—姚安地区,采用面状发震构造来表征地震危险性的方法,讨论了在地震构造法中采用面状发震构造的必要性、鉴定思路和方法,并建议在今后的核工程地震危险性评价地震构造法中应充分考虑面状发震构造的应用.     

冀东地区燕山中段北西向构造带: 构造属性及其年代学

冀东地区燕山中段北西向构造带由北西向展布的逆冲断层系统、伸展断裂系、走滑断裂及伴生同构造沉积组成. 基底卷入、指向北东的主要逆冲作用发生于174 ~168 Ma之间, 随即发生了花岗质岩浆侵入活动. 伴随着逆冲后伸展构造作用, 在晚侏罗世-早白垩世晚期, 沿该带南西侧发育了北西向分布的土城子组、张家口组、义县组、九佛堂组等火山-沉积地层. 由于主要伸展断层的倾向位移量具有向东南方向逐渐增大的趋势, 因此, 火山活动和沉积作用显示出向东南方向南积作用迁移的特征. 九佛堂组沉积晚期及其以后, 北侧原物源区又发生向南西的逆冲作用, 在盆地东北缘逆冲断层下盘的九佛堂组地层形成了倒向南西的不对称向斜. 最后, 沿北西向构造带还发生了右行走滑运动. 该构造带醒目的地貌-构造表现以及频繁的地震活动表明, 在新生代以来它仍然具有很高的构造活动性. 该构造带在空间上与地质、地球物理研究所揭示的基底断裂构造基本吻合, 因此, 其中生代构造活动可以看作是在有利的区域构造应力作用下基底构造活化的结果. 这种基底构造活化可能是板内变形和板内造山作用的重要机制之一.     

四川省美姑地区叠加褶皱构造特征

美姑地区位于扬子陆块西南缘四川断块西南部,西邻康滇地轴断块,南东接上扬子断块.因此该区域内地质构造复杂.深入研究该地区的叠加构造特征、演化过程,为美姑河流域梯级水电开发提供可靠的地质资料非常有意义.研究表明,该区域主要发育了SN、NE、NW三个方向的叠加构造体系,这三个方向的构造分别形成于喜马拉雅造山期的三个阶段,明确了各个构造体系之间的演化序列.     

Protolith ages and deformation mechanism of metamorphic rocks in the Zhangbaling uplift segment of the Tan-Lu Fault Zone

Protolith ages and Indosinian deformation mechanism of metamorphic rocks in the Zhangbaling uplift segment of the Tan-Lu Fault Zone are important, unsolved problems. Our LA-ICP-MS zircon dating work indicates that protolith ages of the greenschist-facies Zhangbaling Group are 754–753 Ma, and those of the amphibolite-facies Feidong Complex are 800–745 Ma. These rocks belong to the earliest cover of the Yangtze Plate. Their ages and metamorphic features suggest that the rocks did not come from the Dabie Orogen. The Indosinian structures in the Zhangbaling Group and lower Sinian strata formed in a flatlying ductile detachment zone with a shear sense of top-to-the-SSW whereas those in the underlying Feidong Complex are characterized by ENE-WSW inclined folds developed under a ductile regime. It is suggested therefore that the sinistral Tan-Lu Fault Zone of the Indosinian period is buried under the Hefei Basin west of the Zhangbaling uplift segment and the uplift segment is a displaced block neighboring the fault zone. Detachment deformation between the upper rigid and lower ductile crust during displacement of the Zhangbaling uplift segment resulted in the formation of the flat-lying ductile detachment zone and its underlying drag fold zone of a ductile regime. The protolith ages and deformation mechanism in the Zhangbaling uplift segment further prove sinistral origination of the Tan-Lu Fault Zone during the continent-continent collision of the North China and Yangtze plates and support the indentation model for the two-plate collision that considers the Tan-Lu Fault Zone as an oblique convergence boundary.     

TECTONIC CHARACTERISTICS OF BAOTOU UPLIFT IN HETAO DEPRESSION ZONE

The Hetao depression zone, located to the north of Ordos block, is a complex depression basin that consists of two sub-uplifts and three sub-depressions. The depression zone is subject to the regional extensional stress field driven by the Indo-Asian continental collision and the westward subduction of the Pacific Plate. The Baotou uplift that separates the Baiyanhua sub-depression and Huhe sub-depression is mainly composed of Archean gneiss and is overlaid by Quaternary sedimentary strata. The two sub-depressions are bordered by the Wula Mountains and Daqing Mountains to the north, respectively. The bedrock exhumed in Wula Mountains and Daqing Mountains consists mostly of Precambrian granitic gneiss, and the piedmont depressions are infilled by thick Cenozoic strata. The Wulashan piedmont fault and Daqingshan piedmont fault extend along the range front of Wula Mountains and Daqing Mountains, respectively. The subsidence is controlled by the two boundary faults. Previous studies have preliminarily documented the characteristics of the northwest boundary fault of Baotou uplift. Combining shallow seismic exploration, active fault mapping, and geological drilling, this paper presents a detailed study on the tectonic characteristics of the Baotou uplift. The shallow seismic exploration reveals that the Baotou uplift is an asymmetrical wedge with a steep southeast wing and a gentle dipping northwest wing. The Baotou uplift is wider in the northeastern part and narrows down towards the southwest. In seismic profiles, the Baiyanhua sub-depression and the Huhe sub-depression manifest as asymmetric dustpan-like depressions with south-dipping controlling faults. Baotou uplift is bounded by the Xishawan-Xingsheng Fault to the northwest and Daqingshan piedmont fault to the southeast. The two faults exhibit significant difference in many aspects, such as fault geometry, fault displacement, the latest active time, and so on. The southeast boundary fault of Baotou uplift is the Baotou section of the Daqingshan piedmont fault which is a Holocene active fault and the major boundary fault of Huhe sub-depression. East of Wanshuiquan, the fault strikes EW-NEE; west of Wanshuiquan, the strike changes to NW. The Daqingshan piedmont fault appears as a south-dipping listric fault in seismic profiles whose dip decreases with depth and cuts through all the sedimentary strata in Huhe sub-depression; the fault extends along the late Pleistocene lacustrine platform at surface with prominent geomorphological evidences. The Xishawan-Xingsheng Fault is a buried high-angle normal fault that mainly dips to the northwest and strikes NE. The fault strike changes to NNE at the eastern tip. Based on the results of seismic exploration and geological drilling, the Xishawan-Xingsheng buried fault is an early to middle Pleistocene Fault capped by late Pleistocene lacustrine strata. We reckon that the Xishawan-Xingsheng Fault is one of the synthetic faults that dip towards the main boundary fault of Baiyanhua sub-depression. Similarities in lithology, geometry, and structural characteristics of south boundary faults all indicate that Baotou uplift is the western extension of Daqing Mountains. Multiple factors may contribute to the formation of Baotou uplift, such as tectonic subsidence and the development of large-scale river system and mega-lake. We suggest that the upwelling of asthenosphere may play a primary role in the evolution of Wulanshan piedmont fault and Daqingshan piedmont fault. Separated by the Baotou uplift, the Wulashan piedmont fault and Daqingshan piedmont fault can be regarded as independent seismogenic faults. The Hetao depression zone is featured by complex inner structures, and many scientific issues are subject to further researches. Thus, more attention should be paid to the secondary structures within the depression zone for a better understanding on the formation and evolution of Hetao depression zone.     

南天山及塔里木北缘构造带西段地震构造研究

南天山及塔里木北缘构造带位于帕米尔地区东北侧,地震活动强烈。文中通过地质构造剖面、深部探测资料和地震震源机制解资料,综合研究了该区的地震构造模型。结果认为,该区的构造活动主要表现为天山地块逆冲于塔里木地块之上。天山构造系统包括迈丹断裂及其前缘推覆构造;塔里木构造系统包括深部的塔里木北缘断裂、基底共轭断层和浅部的推覆构造。塔里木北缘断裂是发育于塔里木地壳内部的高角度断裂,其形成原因在于塔里木和天山构造变形方向的差异。塔里木北缘断裂为研究区大地震的主要发震构造,天山推覆构造和塔里木基底断裂系统均具有不同性质的中强地震发震能力     

塔里木西缘明尧勒背斜的弯滑褶皱作用与活动弯滑断层陡坎

塔里木西缘明尧勒活动背斜两翼河流阶地面上多处发育活动弯滑断层陡坎。这些断坎主要分布在活动轴面附近较陡的等斜岩层(地层倾角分别为74°~89°、18°~20°和45°~60°)一翼,往往成排发育在距活动轴面50~1 200m范围内,宽90~1 000m,长40~950m,随着离活动轴面的距离加大弯滑断层陡坎规模渐小。同一阶地面上发育的弯滑断层陡坎几乎以等间距或间距倍数关系产出。这些断坎走向与下伏基岩地层走向一致,基岩地层大多为中-厚层块状砂岩或粉砂岩互层,岩层间力学性质差异较小。明尧勒背斜南翼克孜勒苏河北岸T3阶地面废弃以来,单条弯滑断层的地表最大缩短速率为0.31mm/a,地表最大抬升速率为0.34mm/a。这些弯滑断层的活动具有重复性和新生性。     

阿拉善地块南缘的左旋走滑断裂与阿尔金断裂带的东延

阿拉善地块南缘发育了由5条走向近EW、向西收敛、向东撒开的断裂组成的断裂束,每条断裂长度一般>100km,控制第四纪盆地呈EW向长条状展布,卫片上线性影像清晰,晚第四纪以来表现出左旋走滑活动的特点。断裂束西段的金塔南山断裂与阿尔金断裂带东段的宽滩山段趋于交会,并与文殊山构造隆起之间构成构造转换关系。分析认为金塔南山断裂以及整个阿拉善南缘断裂束是阿尔金断裂左旋运动的东延部分,断裂束在平面上“帚状”的、向东撒开的构造样式有利于走滑运动量的分解、消减和吸收,符合走滑断裂末端的构造特点。阿拉善南缘断裂束的左旋走滑活动有可能是阿尔金断裂带进一步向东扩展的结果,其时代可能发生于早更新世末—中更新世初     

青藏高原东北缘主要断裂滑动速率及其动力学意义

本文利用青藏高原东北缘地区1991—2015年的GPS速度场资料, 基于弹性球面块体模型获得了区域活动断裂的滑动速率, 并讨论了断裂滑动速率分配的动力学意义。 反演结果表明, 青藏高原东北缘地区主要块体以北东向并兼顺时针旋转运动为主; 区域断裂平均闭锁深度为17 km; 另外, 各主要断裂滑动速率也不尽相同。 其中, 阿尔金断裂、 东昆仑断裂左旋走滑速率为10～12 mm/a, 祁连—海原断裂左旋走滑速率为3～5 mm/a, 鄂拉山断裂、 拉脊山断裂右旋走滑速率为1～3 mm/a。 阿尔金断裂、 祁连—海原断裂、 东昆仑断裂的走滑速率被其端部的山脉隆起和逆冲断裂所吸收和转换, 鄂拉山断裂和拉脊山断裂则起到了调节块体间运动平衡的作用。     

柯坪塔格推覆体的新生代变形与扩展

柯坪塔格推覆体位于天山西南麓。新生代以来,由于印度板块与欧亚板块的碰撞,天山晚古生代褶皱和断裂构造重新复活隆起,并向南北两侧推挤,在前陆盆地中渐进式地形成多排褶皱-逆断裂带。文中讨论了皮羌近SN向断裂带以西推覆体的新生代变形与扩展特征。结果表明,推覆体的新生代变形为波浪式差异性隆起。从天山南侧到塔里木盆地方向,构成推覆体的各排褶皱-逆断裂带的形成顺序有先后之分,早期形成的靠近天山,晚期形成的靠近塔里木盆地,反映推覆体在形成过程中由北向南的扩展,其扩展距离最大约76km。除此之外,各排褶皱-逆断裂带前缘都由多条断裂组成,它们与褶皱伴生,具有不同的形成和新活动时代。早期形成的断裂靠近山地一侧,晚期形成的断裂靠近盆地一侧,反映褶皱-逆断裂带单排前缘断裂也具有由北向南扩展的性质,其扩展距离为100~500m。最后,对推覆体扩展的形成机制进行了讨论     

东海陆架盆地雁荡低凸起综合地球物理解释及其成因探讨

通过对东海陆架盆地西部地震和重磁资料的综合地球物理解释,对雁荡低凸起展布形态进行了细致刻画,凸起呈NE方向不连续展布于瓯江凹陷和闽江凹陷之间,长约170 km、宽约15~50 km.地震资料揭示雁荡低凸起上广泛发育了侏罗纪与白垩纪地层,厚度约为500~1500 m,展布面积约5000 km²,局部缺失中生界地层.凸起两侧中生代盆地结构差异明显,西侧瓯江凹陷为典型的断陷盆地,东断西超、断裂发育,半地堑、掀斜断块等中生界构造样式发育;东侧闽江凹陷为坳陷型盆地,断裂、火成岩不发育,挤压背斜、断背斜、反转构造等中生界构造样式发育.自由空间重力异常图与剩余重力异常图上,凸起表现为一系列NE向团块状重力高值区,而磁力异常ΔT图上则表现为深部磁场强度低的特征,火成岩影响部位可见磁力高值异常.综合凸起及邻域重磁震、莫霍面深度等地质地球物理资料,认为雁荡低凸起为一元古界组成的古隆起,区别于东部的台北低凸起.同时,结合区域构造演化及沉积特征,推测侏罗纪时期雁荡低凸起与浙闽隆起区可能连为一体,晚白垩世近东西向伸展作用下浙闽隆起发生裂陷进而形成了雁荡低凸起.     

Sedimentary fill history of the Huicheng Basin in the West Qinling Mountains and associated constraints on Mesozoic intracontinental tectonic evolution

The Qinling Orogenic Belt is divided commonly by the Fengxian-Taibai strike-slip shear zone and the Huicheng Basin into the East and West Qinling mountains,which show significant geological differences after the Indosinian orogeny.The Fengxian-Taibai fault zone and the Meso-Cenozoic Huicheng Basin,situated at the boundary of the East and West Qinling,provide a natural laboratory for tectonic analysis and sedimentological study of intracontinental tectonic evolution of the Qinling Orogenic Belt.In order to explain the dynamic development of the Huicheng Basin and elucidate its post-orogenic tectonic evolution at the junction of the East and West Qinling,we studied the geometry and kinematics of fault zones between the blocks of West Qinling,as well as the sedimentary fill history of the Huicheng Basin.First,we found that after the collisional orogeny in the Late Triassic,post-orogenic extensional collapse occurred in the Early and Middle Jurassic within the Qinling Orogenic Belt,resulting in a series of rift basins.Second,in the Late Jurassic and Early Cretaceous,a NE-SW compressive stress field caused large-scale sinistral strike-slip faults in the Qinling Orogenic Belt,causing intracontinental escape tectonics at the junction of the East and West Qinling,including eastward finite escape of the East Qinling micro-plate and southwest lateral escape of the Bikou Terrane.Meanwhile,the strike-slip-related Early Cretaceous sedimentary basin was formed with a right-order echelon arrangement in sinistral shear zones along the southern margin of the Huicheng fault.Overall during the Mesozoic,the Huicheng Basin and surrounding areas experienced four tectonic evolutionary stages,including extensional rift basin development in the Early and Middle Jurassic,intense compressive uplift in the Late Jurassic,formation of a strike-slip extensional basin in the Early Cretaceous,and compressive uplift in the Late Cretaceous.     

Neogene deformation of the Kuqa-Tianshan Basin-range System

The Neogene deformation of the Kuqa-Tianshan Basin-range System is characterized by discrepancy in paleostress patterns on the basin-range boundary and in the basin interior, and by discrepancy in deformation styles of the basement and the cover. Measurement and paleostress reconstruction of the brittle faults display a stress pattern with NW-SE and/or NNW-SSE extension on the basin margin and NW-SE compression in the basin interior. The basement was cut into blocks separated by boundary faults and upthrusts that were recognized in the seismic reflection profile. The block-faulting could have caused vertical uplift of the basement and gravitational sliding in the overlying sedimentary cover. Theoretical calculation indicates two generations of potential decollement folds within the basin, with one being mudstone in the Triassic Huangshanjie formation and the other the Cenozoic salt-gypsum layers.