西秦岭北缘漳县新生代伸展断陷盆地确定及其地质意义     

《地学前缘》2017,(5):230-244

西秦岭北缘断裂带新生代以来挤压逆冲变形起始于何时?挤压逆冲变形之前是否经历过伸展拉张过程?北缘断裂带北侧的新生代红层盆地到底是类前陆压陷挠曲盆地还是拉张断陷盆地?上述问题对西秦岭新生代盆-山构造格局重建和印度-欧亚板块碰撞汇聚的远程构造响应的时间与方式等科学问题的认识具有重要的地质约束。本文通过对西秦岭北缘构造带内漳县渐新世—中新世含盐红层盆地沉积序列和沉积旋回特征以及盆地边界断裂之间的几何学-运动学关系分析,认为西秦岭北缘构造带内漳县含盐红层盆地具有拉张伸展动力学背景下形成的断陷盆地的地质特征。西秦岭北缘构造带内渐新世—中新世断陷盆地的确定,指示了印度板块与欧亚板块碰撞汇聚而导致的青藏高原构造挤压缩短作用至少在盆地沉积充填阶段尚未扩展到西秦岭北缘及以北地区。而漳县含盐红层盆地沉积地层褶皱缩短变形以及之后角度不整合在漳县含盐红层盆地之的上新统韩家沟粗砾岩,可能记录了西秦岭北缘由伸展边界向挤压缩短逆冲边界的转换过程。因此,青藏高原东北缘真正成为青藏高原体系组成部分是在上新世的漳县含盐红层盆地封闭-构造反转之后。这一认识对地学界长期以来认为印度板块与欧亚板块碰撞汇聚而导致的高原隆升和构造挤压早在渐新世就已经波及西秦岭北缘的观点提出了挑战。  相似文献   

青藏高原东北缘寺口子盆地新生代沉积演化及其构造意义   总被引：2，自引：0，他引：2  

王伟涛  张培震  张广良  郑德文  郑文俊  蒋汉朝 《地质科学》2010,45(2):440-452

宁夏固原寺口子盆地发育巨厚的新生代地层,这些地层记录了青藏高原东北部的沉积演化特征和构造演变历史。根据剖面沉积物粒度特征、沉积结构和构造、沉积层序,识别出20种岩相、5种沉积相类型。结合前人对寺口子剖面的古地磁测年,分析研究盆地的沉积演化特征以及对构造的响应表明:20.1 Ma盆地以缓慢的坳陷沉降开始演化,直至1.2 Ma遭受破坏。在此期间青藏高原东北部经历了6.4 Ma、4.6 Ma和1.2 Ma这3次明显的构造挤压隆升运动,其中约6.4 Ma的构造运动是青藏高原向东北部扩展首次影响到海原—六盘山断裂以东地区。从盆地的形成和沉积演化过程来看,马东山山前断裂的逆冲推覆,导致了寺口子盆地的强烈变形和构造降升,并且最终成为青藏高原的最新组成部分。  相似文献   

宁夏中南部中新世构造活动的地质证据及其意义   总被引：3，自引：0，他引：3  

张进  马宗晋  肖文霞  任文军 《地质学报》2006,80(11):1650-1660

通过区域性新生界的对比及不整合面分布的研究,发现宁夏地区中新世曾发生过两次构造运动,一次发生于早中新世,另一次发生于中中新世晚期,但以后者明显,分布也最广。其中前者集中在六盘山以西地区,后者分布在查汗布拉格—三关口—青铜峡—固原(查-固)断裂沿线。宁夏中北部大部分红柳沟组是在受中新世构造运动影响的环境下沉积的。发生于早中新世的构造运动集中体现在六盘山以西的地区和甘肃部分地区,该期运动使渐新统清水营组变形,由于这些现象多发生于海原断裂附近,因此推测在早中新世海原断裂就可能已活动了。而发生于中中新世晚期的运动体现在如下几个方面,在贺兰山中南段西侧发现了中中新世晚期的逆冲推覆活动,堆积了厚度较大的同构造沉积(红柳沟组);在查-固断裂沿线发现了由于中中新世晚期的构造活动而形成的红柳沟组与清水营组之间的角度不整合面,这些说明在该期青藏高原的变形前锋已到达查-固断裂,也就是鄂尔多斯西缘地区,早新生代盆地因此解体;与此同时盆地内部红柳沟组向上逐渐变粗,也说明中中新世晚期较强烈的构造运动已影响到了该区,香山地区开始隆起并分割了早先的盆地,使之成为背驮盆地。宁夏中南部并入到青藏高原东北缘逆冲构造楔之中,该逆冲构造楔中新世向北东扩展的原因可能是由于高原北部在同期显著的隆升运动使得逆冲楔顶角超过临界值,而向前扩展的,查-固断裂是早期类似于目前海原断裂的青藏高原变形前缘,整个高原东北部的扩展并不是前展式,而是一种没有特定顺序的变形。上述这些现象否定了前人认为宁夏地区第三系的变形发生在上新世末期—更新世以后的观点。  相似文献   

祁连山北缘早白垩世榆木山逆冲推覆构造与油气远景   总被引：3，自引：0，他引：3  

陈宣华  邵兆刚  熊小松  高锐  徐盛林  张义平  李冰  王叶 《地球学报》2019,40(3):377-392

榆木山地处祁连山北缘与河西走廊南缘的盆山结合带,是青藏高原北缘高原隆升与扩展的关键构造带。野外地质调查与构造填图发现,祁连山北缘的榆木山地区发育大型逆冲推覆构造,逆冲推覆构造之下是被掩埋的、褶皱了的早白垩世早期沉积地层,并被随后的走滑断裂活动和走滑双重构造所改造。深地震反射和大地电磁剖面测量与解释的初步结果,验证了祁连山北缘断裂以北发育的逆冲推覆构造,榆木山北缘山系构成飞来峰构造,将早白垩世酒泉盆地的一个分支掩盖在前中生代地层之下。构造关系分析给出主期逆冲推覆作用的时限大致为早白垩世早期,反映了在新生代印度—亚洲碰撞之前存在一期强烈的晚中生代构造挤压事件。逆冲推覆构造之下发现白垩纪盆地油气显示,扩展了该地区油气前景。  相似文献   

青藏高原中段古近纪早期古构造演化   总被引：1，自引：0，他引：1  

吴珍汉  胡道功  叶培盛  吴中海  张耀玲 《地球学报》2009,30(6):749-760

青藏高原古近纪早期发育大量区域逆冲推覆构造系统, 典型实例如冈底斯逆冲断裂系、纳木错西逆冲推覆构造、伦坡拉逆冲推覆构造、唐古拉山北逆冲推覆构造、东昆仑南部左旋斜冲断裂系。古近纪逆冲推覆构造对古新世—始新世沉积盆地具有重要控制和改造作用。冈底斯古新世—始新世早期发育大量中酸性岩浆侵入和多期中酸性火山喷发, 岩石Sr/Y-Y地球化学显示为岛弧岩浆岩, 推断与古近纪早期新特提斯残留古大洋板块俯冲存在成因联系。古近纪早期新特提斯残留大洋板块俯冲向印度大陆板块俯冲的转换时代约为46-45 Ma, 转换期前逆冲推覆构造运动与新特提斯残留古大洋板块俯冲存在密切关系; 转换期后印度大陆板块俯冲导致更为强烈的逆冲推覆构造运动和挤压缩短变形, 不仅使早期很多逆冲推覆构造继续发生构造运动, 还在喜马拉雅、冈底斯、风火山、东昆仑南部形成大量新的逆冲推覆构造系统。  相似文献   

准噶尔盆地南缘新生代构造特征及其与砂岩型铀矿成矿作用初析   总被引：5，自引：0，他引：5  

陈正乐  鲁克改  王果  陈柏林  王国荣  郑恩玖  崔玲玲  丁文君 《岩石学报》2010,26(2):457-470

准噶尔盆地南缘盆山结合部中新生界沉积巨厚,新生代变形强烈,是研究新盆山耦合的理想场所,也是我国砂岩型铀矿找矿的远景区段。本文在综合前人资料和野外观测分析基础上,根据新生代构造活动特征,将准噶尔盆地南缘划分为博格达山前和西部断褶带两个构造分区,博格达山前以强烈的逆冲推覆为特征,发育多条活动的逆冲推覆断裂; 乌鲁木齐以西至乌苏南的西部断褶带则发育三-四排的褶皱-逆冲断裂构造带。对采自博格达山前逆冲推覆断裂带内的方解石和断层泥,利用电子自旋共振测年手段,推测博格达山前的富康-吉木萨尔断裂带和北三台断裂带分别在0.7~1Ma和0.25Ma期间,经历了一期重要的逆冲推覆作用。结合盆地南缘砂岩型铀矿的展布规律及其成矿条件的分析,探讨了新生代构造运动对砂岩型铀矿成矿的控制作用,认为西部断褶带的第一排构造带具有较好的成矿前景,而博格达山前由于新生代构造活动强烈而相对成矿不利,为此提出了准噶尔盆地南缘砂岩型铀矿成矿“构造优先权”的构造控矿模式,进而指出了区域找矿的优选区段。  相似文献   

中国喜马拉雅构造运动的陆内变形特征与油气矿藏富集   总被引：12，自引：0，他引：12  

贾承造 《地学前缘》2007,14(4):96-104

在前人研究的基础上,结合近年来在油气勘探中不断积累的地质资料和地质认识,提出了中国喜马拉雅构造运动的陆内变形特征及其分布规律受控于小型克拉通板块拼贴的基底结构和印/欧碰撞与太平洋板块俯冲所主导的双重控制因素;喜马拉雅构造运动的发育特征主要表现为三种动力学机制:青藏高原隆升、盆地与造山带体制和东部拉张活动。喜马拉雅构造运动的大地构造格局及其构造变形分布规律集中体现为4个构造域:青藏高原隆升区、环青藏高原盆山体系、稳定区和环西太平洋裂谷活动区。我国沉积盆地在喜马拉雅构造运动中的构造特征分为三种类型:(1)东部渤海湾、松辽等盆地受拉张构造环境控制的裂谷沉降;(2)中部四川、鄂尔多斯等盆地受青藏高原的向东推挤、盆缘冲断、盆内抬升剥蚀;(3)西部的塔里木、准噶尔、柴达木等盆地受青藏高原的向北推挤、冲断挠曲沉降,表现为克拉通单边或双边的压缩挠曲沉降与克拉通内部的冲断隆升沉降等多种盆山耦合形式。喜马拉雅构造运动控制着中国油气晚期定位与富集成藏,主要体现在:盆地的沉积与成藏,形成新生界自生自储的含油气盆地和油气藏;圈闭形成与油气运聚成藏;早期油气藏的调整和再分配;油气藏的破坏。  相似文献   

塔里木东北地区盆山耦合及其对油气成藏的控制   总被引：6，自引：0，他引：6  

吴国干  夏斌  王核  李华启  陈志勇 《矿物学报》2004,24(3):218-224

震旦纪一寒武纪库鲁克塔格、英吉苏地区为陆内裂谷盆地。加里东末期与早海西运动造成塔东地区的普遍抬升剥蚀，孔雀河斜坡、罗布庄凸起开始形成，早二叠世，塔里木板块与中天山地块、哈萨克斯坦一准噶尔板块最终碰撞拼贴，古天山造山带相继形成。燕山晚期，受中特提斯洋关闭影响。塔里木盆地基底随造山带的构造抬升而部分抬升，喜马拉雅期开始，在南北向挤压力作用下，收缩、隆升的山体侧向扩张，向沉积盆地逆冲形成型逆冲推覆构造。造山带和盆地的共同演化不仅形成了多套烃源岩，而且控制了古生界和中新生界两套不同的油气成藏系统。元古界地层由北向南推覆，可能预示着在库鲁克塔格南缘西段山前前寒武纪地层下部保存有古生代和中新生代烃源岩建造，如果配有有利的油气储盖组合和圈闭，有望在山前获得突破。  相似文献   

东昆仑阿其克库勒湖地区的逆冲扩展作用   总被引：1，自引：0，他引：1  

崔军文  李朋武  张晓卫  陈文 《地质学报》2003,77(4)

东昆仑西段是我国西北地区地质研究程度较低的地区之一。通过典型剖面的构造分析,可以得出下列几点重要认识:①东昆仑西段具有十分发育的断裂构造系统,逆冲扩展、正滑作用和拆离作用是该区的主要变形事件。②逆冲断裂起始于晚石炭世和晚三叠世早侏罗世时期,但强烈活动发生在库木库里盆地强烈坳陷的中新世第四纪时期。③该区北向逆冲扩展作用和南向正滑作用并存的构造格局,和青藏高原北部的总体构造格局相一致,与青藏高原南缘喜马拉雅地区的构造格局也十分类似,但逆冲扩展方向相反,强烈逆冲扩展作用都发生在中—上新世至第四纪印度板块与欧亚板块强烈碰撞和青藏高原急剧隆升时期。这种方向相反的逆冲扩展和正滑作用揭示青藏高原深层物质向南、北两侧对称式扩展和表层物质向高原腹地重力滑动的运动学特征。因此该区断裂构造系统的建立对研究青藏高原北部的深部作用过程,建立青藏高原隆升的统一的地球动力学模式提供了一种思路。  相似文献   

祁连山北缘深部弧形褶皱—逆冲带及其油气勘探前景   总被引：1，自引：0，他引：1       下载免费PDF全文

杜文博  张进江  肖毓祥  张波  李晓军  侯秀林  王盟  李景  程光瑾 《地质科学》2016,(4):1059-1073

祁连山北缘-河西走廊西段位于青藏高原东北缘,是新生代陆内构造活动最强烈地区。基于野外构造观测、横跨山前及前陆盆地区的三维地震构造分析与解释,结合地震地质属性提取分析,识别出祁连山北缘-酒泉盆地西段窟窿山-柳沟庄带隐伏的弧形褶皱-逆冲带,该弧形构造是造山带基底逆冲构造楔体垂向差异抬升与向前陆方向差异运动的产物;该弧形结构控制本区下白垩统地层裂缝发育、分布与破裂强度,并与本区先期断裂、裂缝带产生构造叠加效应,形成弧形构造“中央强裂缝发育带”,是形成构造裂缝型油气藏的有利区域。  相似文献   

天山地区碰撞后构造与盆山演化   总被引：48，自引：0，他引：48  

舒良树  郭召杰  朱文斌  卢华复  王博 《高校地质学报》2004,10(3):393-404

研究表明,近东西向的天山造山带基本格架在古生代晚期已经初步形成;平行造山带广泛分布的二叠纪红色磨拉石证明当时造山隆升作用非常强烈,导致前陆盆地普遍发育。三叠纪,天山造山带遭受区域剥蚀夷平,盆山高差缩小,盆地规模进一步扩大。侏罗纪—古近纪,由于板内伸展作用,在准平原化的天山地区形成了一系列伸展盆地,呈近东西向分布。新近纪以来,受南面印度—欧亚陆—陆碰撞的影响,天山地区发生强烈陆内变形,以逆冲推覆和褶皱堆叠为特征;节理统计表明新生代的主压应力为南北方向。晚新生代,由印度和欧亚大陆碰撞产生的强烈挤压作用对大陆腹地的天山地区影响很大：前中生代块体发生剧烈隆升和褶皱,伴随大规模新生代坳陷的形成,导致盆山高差急剧增大;脆性剪切与挤压变形构造叠加在韧性变形的古生代岩层之上。同时,中生代拉伸盆地发生构造反转,形成新生代挤压盆地,盆山交接带变形以台阶状逆断层和断层相关褶皱为特征。由于盆地朝造山带的下插作用,使古生代的岩层呈构造岩片方式逆冲推覆在盆地边缘的中新生代岩层之上,当穿越不同地质构造单元时表现出不同的运动学特征。强烈挤压褶皱冲断是晚新生代盆山交接带的基本特征和最普遍的盆-山耦合方式,局部伴有小规模近东西向的走滑断层。中生代沉积岩的褶皱与断裂、侏罗纪煤层自燃及烧结岩的形成、强烈地震与断层活动、以及新疆独特的镶嵌状盆山格局,都是新近纪以来构造作用的产物。  相似文献   

阿拉善地块新生代构造作用——兼论阿尔金断裂新生代东向延伸问题   总被引：17，自引：1，他引：16  

张进李锦轶  李彦峰马宗晋 《地质学报》2007,81(11):1481-1497

阿拉善地块在新生代的变形是青藏高原北部活动的直接结果,各方面的资料显示这种影响仅发生在中新世中晚期,前的活动性已经很低。阿尔金断裂的延伸并不能穿过阿拉善与南蒙古相关断裂相连,我们的研究更偏重认为阿尔金断裂没有进入阿拉善地区,而是经过金塔—花海盆地南缘的宽滩山—黑山地区与合黎山—龙首山南缘断裂相连,中新世中晚期,由于青藏高原北部重要的构造事件,青藏高原由南向北挤压河西走廊地区,造成了金塔—花海盆地内部由近南北向构造转变为近东西向构造。同时形成北山地区控制上第三系沉积(上新统)的东西向断裂。而阿拉善南缘产生右行走滑运动,地块的北部及内部则产生了近南北向的第三纪伸展构造,这些伸展构造以及金塔—花海盆地第三纪断裂控制的沉积与前人认为的强前陆、弱限制性边界的侧向挤出类似。我们认为阿拉善及蒙古地区中新世—上新世期间,由于受到青藏高原近南北向的挤压,产生区域性的"共轭"断裂系统,由于这些地区早期构造的控制,这些新活动的断裂主要迁就于老构造,以脆性活动为主,在蒙古国形成了沿阿尔泰山的北西—南东向断裂和东南部的北东—南西向"共轭"断裂系统,而阿尔金断裂与合黎山—龙首山南缘断裂则形成南侧的"共轭"断裂系统。北山以及金塔—花海地区则是这两组断裂的交汇地区,挤压作用明显,控制了新生代的沉积,并导致了新生代金塔—花海盆地的形成。阿拉善地块作为夹持在这两组断裂之间的地块,发生了一定程度的向东挤出运动,在其东缘贺兰山西侧形成了新生代的挤压构造,而在其东北缘和西南缘则迁就早期的韧性剪切带分别向北东和南西运动,产生相应的变形。该模型能够合理地解释阿拉善周围地区及其内部中新世以来的变形及其与青藏高原北部构造运动之间的关系。  相似文献   

Sedimentary characteristics of Cenozoic strata in central-southern Ningxia,NW China: Implications for the evolution of the NE Qinghai–Tibetan Plateau     

《Journal of Asian Earth Sciences》2011,40(6):740-759

Cenozoic sedimentary deposits in central-southern Ningxia province, NW China are an important record of Tertiary tectonic events along the evolving Qinghai–Tibetan Plateau’s northeast margin. Shortly after the onset of the Indo-Eurasia collision to the south, a thrust belt and adjoining foreland basin began to form during 40–30 Ma. The Eocene Sikouzi Formation developed in a distal setting to this basin, in normal fault-bound basins that may have formed in a forebulge setting. Subsequent deposition of the Oligocene Qingshuiying Formation occurred during a phase of apparently less intense tectonism and the previous underfilled foreland basin became overfilled. During the Early Miocene, contractional deformation was mainly distributed to the west of the Liupan Shan. This resulted in deformation of the Qingshuiying Formation as indicated by an unconformity with the overlying Miocene Hongliugou Formation. The unconformity occurs proximal to the Haiyuan Fault suggesting that the Haiyuan Fault may have begun movement in the Early Miocene. In the Late Miocene, thrusting occurred west of the southern Helan Shan and an unconformity developed between the Hongliugou and Qingshuiying Formations proximal to the the Cha-Gu Fault. Relationships between the Miocene stratigraphy and major faults in the region imply that during the Late Miocene the deformation front of the Qinghai–Tibetan Plateau had migrated to the Cha-Gu Fault along the western Ordos Margin, and the Xiang Shan was uplifted. Central-southern Ningxia was then incorporated into the northeast propagating thrust wedge. The driving force for NE propagation of the thrust wedge was most likely pronounced uplift of the northeastern plateau at the same time. Analysis of the sedimentary record coupled with consideration of the topographic evolution of the region suggests that the evolving fold-and-thrust belt experienced both forward-breaking fold-and-thrust belt development, and out-of-sequence fault displacements as the thrust wedge evolved and the foreland basin became compartmentalised. The documented sedimentary facies and structural relationship also place constraints on the Miocene-Recent evolution of the Yellow River and its tributaries.  相似文献   

Early Cenozoic Tectonics of the Tibetan Plateau   总被引：1，自引：0，他引：1  

WU Zhenhan  HU Daogong  YE Peisheng  WU Zhonghai 《《地质学报》英文版》2013,87(2):289-303

Geological mapping at a scale of 1:250000 coupled with related researches in recent years reveal well Early Cenozoic paleo-tectonic evolution of the Tibetan Plateau. Marine deposits and foraminifera assemblages indicate that the Tethys-Himalaya Ocean and the Southwest Tarim Sea existed in the south and north of the Tibetan Plateau, respectively, in Paleocene-Eocene. The paleooceanic plate between the Indian continental plate and the Lhasa block had been as wide as 900km at beginning of the Cenozoic Era. Late Paleocene transgressions of the paleo-sea led to the formation of paleo-bays in the southern Lhasa block. Northward subduction of the Tethys-Himalaya Oceanic Plate caused magma emplacement and volcanic eruptions of the Linzizong Group in 64.5-44.3 Ma, which formed the Paleocene-Eocene Gangdise Magmatic Arc in the north of Yalung-Zangbu Suture (YZS), accompanied by intensive thrust in the Lhasa, Qiangtang, Hoh Xil and Kunlun blocks. The Paleocene-Eocene depression of basins reached to a depth of 3500-4800 m along major thrust faults and 680-850 m along the boundary normal faults in central Tibetan Plateau, and the Paleocene-Eocene depression of the Tarim and Qaidam basins without evident contractions were only as deep as 300-580 m and 600-830 m, respectively, far away from central Tibetan Plateau. Low elevation plains formed in the southern continental margin of the Tethy-Himalaya Ocean, the central Tibet and the Tarim basin in Paleocene-Early Eocene. The Tibetan Plateau and Himalaya Mts. mainly uplifted after the Indian-Eurasian continental collision in Early-Middle Eocene.  相似文献   

藏北低速体存在的地震学证据——INDEPTH4宽频地震结果   总被引：1，自引：0，他引：1  

薛光琦  赵文津  宿和平  钱辉  冯梅  James Mechie 《地球学报》2011,32(3):331-335

位于青藏高原东北部的INDEPTH-IV地震探测剖面,始于柴达木盆地南缘,穿越东昆仑造山带、金沙江缝合线,终止于羌塘地体.本文作者利用天然地震体波完成了该区的三维走时残差反演,勾划出了青藏高原东北部的深部构造格局.研究区最显著的现象则是分布在昆仑地体、可可西里地体、羌塘地体北部下地壳、上地幔中的低速体.对其成因,有可能...  相似文献   

Sedimentary evolution of basins in mobile belts: examples from the Tertiary terrigenous sequences of the Peloritani Mountains (NE Sicily)     

F. Lentini  S. Carbone  S. Catalano  A. Di  Stefano  C. Gargano  M. Romeo  S. Strazzulla  G. Vinci 《地学学报》1995,7(2):161-170

The Tertiary covers of the Peloritani Mountain Belt (NE Sicily) provide a complete stratigraphical record of tectonic events related to collision in the Central Mediterranean region. The tectonosedimentary evolution is inferred from interpretation of new field data and indicates various stages of polyphase deformation. The Peloritani Mountain Belt is composed mostly of crystalline units representing the active margin of the European Plate that was thrust over the descending African Plate during the Tertiary. Late Eocene-early Oligocene syn-orogenic deposition took place within a fore-arc basin located along the leading edge of the Peloritani Mountain Belt. From the late Oligocene to late Langhian, terrigenous deposition occurred throughout the mountain belt and extended into perched basins, located in southern areas. The basin was fed from the north, from source areas located in the hinterland of the orogenic belt. Deposition was controlled by a combination of active thrusting, regional subsidence and sea-level change. During the early Serravallian sudden tectonic inversion took place, associated with collapse of hinterland areas and uplift of former low-lying southern areas of the mountain belt. These processes were related to onset of opening of the Tyrrhenian Sea that was completed during the Serravallian-Tortonian, and resulted in the deposition of a northwestward prograding clastic fan, fed by source areas located in the southern area of the mountain belt. This setting characterized Messinian and Plio-Pleistocene deposition, and was controlled by both active tectonics and eustasy. The Recent evolution of the Peloritani Mountain Belt is characterized by major progressive uplift of the southern margins of the Tyrrhenian Basin, and local active subsidence related to downfaulting. Such processes resulted in the uplift of mid-Pleistocene fan-delta deposits and late Pleistocene marine terraces deposits to various altitudes above present sea-level.  相似文献   

How did the Alxa Block respond to the Indo-Eurasian collision?     

Jin Zhang  Jinyi Li  Yanfeng Li  Zongjin Ma 《International Journal of Earth Sciences》2009,98(6):1511-1527

The Cenozoic deformation of the Alxa Block resulted directly from the evolution of the northern Qinghai-Tibetan Plateau. However, many data show that the deformation occurred only in the Middle-Late Miocene. Our studies show that the Altyn Tagh fault did not pass through the Alxa Block; on the contrary it went along the southern boundary of the Jintai-Huahai Basin, linking with the Helishan—southern Longshoushan fault. Due to important tectonic events in the northern Qinghai-Tibetan plateau during the Middle-Late Miocene time, the northern plateau underwent rapid uplift and the plateau compressed the Hexi Corridor Region, resulting in a change from NS-trending to EW-trending structures in the Jinta-Huahai basin, and in the development of compressive structures in the Beishan. The southern Alxa fault underwent right lateral movement, and in the northern and central parts of the block, NS-trending Tertiary extensional structures formed. These basins controlled by Tertiary faults are similar to basins developed by lateral extrusion with a strong foreland and weak limited boundaries. The authors suggest that a regional “conjugate” fault system resulted from nearly NS-trending compression from the Qinghai-Tibetan Plateau during the Miocene and Pliocene in the Alxa Block and southern Mongolia. And due to the control of early structures in these regions, most brittle faults reactivated earlier ductile faults; NW–SE faults along the Altai Mountain and NE–SW faults to the southeast in Mongolia consist of a “conjugate” fault system to the north. The Altyn Tagh fault and southern Helishan-Longshoushan fault comprise a “conjugate” fault system to the south. The Beishan and Jinta-Huahai Basin occupied the convergent area between these two sets of faults; the compression controlled the Tertiary deposition and led to the development of the Cenozoic Jinta-Huahai Basin. The Alxa Block bounded by these two sets of faults moved eastwards, which resulted in the development of Cenozoic compressive structures to the west of Helan Shan, and superimposed early ductile shear zones along the northeastern and southwestern boundaries of the Alxa Block respectively. This model could explain the Cenozoic deformation occurring in and around the Alxa region.  相似文献   

Polyphase Tectonic Events and Cenozoic Basin-Range Coupling in the Tianshan Belt, Northwestern China   总被引：3，自引：0，他引：3  

J.CHARVET  S.LAURENT-CHARVET 《《地质学报》英文版》2003,77(4):457-467

Studies show that the Tianshan orogenic belt was built in the late stage of the Paleozoic, as evidenced by the Permian red molasses and foreland basins, which are distributed in parallel with the Tianshan belt, indicating that an intense folding and uplifting event took place. During the Triassic, this orogenic belt was strongly eroded, and basins were further developed. Starting from the Jurassic, a within-plate regional extension occurred, forming a series of Jurassic-Paleogene extensional basins in the peneplaned Tianshan region. Since the Neogene, a collision event between the Indian and the Eurasian plates that took place on the southern side of the Tianshan belt has caused a strong intra-continental orogeny, which is characterized by thrusting and folding. Extremely thick coarse conglomerate and sandy conglomerate of the Xiyu Formation of Neogene System were accumulated unconformably on the Tianshan piedmont. Studies have revealed that the strong compression caused by the Indian-Eurasian collision  相似文献   

长江中下游深部构造及其中生代成矿动力学模式   总被引：1，自引：0，他引：1  

刘博  李三忠  王鹏程  刘鑫  李玺瑶  赵淑娟 《岩石学报》2018,34(3):799-812

长江中下游地区是中国重要的成矿带之一。本文利用地震、大地电磁数据以及野外地质调查,并结合前人研究的地球物理和岩石地球化学资料,明确了长江中下游地区现今深部构造,系统分析了其成矿动力学演化机制。本区发育有三大断裂体系:大别-苏鲁前陆断裂系、江南-雪峰断裂系和中国东部NE-NNE向走滑断裂系。大别-苏鲁前陆断裂系为一自北向南的叠瓦式逆冲推覆构造,而江南-雪峰断裂系为一自南向北的多级逆冲推滑构造,它们沿来安-望江-阳新-天门一线形成强烈的挤压对冲构造样式。中国东部NE-NNE向走滑断裂系早期主要表现为左行平移走滑并侧向挤压,参与了对冲构造形成过程,只是部分切割其它两个逆冲体系。这三大断裂体系均经历了印支-燕山期穿时递进的构造变形。152~135Ma,古太平洋板块向欧亚大陆俯冲时,板片可能沿着转换断层撕裂并产生底侵体。下地壳在底侵体的烘烤作用下熔融并受到混染,其岩浆在多级逆冲推覆和滑脱构造背景下充分结晶分异形成低镁埃达克岩,于断隆或隆坳过渡带生成铜矿。135~127Ma,长江中下游成矿带深部地幔开始上隆,诱发加厚岩石圈沿着郯庐断裂带局部拆沉,并引发富集地幔上升流。其与残留地壳交代反应,在郯庐断裂带两侧形成高镁埃达克岩。古太平洋板块继续向南西俯冲并发生逆时针旋转,长江中下游地区大多数NNE向断裂已转变为右行走滑,形成右行右阶的走滑拉分盆地。上隆地幔的基性岩浆沿着深切地壳的走滑断裂上升到盆地中,快速冷却形成橄榄玄粗岩岩系,从而在接触带或潜火山岩体顶部分异产生铁矿。  相似文献