武夷山北缘断裂带运动学研究

华南武夷山北缘边界被绍兴—江山—东乡断裂带所限。该断裂带至少保留了三期构造事件的形迹。第一期发生在８００Ｍａ～９００Ｍａ的晚元古代，呈ＮＷ向ＳＥ的区域推覆韧剪变形运动，以构造混杂岩和区域绿片岩相角闪岩相变质、强烈的褶皱和韧剪变形为特征，对应于古洋盆关闭、华南复合地体与江南岛弧碰撞焊接过程。第二期发生在４５８Ｍａ～４２１Ｍａ的志留纪，表现为从北向南的韧剪变形运动，伴有左旋走滑韧性剪切，以糜棱岩化和进变质作用为特征，黑云母多变为硅线石。该期变形使第一期构造形迹被强烈迭加置换。其动力学背景与闽东南地体朝武夷山的拼贴增生事件有关。第三期属中生代陆内变形，是一种高构造位的左旋走滑脆性剪切，以岩石的破裂和岩块的水平位移为特征，并具转换拉伸性质，导致中生代火山沉积盆地的形成。     

武夷山北缘断裂带动力学研究

华南武夷山北缘边界被绍兴－兴山－东乡断裂带所限。该断裂带到少保留了三期构造事件的形迹，第一期发生在８００Ｍａ～９００Ｍａ的晚元古代，呈ＮＷ向ＳＥ的区域推覆韧剪变形运动，以构造混杂岩和区域绿片岩相－角闪岩相变质，强烈的褶皱和韧剪变形为特征，对应于古洋盆关闭，华南复合地体与江南岛弧撞焊接过程，第二期发生在４５８Ｍａ～４２１Ｍａ的志留纪，表现为从北向南的韧剪变形运动，伴有左旋走滑韧性剪切，以糜棱岩化和进变质作用为特征．黒云母多变为硅线石。该期变形使第一期构造形迹被强烈选加置换。其动力学背景与闽东南地体朝武夷山的拼贴增生事件有关。第三期属中生代陆内变形，是一种高构造位的左旋走滑脆性剪切，以岩石的破裂和岩块的水平位移为特征．并具转换拉伸性质，导致中生代火山沉积盆地的形成。     

中天山北缘大型右旋走滑韧剪带研究

中天山北缘是一个近 EW向的大型右旋走滑韧剪带。宏、微观构造尺度的运动学研究表明 ,该带经历过至少二期韧性变形作用。第一期为从南向北的逆冲推覆韧剪变形 ,时代为中—晚志留世 ,以米什沟剖面为代表 ,对应于早古生代洋壳从北向南俯冲及稍后吐哈陆块朝中天山岛弧的碰撞事件。第二期为沿 EW方向的右旋走滑韧性变形 ,其构造形迹广泛分布于中天山北缘带各个地段 ;北天山石炭纪火山岩已卷入该期构造活动 ,走滑时代为晚石炭世—早二叠世 ,对应于晚石炭世塔里木与西伯利亚两大板块碰撞造山诱发的陆内变形、走滑剪切。走滑带中新生白云母 4 0 Ar/39Ar年龄为 ( 2 69± 5) Ma。剪切面理、拉伸线理、矿物韧剪构造、石英 C轴组构提供了构造运动学证据 ;地层不整合及同位素测年值提供了变形时间证据。二叠纪以后的构造事件也影响到中天山北缘带 ,但只有脆性变形形迹 ,无韧性剪切。最后对本区古生代构造演化进行了讨论     

秦岭南缘大巴山褶皱－冲断推覆构造的特征

秦岭造山带南缘的大巴山巨型逆冲推覆构造主要是在秦岭造山带板块俯冲碰撞造山与中、新生代以来陆内造山过程中长期复合作用形成的。详细的室内外构造研究表明,巴山逆冲推覆构造可以巴山弧形断裂带为界划分为北大巴山逆冲推覆构造和南大巴山逆冲推覆构造。北大巴山自北而南依次由安康－武当推覆体、紫阳－平利推覆体、高桥－镇坪推覆体和高滩推覆体逆冲叠置而成。南大巴山则以镇巴－阳日断裂为界,分为北部的前陆冲断褶皱带和南部的前陆褶皱带。北大巴山主要是印支期碰撞造山作用和燕山期陆内逆冲推覆作用叠加改造的结果,南大巴山则主要是燕山期递进变形过程中的产物。构造变形北强南弱,北以冲断褶皱变形为特征,南以皱褶作用为主;北部褶皱紧闭复杂,向南渐变为宽缓的薄皮构造。逆冲作用在时序上具有由北向南扩展传递的特点。     

龙门山冲断带的隆升和川西前陆盆地的沉降

通过龙门山区和川西前陆盆地岩石样品的裂变径迹和镜质体反射率的测定和计算机模拟得出：１）松潘－甘孜褶皱带１０Ｍａ以来至少隆升了３－４ｋｍ，隆升速率最低为０．３－０．４ｍｍ／ａ；（２）龙门山逆冲推覆构造带１０Ｍａ以来至少隆升了５－６ｋｍ，隆升速率最低为０．０１６－０．０３２ｍｍ／ａ；（４）川西前陆盆地６０Ｍａ以来降升１－２ｋｍ，降升速率为０．０２８－０．０５ｍｍ／ａ；（５）１０Ｍａ以来北川－映秀－小关     

下扬子地区前陆变形构造格局及其动力学机制

华北板块与扬子板块于印支－早燕山期发一陆－陆碰撞时,使造山带南部的下扬子地区成为前陆变形带。下扬子前陆变形带上,大致以长江为界,北部的逆冲推覆构造系统为向南运动,南部的逆冲推覆构造系统为向北运动,总体呈两套对冲的逆冲推覆构造系统。长江以北前陆变形的动力来自华北与扬子板块沿大别－胶南造山带的碰撞,长江以南前陆变形的动力来自沿江南隆起带的板内造山。     

武当地块主要地质事件年代学研究

武当地块是南秦岭构造带内一系列前寒武纪地块之一,古生代以来经历过３次重要的构造变形,即伸展作用逆冲推覆作用和造山晚期走滑构造作用。运用＾４０Ａｒ／Ａｒ阶段升温、＾４０Ａｒ／Ａｒ激光探针及Ｓｍ－Ｎｄ等时线等多种测年方法确定构造发生于４２３～２６１Ｍａ、逆冲推覆构造发生于２３４～２００Ｍａ,表明伸展构造可能分 与商丹缝合带的碰撞及勉略洋的拉开有关,称之为同碰撞伸展构造,而武当地块内发育的逆冲推覆构造则     

九岭山南缘断裂带运动学研究

江南晚元古代碰撞造山带中段九岭山南缘断裂带的运动学研究揭示出三个不同时期的强烈构造变形作用。第一期从北向南仰冲推覆作用,对应一个晚元古代洋盆关闭,板块碰撞造山过程;第二期从SW向NE的左旋走滑动性剪切作用,对应一个早古生代华南地体的斜向拼贴增生活动;第三期从北向南的逆冲-推覆作用,对应一个印支构造期的侧向挤压机制。现代地表上的九岭古岛弧南缘断裂带,是一个以走滑剪切力学作用占优势的片麻状糜棱岩带。宏观韧剪组构和显微构造标志为这个断裂带提供了重要的运动学证据。     

内蒙古苏左旗地区晚古生代构造—岩浆活动及地壳演化特征

华北地台北缘内蒙古中部地区晚古生代前发生过造山后伸展作用，在晚泥盆世－早石炭世，本区经厅了短暂的造山作用，形成前陆盆地并推积了滨浅 海相磨拉石建造，同时伴有同碰撞期花岗岩产生。中石炭世一早二叠世，本区进入造山后的陆内伸展作用阶段，并发育大量火山岩。火山岩碱质含量高，碱质成分中Na2O>K2O，且显示双峰分布特征；碎屑岩成分熟度和结构熟度降低，表明中石炭世一早=叠世本区进人陆内伸展构造发育阶段。     

北山—南戈壁地区侏罗纪巨型逆冲推覆体

北山—南戈壁海西—印支造山带内发现位移至少１２０ｋｍ—１８０ｋｍ的侏罗纪逆冲推覆体。推覆体走向Ｅ—Ｗ,长１２００ｋｍ以上,将中元古界白云灰岩推覆在新元古界至下—中侏罗统岩层之上。据断层面上的擦痕、沟槽、纤维线理、近断层拖褶曲、褶皱倒向和上盘叠瓦断层等运动学标志表明,西部北山地区上盘向北运动,而东部南戈壁地区相对于东侧向南运动。推测两大推覆断层带（北山推覆体和南戈壁推覆体）被一大型撕裂断层（弱水断层）所分割。主冲断层后期变形为一系列Ｅ—Ｗ背形和向形构造,侵蚀作用使这些推覆体分割成许多位于主断层向形构造部位的飞来峰。推覆事件之后,因伸展事件形成的亚干变质核部杂岩,其Ａｒ４０＿Ａｒ３９坪年龄为１５５．１±１０Ｍａ,Ｒｂ—Ｓｒ等时年龄为１５３±６．２Ｍａ。推覆体形成于中侏罗世晚期（远晚于本区以前报导的大洋闭合时代）,本文作为陆内变形期。侏罗纪特提斯海的闭合或特提斯碰撞前,亚洲南部活动大陆边缘后侧的岛弧后撤变形或蒙古—鄂霍茨克大洋的闭合可能与此陆内变形有关。     

天山东段推覆构造研究

本文概括性总结了天山东段大型推覆构造的基本特征。根据地质证据和同位素年龄,东天山存在早古生代末,晚古生代晚期和新生代三期推覆构造;根据推覆构造分布规律及构造背景,在平面上划分为五大推覆带、9个大型韧剪带;根据出露岩石的矿物变形相将东天山推覆构造划分为深、中深和浅三个深度层次;通过韧剪变形组构的观察分析,确定了多期韧性变形性质与运动方向。糜棱岩中超微构造、古应力及小构造变形缩短率测量统计,证明东天山推覆变形具有显著的地壳缩短增厚作用。新生代板块碰撞导致本区中新生代盆地基底向造山带A型俯冲,造山带向盆地推覆,其结果就构成了今日看到的镶嵌状盆地-山脉构造地貌景观。     

江南造山带东段新元古代至早中生代多期造山作用特征

新元古代江南造山带远离晚中生代活动大陆边缘,是研究华南地区新元古代至早中生代多期造山作用的理想对象。文章通过对江南造山带东段沉积建造、岩浆活动、构造变形以及同位素年代学数据的综合分析,总结了其晋宁期、广西期以及印支期造山作用的特征。江南造山带东段在晋宁期经历了南北两侧大洋俯冲和两期碰撞造山作用。新元古代早期(880~860 Ma)双溪坞岛弧与扬子陆块东南缘发生弧-陆碰撞作用,形成淡色花岗岩、高压蓝片岩、NNE向褶皱-逆冲构造以及弧后前陆盆地。新元古代中期(约850 Ma),扬子陆块北缘开始发育由北向南的大洋俯冲。随着俯冲作用的进行,弧后盆地发生关闭,扬子陆块与华夏陆块发生陆-陆碰撞并形成新元古代(820~810Ma)江南造山带,导致近E-W走向褶皱-逆冲构造、韧性变形以及过铝质花岗岩的发育。江南造山带东段在约810Ma开始发生后造山垮塌和裂谷作用,以发育南华纪早期(805~750 Ma)花岗岩、中酸性火山岩、基性岩以及裂谷盆地为特征。江南造山带东段万载—南昌—景德镇—歙县断裂带以南地区卷入了华南广西期造山作用,发育近E-W走向由南向北的逆冲构造(465~450 Ma)、NNE向正花状构造(449~430 Ma)以及后造山近E-W走向韧性走滑剪切带(429~380 Ma)。印支期造山作用导致了NNE向褶皱-逆冲构造和花岗岩的发育,并奠定了江南造山带东段的基本构造面貌。     

A Large-Scale Palaeozoic Dextral Ductile Strike-Slip Zone:the Aqqikkudug-Weiya Zone along the Northern Margin of the Central Tianshan Belt,Xinjiang,NW China

The nearly E-W-trending Aqqikkudug-Weiya zone, more than 1000 km long and about 30 km wide, is an important segment in the Central Asian tectonic framework. It is distributed along the northern margin of the Central Tianshan belt in Xinjiang, NW China and is composed of mylonitized Early Palaeozoic greywacke, volcanic rocks, ophiolitic blocks as a mélange complex, HP/LT-type bleuschist blocks and mylonitized Neoproterozoic schist, gneiss and orthogneiss. Nearly vertical mylonitic foliation and sub-horizontal stretching lineation define its strike-slip feature; various kinematic indicators, such as asymmetric folds, non-coaxial asymmetric macro- to micro-structures and C-axis fabrics of quartz grains of mylonites, suggest that it is a dextral strike-slip ductile shear zone oriented in a nearly E-W direction characterized by "flower" strusture with thrusting or extruding across the zone toward the two sides and upright folds with gently plunging hinges. The Aqqikkudug-Weiya zone experienced at least two stages of ductile shear tectonic evolution: Early Palaeozoic north vergent thrusting ductile shear and Late Carboniferous-Early Permian strike-slip deformation. The strike-slip ductile shear likely took place during Late Palaeozoic time, dated at 269(5 Ma by the40Ar/39Ar analysis on neo-muscovites. The strike-slip deformation was followed by the Hercynian violent S-type granitic magmatism. Geodynamical analysis suggests that the large-scale dextral strike-slip ductile shearing is likely the result of intracontinental adjustment deformation after the collision of the Siberian continental plate towards the northern margin of the Tarim continental plate during the Late Carboniferous. The Himalayan tectonism locally deformed the zone, marked by final uplift, brittle layer-slip and step-type thrust faults, transcurrent faults and E-W-elongated Mesozoic-Cenozoic basins.     

新疆兴地断裂带前寒武纪构造—岩浆—变形作用特征及其年龄

本文分析了发生在塔里木北缘兴地断裂带的多期构造—岩浆演化特征。在此基础上,对三件前寒武纪火成岩样品进行了LA-ICP-MS锆石U-Pb定年,对兴地断裂带韧性变形构造进行了运动学分析。研究表明,兴地断裂带至少经历了4期地质构造演化; 其中,前寒武纪有两期。第一期发生在前南华纪,以强烈的挤压褶皱、韧性剪切变形和岩浆活动为特色; 第二期发生在南华纪—震旦纪,以广泛发育的双峰式火成岩、复式岩流和基性岩墙群为特征,伴随大规模冰川作用和地壳沉陷,对应Rodinia超大陆的裂解。LA-ICP-MS法锆石U-Pb年龄测定表明,辉长岩中的俘获锆石保留了3114±20Ma、2509±42Ma、1916±36Ma等多期古构造演化和岩浆活动信息,揭示研究区深部存在一个中-新太古代和古元古代的基底。双峰式火成岩测年数据证实,区内在820~800Ma(花岗岩脉,798±7Ma; 辉长辉绿岩墙,816±15Ma)发生过强烈的裂谷—岩浆活动。根据构造交切关系,兴地断裂带发生过两期前南华纪韧性变形;变形时代尚不清楚。运动学分析表明,第一期为朝北逆冲的推覆变形,第二期为右旋走滑变形。南华纪以来,区域变质和韧性变形微弱,为韧脆性变形。     

北秦岭二郎坪岩群两侧韧性剪切带的构造变形及其意义

北秦岭二郎坪岩群南、北两侧分别被朱夏韧性剪切带和瓦乔韧性剪切带与秦岭岩群和宽坪岩群分开,这两条韧性剪切带对二郎坪弧后盆地的演化起着十分重要的作用。本文对这两条剪切带进行了详细的几何学、运动学和⁴⁰Ar-³⁹Ar年代学研究。几何学和运动学分析结果指示瓦乔剪切带具有由北向南逆冲剪切的运动学特征,而朱夏剪切带早期具有由南向北逆冲的运动学特征,而后期又发生右行走滑活动。对瓦乔剪切带和朱夏剪切带内的糜棱岩中白云母进行了⁴⁰Ar-³⁹Ar法定年,结果指示瓦乔剪切带逆冲活动发生在387±1.7 Ma,朱夏韧性剪切早期逆冲发生在晚古生代,后期右行走滑的年龄为146±2.8 Ma。综合两条剪切带的构造变形特征和年代学数据,结合前人的地质资料,本文认为二郎坪弧后盆地曾沿着瓦乔剪切带和朱夏剪切带发生双向式俯冲。     

五台山早前寒武纪碰撞造山带中的韧性剪切带及其大地构造意义

在五台山早前寒武纪碰撞造山带中存在两种类型韧性剪切带，即逆冲型和伸展型剪切带。除变质程度不同外，南部和北部构造片体中的角闪岩相逆冲型韧性剪切带与中部构造片体中的绿片岩相逆冲型韧性剪切带具有相同的变形特征，它们形成于同一变形过程中，是造山作用早期地壳拼合阶段的产物。伸展型韧性剪切带在整个造山带都有分布，与造山作用晚期显著增厚的地壳发生大规模纵向伸展作用相联系     

南阿尔金断裂的韧性剪切作用时代及其构造意义

位于阿尔金山腹地古元古界阿尔金群深变质岩系与中-新元古界浅变质岩系间的南阿尔金断裂,是1条以近于E-W走向,微向S高角度倾斜的大型逆冲断裂,它经历了韧性变形和脆性变形2个构造演化阶段.韧性剪切带的形成始于晚寒武世,强烈活动期为中奥陶世-志留纪(468.4～412.2Ma),早-中泥盆世、早石炭世、晚二叠世和早侏罗世时期,剪切带进入以高、中温为主的韧性变形期,随着时间推移,变形温度不断降低,剪切作用的强度明显减弱,早侏罗世后,南阿尔金断裂完全进入以脆性变形为主的构造演化阶段.南阿尔金断裂以北广泛分布的年龄区间为491.3 ±4.6～413.8±8.0Ma的钙碱性系列花岗岩和断裂南侧出露的时代为519±37～500±10Ma的榴辉岩和角闪糜棱岩,表明在发生极性向北的逆冲型韧性剪切作用前,沿南阿尔金断裂曾发生过自南而北的岩石圈尺度的俯冲作用.因此,南阿尔金断裂是阿尔金山腹地的1条重要的早古生代板块汇聚、碰撞带.     

Late Paleozoic–Mesozoic tectonic evolution of the Trans-Altai and South Gobi Zones in southern Mongolia based on structural and geochronological data

The Trans-Altai Zone in southern Mongolia is characterized by thrusting of greenschist-facies Silurian oceanic rocks over Devonian and Lower Carboniferous volcano-sedimentary sequences, by E–W directed folding affecting the early Carboniferous volcanic rocks, and by the development of N–S trending magmatic fabrics in the Devonian–Carboniferous arc plutons. This structural pattern is interpreted as the result of early Carboniferous thick-skinned E–W directed nappe stacking of oceanic crust associated with syn-compressional emplacement of a magmatic arc. The southernmost South Gobi Zone represents a Proterozoic continental domain affected by shallow crustal greenschist-facies detachments of Ordovician and Devonian cover sequences from the Proterozoic substratum, whereas supracrustal Carboniferous volcanic rocks and Permian sediments were folded into N–S upright folds. This structural pattern implies E–W directed thin-skinned tectonics operating from the late Carboniferous to the Permian, as demonstrated by K–Ar ages ranging from ~ 320 Ma to 257 Ma for clay fractions separated from a variety of rock types. Moreover, the geographical distribution of granitoids combined with their geochemistry and SHRIMP U–Pb zircon ages form distinct groups of Carboniferous and Permian age that record typical processes of magma generation and increase in crustal thickness. The field observations combined with clay ages, the geochemical characteristics of the granitoids and their ages imply that the E–W trending zone affected by tectonism migrated southwards, leaving the Trans Altai Zone inactive during the late Carboniferous and Permian, suggesting that the two units were tectonically amalgamated along a major E–W trending strike slip fault zone. This event was related to late Carboniferous subduction that was responsible for the vast volume of granitoid magma emplaced at 300–305 Ma in the South Gobi and at 307–308 Ma in the Trans-Altai Zones. The formation and growth of the crust was initially due only to subduction and accretion processes. During the post-collisional period from 305 to 290 Ma the addition of heat to the crust led to the generation of (per-) alkaline melts. Once amalgamated, these two different crustal domains were affected by N–S compression during the Triassic and early Jurassic (185–173 Ma), resulting in E–W refolding of early thrusts and folds and major shortening of both tectonic zones.     

The hercynian chain in Sardinia (Italy)

Abstract

A new geodynamic model for the Sardinian segment of the Hercynian chain is presented. The improvement of knowledge regarding several geological, metamorphic, magmatic and geochronological aspects of the Sardinian Palaeozoic basement, mainly achieved in the last few years, allows us to propose a more complete picture of its evolution.

The occurrence of remnants of an oceanic suture along a major tectonic lineament in northern Sardinia, as well as the products of Ordovician calc-alkaline magmatism, testifies to the presence, during the Lower Paleozoic, of an ancient (Precambrian- Cambrian) oceanic domain and its consumption along an Andean- type subduction zone. The following Carboniferous continental collision caused crustal stacking with Barrovian metamorphism and southward-migrating deformation from the suture zone toward the foreland.

Early Carboniferous Culm-type facies sediments, deposited in the outermost zone of the chain, imply that continental collision took place earlier in the internal zone, from Late Devonian or Early Carboniferous.

The collisional orogenic wedge experienced ductile extension during the Late Carhoniferous as a result of gravitational collapse of the thickened continental crust.

Extensional tectonism enhanced the uplift of the chain and some regions underwent tectonic denudation or LP/HT metamorphism and somewhere anatexis. The emplacement of calc-alkaline batholiths and the development of Late Carboniferous - Early Permian molasse basins occurred during extension that prolonged throughout the Permian.     

Late-Stage Ductile Deformation in Xiongdian-Suhe HP Metamorphic Unit, North-Western Dabie Shan, Central China

New structural and petrological data unveil a very complicated ductile deformation history of the Xiongdian-Suhe HP metamorphic unit, north-western Dabie Shun, central China. The finegrained symplectic amphibolite-facies assemblage and coronal structure enveloping eclogite-facies garnet,omphacite and phengite etc., representing strain-free decompression and retrogressive metamorphism,are considered as the main criteria to distinguish between the early-stage deformation under HP metamorphic conditions related to the continental deep subduction and collision, and the late-stage deformation under amphibolite to greenschist-facies conditions occurred in the post-eclogite exhumation processes.Two late-stages of widely developed, sequential ductile deformations D3 and D4, are recognized on the basis of penetrative fabrics and mineral aggregates in the Xiongdian-Suhe HP metamorphic unit, which shows clear, regionally, consistent overprinting relationships. D3 fabrics are best preserved in the Suhe tract of low post-D3 deformation intensity and characterized by steeply dipping layered mylonitic amphibolites associated with doubly vergent folds. They are attributed to a phase of tectonism linked to the initial exhumation of the HP rocks and involved crustal shortening with the development of upright structures and the widespread emplacement of garnet-bearing granites and felsic dikes. D4 structures are attributed to the main episode of ductile extension (D^24) with a gently dipping foliation to the north and common intrafolial, recumbent folds in the Xiongdian tract, followed by normal sense top-to-the northductile shearing (D^24) along an important tectonic boundary, the so-called Majiawa-Hexiwan fault (MHF), the westward continuation of the Balifan-Mozitan-Xiaotian fault (BMXF) of the northern Dabie Shan. It is indicated that the two stages of ductile deformation observed in the Xiongdian-Suhe HP metamorphic unit, reflecting the post-eclogite compressional or extrusion wedge formation, the subhorizontal ductile extension and crustal thinning as well as the top-to-the north shearing along the high-angle ductile shear zones responsible for exhumation of the HP unit as a coherent slab, are consistent with those recognized in the Dabie-Sulu UHP and HP metamorphic belts, suggesting that they were closely associated in time and space. The Xiongdian-Suhe HP metamorphic unit thus forms part of the Triassic(250-230 Ma) collision orogenic belt, and can not connect with the South Altun-North Qaidam-North Qinline UHP metamorphic belt formed durin~ the Early Paleozoic (500-400Ma).