钦-杭结合带在中生代构造转折事件以前的板块构造机制

钦州湾—杭州湾结合带是位于扬子与华夏两大古陆块中间的巨型构造结合带,在演化成西太平洋活动大陆边缘之前,经历了多期次的构造-岩浆事件。扬子和华夏板块于新元古代通过四堡造山运动(1 000~880 Ma)沿江山—绍兴断裂,经赣东北、湘中至钦州湾地区发生碰撞-拼合事件,拼合界线大致位于钦州湾—杭州湾结合带内,形成"两陆夹一盆"的主要格局。后碰撞过程经历了造山后岩浆活动和大陆拉张裂解两个过程,在结合带形成广阔的拉张盆地,加里东期(460~410 Ma)以及印支期(250~200 Ma)发生的碰撞-拼合事件导致扬子和华夏地块多次再造,引发强烈的构造-岩浆活动,并形成了华南统一的沉积环境。受西太平洋板块俯冲影响,华南地区中生代构造转折事件(125~140 Ma)使华南地区主要构造背景由碰撞挤压调整为岩石圈减薄,成为华南最重要的岩浆活动和成矿期。根据内部结构的不均一性和演化历史差异,钦州湾—杭州湾结合带可分为北段、中段和南段3段。其中,中段与传统南岭大体一致;北段为南岭以北地区,即绍兴—江山—萍乡一带;南段为南岭以南地区,大致与云开隆起—十万大山盆地相当。年代学和地球化学研究显示,在云开地块西缘的一系列变质基性岩、超基性岩和变质基性火山岩形成于新元古代洋中脊(MORB)或者岛弧(ITA)特征的构造环境,最近在岑溪一带发现形成于加里东期(441 Ma)的变质火山岩同样具有MORB型地球化学特征。在十万大山两侧发现早中生代的酸性火山岩和流纹岩具有典型岛弧型火山岩地球化学特征。可见结合带南段曾经存在古老洋壳,先后经历了新元古代、加里东期和印支期的碰撞造山事件,与北段演化历史具有一致性。     

赣北程浪断裂带的形成:程浪超基性岩墙群和星子花岗岩的地球化学证据

对侵位于彭庐地块东南边缘与程浪断裂带毗邻的前寒武纪花岗岩和出露于程浪深断裂带内的超基性岩墙群的微量元素地球化学特征进行了研究,结果表明前者属板内与岛弧环境的过渡类型,后者代表典型的火山岛弧环境。结合前人在区域构造和地质年代学的研究成果,认为晋宁运动时期,扬子板块东南缘散布着多个小型块体,在华夏板块向扬子板块方向的俯冲过程中,障公山地块先与彭庐地块沿程浪断裂带发生拼合,同时形成程浪超基性岩墙群;与此同时,彭庐地块内则表现为大规模的岩浆侵入作用。在各小型块体陆续发生碰撞后,扬子板块与华夏板块在晋宁运动晚期最终碰撞拼合,火山岛弧环境转换为造山带构造,因此,彭庐地块、障公山地块等火山岛弧均成为华南造山带的组成部分。     

钦-杭接合带之构造特征

华南大陆壳由扬子地块和华夏地块两个主要的地质构造单元组成,其间发育一条板块碰撞拼接带——钦-杭接合带,依据地层组成、构造变形差异,进一步划分为鄣公山构造混杂岩带、绍兴-江山对接带,前者叠加发育在扬子地块南部陆缘江南古岛弧之上,后者代表两地块间消减了的大洋及边缘海混杂体,经历了晋宁-加里东多期碰撞拼贴：晋宁期华夏陆块向扬子陆块俯冲、碰撞、走滑,形成了透镜-网结状韧性剪切系统争三期褶皱变形;加里东运动,华夏陆块再次与扬子陆块碰撞、仰冲,导致华南加里东造山带逆冲推覆在晋宁期造山带之上。至此,两者最终焊接成一体,形成了统一的晚古生代沉积盖层。     

南段新元古代俯冲作用:来自粤西贵子混杂岩变基性岩年代学和地球化学的证据

<正>钦—杭结合带(简称钦杭带)是位于华南扬子板块和华夏板块间的巨型结合带,记录了新元古代古华南洋板块俯冲-陆陆碰撞过程。根据其内部不均一性可分为北、中、南三段。新元古代早期,扬子板块和华夏板块沿江山—绍兴—萍乡断裂拼贴汇聚,留下了许多板块俯冲的证据。例如,钦杭带北段江山—绍兴断裂带、东乡—德兴断裂带分布的970~880 Ma蛇绿岩套,洋壳俯冲形成的0.9 Ga岛弧岩浆岩;中段桂北地区830 Ma岛弧性质基性-超基性岩墙。但对于南段,学者的认识并不一致。南段是否存在该时期的俯冲作用?     

扬子—华夏构造结合带的演化阶段及对斑岩铜矿形成的控制机制

扬子与华夏古板块均存在太古宙—中元古代古老基底,在构造演化历程中响应全球超大陆聚合-裂解过程,并最终碰撞拼贴形成钦-杭结合带,且经历构造运动之后,其总体演化格架为"两开三合一转折"。结合带内存在元古宙洋壳,以蛇绿岩套与镁铁质-超镁铁质岩石为特征,并以此推断结合带形成于新元古代。钦-杭结合带是斑岩成矿带,斑岩铜矿时空分布具有三段划分特征,且处于170~150 Ma和100 Ma左右两个成矿期。与成矿有关的斑岩主要为钙碱性岩浆系列的中酸性岩,岩石类型主要为花岗闪长斑岩、花岗斑岩和二长花岗斑岩等。钦-杭结合带燕山期的斑岩具岛弧岩浆作用特点,指示了华南地区中生代构造转折事件发生以前的地质演化及太平洋板块俯冲作用,即古俯冲带物质在中生代活化成矿。中侏罗世岩石圈减薄及太平洋板块俯冲的扰动导致上涌软流圈地幔带来大量的热量,这些热量加热上覆元古宙岛弧底部玄武质岩石导致它们发生重熔形成了含矿岩浆,本质上该类矿床带有岛弧俯冲环境的基因。而100 Ma左右斑岩铜矿的形成,则与太平洋俯冲换向所扰动有关。     

华南大陆东部若干构造问题的思考

华南大陆的结构、属性、过程与动力学一直是地质学家关注的热点。本文以钦杭构造带东段为主要研究地区,通过精细的构造解析、变质变形研究、年代学分析,结合反射地震剖面,探讨了华南大陆东部几个科学问题。（1）江南造山带形成于新元古代华夏板块与扬子板块的“软碰撞”作用,可划分为扬子板块南缘、扬子—华夏汇聚带和华夏板块北缘3个构造单元,江南断裂带和武夷山—遂昌断裂带分别为江南造山带的北界和南界。（2）扬子—华夏板块汇聚带由多个小板块拼合而成,其间有多条缝合带,大约900 Ma开始汇聚,760 Ma全面闭合,850~780 Ma为活动高峰期,具有递变式的汇聚拼合过程,由南向北发展,先斜向俯冲,后右旋走滑,最晚集中在中部活动。（3）华南大陆东部为中生代奠定的构造格架,主要构造为一系列北东走向褶皱和逆冲断层,大量地壳范围内的叠瓦状逆冲推覆构造,由南向北逆冲,可下切到中—下地壳。（4）华南大陆燕山晚期区域性伸展构造广泛发育,存在“华南热隆”构造,震旦系内的滑覆构造典型,同期大规模岩浆活动、火山活动和大规模的热液成矿。（5）华南大陆构造演化为：850 Ma扬子—华夏板块递进式汇聚,760 Ma全面拼合,江南造山带形成;600 Ma华南大陆盖层发育;430 Ma钦杭构造带受南部构造影响;220 Ma钦杭构造带受北部远程构造影响;160 Ma逆冲推覆构造产生;140 Ma大规模伸展,构造-岩浆-成矿关系密切;随后江南持续隆升,华南强烈热隆。     

中国钼矿床的时空分布及成矿背景分析

我国钼资源十分丰富,目前已发现钼矿床四百余个,它们具有成带分布的特点。本文在钼矿床地质特征基础上,系统总结了钼矿床和含钼矿床的成矿年代(依据辉钼矿Re-Os年龄),结果显示我国钼矿床空间上可分为东秦岭-大别、兴-蒙、长江中下游、华南、青藏和天山-北山六大钼成矿带;成矿时代上,钼成矿作用分为古元古代(1882~1804Ma)、早古生代(480~420Ma)、晚古生代(412~260Ma)、中生代印支期(251~209Ma)、中生代燕山期(194~77Ma)和新生代(65~13Ma)等六个阶段,主要集中于中生代和新生代。元古宙形成的钼矿床分布于东秦岭-大别钼成矿带,古生代钼矿床主要分布于天山-北山钼成矿带,中生代钼矿床在中国东部广泛分布,新生代钼矿床全都分布于青藏钼成矿带。我国古元古代钼矿床(1882~1804Ma)形成于古陆块之间俯冲碰撞背景下的岛弧环境(东秦岭-大别);早古生代钼矿床(480~420Ma)形成于不同构造单元由挤压向伸展转换的岛弧或陆缘弧环境(东秦岭-大别、兴-蒙和华南);晚古生代钼矿床(412~260Ma)形成于古亚洲洋壳俯冲的岛弧环境(兴-蒙);中生代印支期钼矿床(251~209Ma)形成于板块碰撞及后碰撞背景(东秦岭-大别、兴-蒙和天山-北山)或洋壳俯冲的背景(青藏);燕山期钼矿床形成于古太平洋板块俯冲转向及其后伸展体制下岩石圈减薄拆沉环境(东秦岭-大别、兴-蒙、长江中下游和华南),燕山晚期钼矿床(85~77Ma)形成于碰撞后的伸展背景(青藏);新生代(65~13Ma)钼矿床形成于印度板块与欧亚板块陆陆碰撞及其后的伸展背景(青藏)。我国钼成矿作用受到了环太平洋构造带(东秦岭-大别、兴-蒙、长江中下游和华南)、中亚造山带(天山-北山、兴-蒙)和特提斯构造带(青藏)三大构造体制的影响。     

江南古陆东南缘晚元古代大陆增生史

根据赣东北蛇绿岩和皖南伏川蛇绿岩最新的Sm-Nd等时线年龄1034Ma和935Ma与晚元古代初期火山岩下面及震旦系下面的2个不整合面;根据侵入皖南上溪群的休宁岩体的Rb-Sr全岩等时线年龄963Ma和赣东北-浙西北晚元古代钙碱性火山岩带的存在,等等,作者认为:江南古陆东南缘为一古岛弧,约1000Ma前华南洋壳沿德兴-杭州一带俯冲,是岛弧向江南古陆增生的开始,而800Ma前华夏古陆沿江山-绍兴一带与江南古陆拼合,则标志着增生的完成。     

川西甲基卡地区侏倭组沉积物源分析—来自碎屑锆石U- Pb年龄证据

松潘- 甘孜造山带是青藏高原东北部的重要组成单元,是华北板块、扬子板块和羌塘块体的主要汇聚地区,主要由中生代浅变质沉积地层和一系列岩浆岩组成,记录了印支期以来块体之间的收敛汇聚等构造活动。其中,雅江残余盆地发育一套厚度巨大的中生代碎屑岩和岩浆岩地层组合,是研究松潘- 甘孜造山带地质构造演化的理想地区之一。本文对川西甲基卡地区侏倭组的样品进行了碎屑锆石LA- ICP- MS U- Pb年龄测试,碎屑锆石U- Pb年龄存在四个峰值,分别为231~281Ma、424~502Ma、707~983Ma、1539~1850Ma,表明扬子克拉通西缘及松潘甘孜造山带南部至少经历了四期强烈的构造—岩浆热事件,这四期事件在三叠系沉积地层中有非常清楚的记录。231~281Ma的锆石来自东昆仑,这一年龄段的锆石最可能来自北部晚二叠世松潘洋向北俯冲于华北板块之下所形成的东昆仑岛弧花岗岩。424~502Ma的锆石来自北秦岭,代表了加里东期南秦岭与北秦岭和华北板块的拼合事件。722~983Ma的锆石来自扬子板块,这一年龄段的锆石最可能来自盆地东部新元古界拉伸系上扬子克拉通盆地向北西俯冲于华北板块之下所形成的南秦岭花岗岩,形成于扬子板块晋宁期陆壳增生事件。1539~1850Ma与华北板块基底年龄特征值正相对应,是吕梁期华北克拉通东西两大块体在中部发生碰撞,华北古陆进一步固结、扩大的时间,这其中包含了继承东西块体的太古宙物质和新生的火成岩和沉积岩,在中- 晚三叠世,随着秦岭洋的关闭和碰撞造山,将大量碎屑物质经华北板块南缘东西向的疏导体系注入松潘甘孜盆地。说明松潘甘孜三叠纪复理石盆地侏倭组主要接受来自东昆仑、华北板块和秦岭造山带的物质。最年轻碎屑锆石可以限定沉积岩的最大沉积年龄,侏倭组4颗年轻碎屑锆石加权平均计算得出241. 8±4. 5Ma（n=4）,推测侏倭组沉积年龄介于231. 6~249. 9Ma之间。     

东天山花岗岩与造山带演化

文章通过建立花岗岩类类型与地球动力学之间的联系,试图利用分类清楚、测年准确的花岗岩解决本区地壳及造山带演化过程。根据K2O等地壳成熟度的指标,得出了该地区地壳性质由不成熟→半成熟岛弧→成熟陆壳演变;构造环境由不成熟岛弧→成熟的"大陆化"岛弧→大陆碰撞带演化。总结了东天山地区经历了三大地壳演化时期,分别为前寒武纪基底演化阶段陆核及超大陆形成期;古生代古亚洲洋形成演化期和中生代特提斯―印欧板块碰撞阶段板内演化期。反演出了东天山造山带经历了俯冲汇聚及不成熟陆壳形成阶段→弧―陆碰撞及半成熟陆壳形成阶段→碰撞造山及成熟陆壳形成阶段→陆内造山及陆壳改造阶段→中生代板内演化阶段。     

华南在Rodinia古陆中位置的讨论——扬子地块西缘变质-岩浆杂岩证据及其与Seychelles地块的对比

沿扬子地块西缘出露的一系列变质杂岩的构造性质及形成时代是分析华南地块大地构造属性的关键。这些杂岩均被初始为低角度的正断层所围限 ,具有变质核杂岩的构造性质 ,其剥露时间在177Ma左右。目前 ,对这一区域几个代表性杂岩体进行的系统的岩石学和地球化学分析表明 ,这是一套主体为与俯冲板块有关的岛弧型岩浆杂岩 ,其形成时代从 72 6～ 86 4Ma ,时间跨度在 10 0Ma以上。证明这些岩石的形成与地幔柱作用无关。上述结果与最近在Madagascar东北缘、Seychelles岛及印度的Malani的一条类似的变质岩浆杂岩带的地球化学与地质年代学研究结果完全吻合 ,这个构造带被解释为一条沿Mozambique洋东缘的巨大的向东俯冲的安第斯型俯冲 岩浆岛弧带。据此我们推测在Rodinia古大陆中 ,华南地块位于印度板块东北缘 ,其南东则可能与澳大利亚相接。     

Geochronology and Tectonic Evolution of the West Section of the Jiangnan Orogenic Belt

As an important part of South China Old Land, the Jiangnan Orogenic Belt plays a significant role in explaining the assembly and the evolution of the Upper Yangtze Block and Cathaysia, as well as the structure and growth mechanism of continental lithosphere in South China.The Lengjiaxi and the Banxi groups are the base strata of the west section of the Jiangnan Orogenic Belt.Thus, the research of geochronology and tectonic evolution of the Lengjiaxi and the Banxi groups is significant.The maximum sedimentary age of the Lengjiaxi Group is ca.862 Ma, and the minimum is ca.822 Ma.The Zhangjiawan Formation, which is situated in the upper part of the Banxi Group is ca.802 Ma.The Lengjiaxi Group and equivalent strata should thus belong to the Neoproterozoic in age.The Jiangnan Orogenic Belt consisting of the Lengjiaxi and the Banxi groups as important constituents is not a Greenville Orogen Belt(1.3 Ga–1.0 Ga).The Jiangnan Orogenic Belt is a recyclic orogenic belt, and the prototype basin is a foreland basin with materials derived from the southwest and the sediments belong to the active continental sedimentation.By combining large amounts of dating data of the Lengjiaxi and the Banxi groups as well as equivalent strata, the evolutionary model of the western section of the Jiangnan Orogenic Belt is established as follows: Before 862 Ma, the South China Ocean was subducted beneath the Upper Yangtze Block, while a continental island arc was formed on the side near the Upper Yangtze Block.The South China Ocean was not closed in this period.From 862 Ma to 822 Ma, the Upper Yangtze Block was collided with Cathaysia; and sediments began to be deposited in the foreland basin between the two blocks.The Lengjiaxi Group and equivalent strata were thus formed and the materials might be derived from the recyclic orogenic belt.From 822 Ma to 802 Ma, Cathaysia continued pushing to the Upper Yangtze Block, experienced the Jinning-Sibao Movement(Wuling Movement); as result, the folded basement of the Jiangnan Orogenic Belt was formed.After 802 Ma, Cathaysia and the Upper Yangtze Block were separated from each other, the Nanhua rift basin was formed and began to receive the sediments of the Banxi Group and equivalent strata.These large amounts of dating data and research results also indicate that before the collision of the Upper Yangtze Block with Cathaysia, materials of the continental crust became less and less from the southwest to the east in the Jiangnan Orogeneic Belt; only island arc and neomagmatic arc were developed in the eastern section.Ocean-continent subduction or continent-continent subduction took place in the western and southern sections, while intra-oceanic subduction occurred in the eastern section.Comprehensive analyses on U-Pb ages and Hf model ages of zircons, the main provenance of the Lengjiaxi Group is Cathaysia.     

大别山超高压变质带的构造背景

大别山南部的超高压变质带具有特征的榴辉岩相矿物组合，榴辉岩的岩石化学及稀土元素特征及其伴生的岩石组合，表明这个带是以陆壳成分为主混有少量上地幔及洋壳成分的混杂岩，榴辉岩相围岩和大别群具有不同的变质和变形特征。超高压变质带形成于扬子和中朝板块大陆碰撞的构造环境，是扬子板块陆壳向北俯冲到一定深度的变质产物。     

秦岭的大地构造演化

一项中瑞合作研究成果表明,中国秦岭属碰撞型造山带。秦岭是在中生代造山运动早期由华北大陆板块与扬子大陆板块碰撞而成。原存于两大板块之间的古特提斯洋在泥盆纪时即已开始消减,仅部分洋壳残余于碰撞混杂岩中。     

TECTONICS OF THE DABIE OROGENIC BELT, CENTRAL CHINA

Tectonically the Dabie orogenic belt consists mainly of the Dabieshan Yanshanian uplifted zone and the Beihuaiyang Variscan-Indosinian folding zone. In the north boundary adjoining the North China Block, there are an Early Palaeozoic ophiolitic mixtite belt and the Hefei Mesozoic-Cenozoic faulted basin which overlaps on the suture belt. In the south of Dabie orogen, there is a secondary tectonic unit called Foreland thrust-faulted structural zone which was mainly formed by the intracontinental subductions during Mesozoic era. The study shows that the Dabie Block is a part of mid-late Proterozoic palaeo-island arc at the north margin of Yangtze Block. During Caledonian period, as a submerged uplift at the northen continental margin of Yangtze Block, the Dabie Block collided with the early Palaeozoic palaeo-island arc at the south margin of North China Block, resulting in the convergence of the North and South China Blocks and the disappearance of oceanic crust. Since then,large-scale intracontinental subductions were followed. Dabie Orogenic Belt is the product of overlapping of Yangtze Block, Dabie Block and North China Block under the mechanism of intracontinental subduction. Indosinian period is the period of chief deformation and high pressure dynamic metamorphism for Dabie Block, and Yanshan period is the main orogenic period in which the remelting of crust caused by basement shearing resulted in large scale thermometamorphism. The present tectonic framework of the orogen was finally formed by the rapid uplifting of the Dabieshan mountains and gliding southwards, which result in the developing of thrust belt on south side and the extensional tectonic movement on north side.     

TECTONICS OF THE DABIE OROGENIC BELT, CENTRAL CHINA

Tectonically the Dabie orogenic belt consists mainly of the Dabieshan Yanshanian uplifted zone and the Beihuaiyang Variscan-Indosinian folding zone. In the north boundary adjoining the North China Block, there are an Early Palaeozoic ophiolitic mixtite belt and the Hefei Mesozoic-Cenozoic faulted basin which overlaps on the suture belt. In the south of Dabie orogen, there is a secondary tectonic unit called Foreland thrust-faulted structural zone which was mainly formed by the intracontinental subductions during Mesozoic era. The study shows that the Dabie Block is a part of mid-late Proterozoic palaeo-island arc at the north margin of Yangtze Block. During Caledonian period, as a submerged uplift at the northen continental margin of Yangtze Block, the Dabie Block collided with the early Palaeozoic palaeo-island arc at the south margin of North China Block, resulting in the convergence of the North and South China Blocks and the disappearance of oceanic crust. Since then,large-scale intracontinental subductions were followed. Dabie Orogenic Belt is the product of overlapping of Yangtze Block, Dabie Block and North China Block under the mechanism of intracontinental subduction. Indosinian period is the period of chief deformation and high pressure dynamic metamorphism for Dabie Block, and Yanshan period is the main orogenic period in which the remelting of crust caused by basement shearing resulted in large scale thermometamorphism. The present tectonic framework of the orogen was finally formed by the rapid uplifting of the Dabieshan mountains and gliding southwards, which result in the developing of thrust belt on south side and the extensional tectonic movement on north side.     

Geology and tectonics of Japanese islands: A review – The key to understanding the geology of Asia

The age of the major geological units in Japan ranges from Cambrian to Quaternary. Precambrian basement is, however, expected, as the provenance of by detrital clasts of conglomerate, detrital zircons of metamorphic and sedimentary rocks, and as metamorphic rocks intruded by 500 Ma granites. Although rocks of Paleozoic age are not widely distributed, rocks and formations of late Mesozoic to Cenozoic can be found easily throughout Japan. Rocks of Jurassic age occur mainly in the Jurassic accretionary complexes, which comprise the backbone of the Japanese archipelago. The western part of Japan is composed mainly of Cretaceous to Paleogene felsic volcanic and plutonic rocks and accretionary complexes. The eastern part of the country is covered extensively by Neogene sedimentary and volcanic rocks. During the Quaternary, volcanoes erupted in various parts of Japan, and alluvial plains were formed along the coastlines of the Japanese Islands. These geological units are divided by age and origin: i.e. Paleozoic continental margin; Paleozoic island arc; Paleozoic accretionary complexes; Mesozoic to Paleogene accretionary complexes and Cenozoic island arcs. These are further subdivided into the following tectonic units, e.g. Hida; Oki; Unazuki; Hida Gaien; Higo; Hitachi; Kurosegawa; South Kitakami; Nagato-Renge; Nedamo; Akiyoshi; Ultra-Tamba; Suo; Maizuru; Mino-Tamba; Chichibu; Chizu; Ryoke; Sanbagawa and Shimanto belts.The geological history of Japan commenced with the breakup of the Rodinia super continent, at about 750 Ma. At about 500 Ma, the Paleo-Pacific oceanic plate began to be subducted beneath the continental margin of the South China Block. Since then, Proto-Japan has been located on the convergent margin of East Asia for about 500 Ma. In this tectonic setting, the most significant tectonic events recorded in the geology of Japan are subduction–accretion, paired metamorphism, arc volcanism, back-arc spreading and arc–arc collision. The major accretionary complexes in the Japanese Islands are of Permian, Jurassic and Cretaceous–Paleogene age. These accretionary complexes became altered locally to low-temperature and high-pressure metamorphic, or high-temperature and low-pressure metamorphic rocks. Medium-pressure metamorphic rocks are limited to the Unazuki and Higo belts. Major plutonism occurred in Paleozoic, Mesozoic and Cenozoic time. Early Paleozoic Cambrian igneous activity is recorded as granites in the South Kitakami Belt. Late Paleozoic igneous activity is recognized in the Hida Belt. During Cretaceous to Paleogene time, extensive igneous activity occurred in Japan. The youngest granite in Japan is the Takidani Granite intruded at about 1–2 Ma. During Cenozoic time, the most important geologic events are back-arc opening and arc–arc collision. The major back-arc basins are the Sea of Japan and the Shikoku and Chishima basins. Arc–arc collision occurred between the Honshu and Izu-Bonin arcs, and the Honshu and Chishima arcs.     

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。     

中国东南部晚中生代火成岩的基底探讨

根据浙闽赣粤地区出露的中深变质岩石构造组合,构造形迹和近年报道的同位素测年数据认为,中国东南部晚中生代火成岩之下存在一个前泥盆纪的变质基底,其中,前震旦纪的变质基底以呈面形分布的片岩,片麻岩及混合岩为特征,年龄值大于8亿年,是构成华南地区最古老的陆壳基底之一,俗称华厦古陆,9亿年左右,该陆块和扬子陆块碰撞,其缝合带为强兴－江山－东乡－萍乡断裂带,稍后,受区域拉张构造事件的影响,它被裂解为三个走向各异,分布在浙东南－闽西北,赣中－赣南和云开三个地区的块体,分别呈NEE,NNE和NE方向展布,三者之间为巨厚的震旦纪一早古生代沉积物质所充填,并有复式岩浆岩流出现,研究表明,中国东南部晚中生代火成岩的基底构造至少经历过三期构造一热事件的演化,这种古构造格局,制约了中国东南部中生代大规模构造－岩浆活动,岩浆成分差异及其空间展布。     

安徽的地壳演化:Sr,Nd同位素证据

在地壳(幔)演化和板块构遣的框架内，评述了有关安徽南部(扬子地块东部，包括大别遣山带和江南遣山带)的同位素地质年代学和Nd，Sr同位素地球化学示踪研究的成果。该地区出露地表的中元古界溪口群浅变质岩代表皖南的基底，沿江地区和大别山区的基底包舍太古宇或／和古元古界古老岩石。此格局还影响到从震旦纪到古生代沉积岩的物源区，江南深断裂以北的沉积岩中有古老岩石的贡献，而以南的物源主要来自出露的中元古界岩石。扬子陆块南北缘(大别和江南遣山带)的晋宁期演化可能与罗迪尼亚超大陆演化有密切关系，但有关研究开展很少。三叠纪大陆深俯冲和超高压变质作用研究已成为国际地球科学的热点。晚中生代(120-140Ma)本区发生强烈的岩浆活动，并伴有重要矿床的形成。中酸性岩的形成是一种壳幔物质混合的过程。沿江地区陆下地幔具有富集特征，为扬子型岩石圈地幔与软流圈地幔混合的产物。从晚中生代到第四纪，基性岩指示其源区的地球化学性质有随时间变得越来越亏损的趋势。