南极洲主要矿产资源

南极洲蕴藏着丰富的矿产，但目前还研究得很不够。本文主要介绍了东南极南查尔斯王子山脉和恩德比地前寒武纪铁矿、毛德王后地不同时代的脉状铁矿及云母、石墨、绿柱石、水晶等非金属矿产。横贯南极山脉的Ｕ矿化、彭萨科拉山的杜费克杂岩体的Ｆｅ，Ｔｉ，铂族金属及ＣＵ，Ｎｉ等矿化、西南极包括南极半岛地区在内中─新生代的Ｃｕ矿化都是有潜力的矿产资源。横贯南极山脉地区的二叠纪煤系分布很广。南极洲的石油与天然气以威德尔海及罗斯海最有潜力。     

南极地质演化及其与冈瓦纳古陆裂解有有关问题

南极大陆位于地球南端。地层自太主界至新生界均有出露，岩浆活动各个时代亦均有发育。南极基底是由前寒武系和寒武－奥陶系构成的双构造层基底；盖层由泥盆系三叠系组成，其中石炭纪末至二叠纪初的冰碛层对研究冈瓦纳古陆的演化具有极为重要的意义。冈瓦纳古陆的裂解，即东冈瓦纳（南极－印度－澳大利亚）与西冈瓦纳（南美－非洲）是在约１５０Ｍａ之前分开的。１３０Ｍａ之前，南大西洋的打开又把西冈瓦纳分割成两块，并导致Ｅｌｌｓｗｏｒｔｈ山与南极半岛及Ｔｈｕｒｓｔｏｎ岛相连形成威德尔古陆。     

南极洲的前寒武系

南极洲按地形特征和地质构造可分成东南极和西南极两大部分。东南极是一个前寒武纪克拉通地盾,一侧以横贯南极山的年轻造山带为界,其地壳厚度超过401里,在横贯南极山的克拉通一侧的地表由切割的断块高原所组成。西南极则由较年轻的陆壳地块组成,厚30公里以上,以深海槽为界。前寒武纪地盾陆地边界——东南极巨大块体推测下伏有前寒武纪变质岩类,根据冰碛砾石推断,该变质岩呈锒边状出露于西经15°和东经145°之间的陆地上。岩石变质程度主要为麻粒岩相,表明属高温并相对无水条件下形成,还见到有一些紫苏花岗岩体散布于整个周边地区。     

拉斯曼丘陵新生代剥露作用的裂变径迹证据

在西南极和横贯南极山脉地区,新生代裂谷和剥露作用非常普遍。但是,文献中很少记录东南极地区的新生代剥露作用。文中根据东南极普里兹湾拉斯曼丘陵地质样品的磷灰石裂变径迹年龄和热历史的模拟,认为在东南极海岸边缘存在新生代的隆升和伸展作用,其年龄为始于(49.8±12)Ma。该年龄略晚于西南极裂谷系的启动年龄(约60~50Ma)。由于差异隆升作用,在拉斯曼丘陵地区发育了更新的正断层作用--拉斯曼丘陵拆离断层的新活动,其年龄为约5.4Ma。东南极周缘新生代裂谷和伸展作用的普遍存在,是冈瓦纳裂解以来大陆分离和印度洋形成的结果。     

拉斯曼丘陵新生代剥露作用的裂变径迹证据

在西南极和横贯南极山脉地区,新生代裂谷和剥露作用非常普遍。但是,文献中很少记录东南极地区的新生代剥露作用。文中根据东南极普里兹湾拉斯曼丘陵地质样品的磷灰石裂变径迹年龄和热历史的模拟,认为在东南极海岸边缘存在新生代的隆升和伸展作用,其年龄为始于(49.8±12)Ma。该年龄略晚于西南极裂谷系的启动年龄(约60~50Ma)。由于差异隆升作用,在拉斯曼丘陵地区发育了更新的正断层作用——拉斯曼丘陵拆离断层的新活动,其年龄为约5.4Ma。东南极周缘新生代裂谷和伸展作用的普遍存在,是冈瓦纳裂解以来大陆分离和印度洋形成的结果。     

华夏地块:一个由古老物质组成的年轻陆块

对华夏地块三个主要前寒武纪地质体出露区变质岩的详细锆石年代学的综合分析显示,华夏地块大致可以被分成武夷山区和南岭-云开区。武夷山区由古元古代核和新元古代（形成于730-820 Ma）的盖层组成,构成华夏地块最老的古陆,在其深部很可能还存在一个新太古代基底。新元古代的沉积物主要来自武夷微古陆本身。南岭与云开具有相似的前寒武纪地壳组成,它们主要是由新元古代形成的沉积物夹少量火山岩组成。这些沉积物质中包含了非常古老的中太古代和新太古代组分,甚至古太古代组成。Grenville期和中元古代组分是其中最丰富的。这些组分在华夏没有对应出露的岩石,说明它们主要来自另外一个曾经与华夏相邻的陆块。该陆块很可能是东印度－东南极大陆。南岭－云开区最初可能是Rodinia超大陆裂解时形成的一个裂谷盆地,加里东的造山运动使盆地中的沉积物挤压、褶皱和隆起,与武夷陆块共同构成了一个新的年轻的大陆     

东南极晚新元古—早古生代构造热事件及其在冈瓦纳超大陆重建中的意义

在东南极大陆内部及边缘发育3条晚新元古代—早古生代造山带,即东非造山带（南延部分）、普里兹造山带和罗斯造山带。东非造山带的南延部分主要出露于吕措—霍尔姆湾—毛德王后地—沙克尔顿岭地区,其内发育蛇绿岩、榴辉岩相超镁铁岩及逆冲—推覆构造,因而被解释为东、西冈瓦纳陆块拼合的缝合线。罗斯造山带主要出露于横贯南极山脉地区,其内保存有大陆裂解、洋壳俯冲和地体增生的地质纪录,代表冈瓦纳超大陆的活动大陆边缘。普里兹造山带主要出露于普里兹湾和登曼冰川,因其位于从前假设的统一东冈瓦纳陆块的内部,加之缺少蛇绿混杂岩、岛弧增生杂岩和高压变质岩（如蓝片岩或榴辉岩）等与大洋板块俯冲作用密切相关的岩石,所以当前存在着碰撞造山成因和板内改造成因两种不同的认识。普里兹造山带构造性质的确定不仅决定了冈瓦纳超大陆的汇聚过程和方式,也制约了罗迪尼亚超大陆的形成和演化过程。因此,开展普里兹造山带的研究对于揭示新元古代—早古生代的全球构造演化具有重要的科学意义。     

东南极普里兹带多期变质作用及其对罗迪尼亚和冈瓦纳超大陆重建的启示

东南极普里兹带是一条经受格林维尔期和泛非期高级构造热事件影响的多相变质带,其构造演化过程与罗迪尼亚和冈瓦纳超大陆的形成密切相关.新的岩石学和年代学资料表明,普里兹带中的格林维尔期高级变质作用是区域性的,并经历了>970Ma和930～900Ma两个演化阶段(期),变质条件达到相对高温高压的麻粒岩相.格林维尔期造山作用起始于活动大陆边缘或岛弧环境下的岩浆增生,最后发展到陆陆碰撞,从而使印度、东南极西陆块和非洲的卡拉哈里克拉通拼合在一起,构成了罗迪尼亚超大陆的重要组成部分之一.普里兹带中的泛非期高级变质作用并不象前人认为的那样只发生在中低压麻粒岩相条件下,而是达到高压麻粒岩相,并具有近等温减压的顺时针P-T演化轨迹.格林维尔期变质先驱的普遍存在说明泛非期碰撞造山事件主要叠加在印度-南极陆块东缘的基底杂岩之上,所以其主缝合线的位置应该在现今普里兹带的东南方向,并可能向南极内陆延伸到甘布尔采夫冰下山脉.对不同类型岩石的精细定年揭示,普里兹带中泛非期造山作用过程从570Ma一直持续到490Ma,这与东非造山带的晚期碰撞阶段大致相吻合.因此,冈瓦纳超大陆的最后拼合可能是通过西冈瓦纳、印度-南极陆块和澳大利亚-南极陆块等三个陆块的近于同期碰撞来完成的.     

藏北羌塘盆地构造特征及演化

羌塘盆地基底由元古宙变质岩系组成，具双层结构，下部为结晶“硬基底”、上部为变质“软基底”；构造上具两坳夹－隆和断凸断凹特征。盆地盖层由中泥盆统至第三系组成，主要为海相碳酸盐岩和碎屑屑岩及白垩系、第三系陆相砂、砾岩。盖层中变形强烈，发育多组褶皱、断裂。在变形在平面上方向性、分带性、等距性明显；在剖面上具差异性、不协调性。盆地主要变形期为燕山期－喜马拉雅期。     

南极普里兹造山带性质及构造变形过程

南极大陆足世界上最古老的大陆之一,是冈瓦纳大陆的重要组成.第一次南极科学考察以来,中国地质科学院一直参加南极研究.目前为止,已有33人次参加了14次南极考察,其中2人进入南极内陆格罗夫山考察.经过几代科学家20多年的努力,取得了一系列成果.传统观点认为,东南极大陆是由太古宙陆核与围绕陆核的元古宙活动带组成,东冈瓦纳大陆在晚元古代格林威尔事件后完成统一大陆的构建.上世纪90年代初,在原属于环东南极格林维尔活动带的不同部位识别出-系列晚新元占-早古生代的泛非期(约500 Ma)构造热事件,对传统的东南极大陆模式提出了挑战.其中,普里兹湾地区泛非构造热事件在最近几年的研究中被中国科学家证明向南延伸到南极内陆的格罗夫山一带,在东南极大陆内部形成了一条泛非期构造带.然而,普里兹带的构造属性一直受到研究者的争论.人们关注的焦点是这条泛非期普里兹构造带到底是一条陆内变形带?还是板块碰撞带?因为这个问题直接关系到东南极大陆的结构与形成时代,更关系到东冈瓦纳大陆形成演化过程的重建.2007年,"南极普里兹带1:50万地质图编制"与"南极埃默里冰架-格罗夫山综合地质调查与研究"课题组对普里兹带研究取得了重要进展:①完成了我国在南极的第一张中比例尺地质图,为普里兹构造带的研究、为探讨冈瓦纳大陆的重建,奠定了新的基础;②格罗夫山地区首次发现高压麻粒岩,根据石榴子石的化学环带和单斜辉石原始成分的恢复获得峰期变质条件为12.9～15.8 kb、810～910℃,减压退变质条件为7.6～10.3 kb、700～760℃,具有顺时针演化的P-T轨迹.SHRIMP锆石U-Pb定年揭示高压变质作用发牛的时代为545～542 Ma.这项成果首次为确认普里兹构造带为碰撞造山带提供了直接的岩石学证据;③普哩兹构造带麻粒岩地体变质作用、花岗岩浆侵位构成的热事件经历了ITD IBC发展轨迹,也是大陆碰撞带的指示标志;④基本上确定了普里兹构造带构造格架与变形序列及演化过程;⑤发现格罗夫山地区大型低角度韧性剪切变形带,变形时代为.530～480 Ma;⑥格罗夫山地区NENNE向延伸的沟谷-纵岭地貌特征是由于晚中生代到新生代区域上蓝伯特裂谷发育过程中形成的.     

Provenance of LGM glacial till (sand fraction) across the Ross embayment,Antarctica

The provenance of Late Quaternary Ross Embayment till was investigated by comparing the coarse sand composition of East and West Antarctic source area tills with till samples from across the Ross Sea. The West Antarctic samples from beneath the Whillans (B) and Kamb (C) ice streams are petrologically distinct from samples of lateral moraines flanking several East Antarctic outlet glaciers. The characteristic assemblage of four West Antarctic samples includes felsic intrusive and detrital sedimentary lithic fragments, plagioclase and abundant quartz. In contrast, most of the ten East Antarctic till samples contains abundant mafic intrusive and detrital sedimentary lithic fragments as well as less abundant quartz. The distinctive composition of these source areas can be linked to 33 samples from 20 cores of Last Glacial Maximum (LGM) age till distributed across the Ross Sea. Western Ross Sea till samples exhibit mineralogic and lithological similarities to East Antarctic till samples, although these western Ross Sea tills contain higher percentages of felsic intrusive and extrusive lithic fragments. Eastern Ross Sea till samples are compositionally similar to West Antarctic till, particularly in their abundance of quartz and dearth of mafic and extrusive lithic components. Central Ross Sea till exhibits compositional similarities to both East and West Antarctic source terranes including a mafic lithic component, and marks the confluence of ice draining from East and West Antarctica during the LGM, thus West Antarctic-derived ice streams did not advance into the western Ross Sea. This indicates that even if pre-LGM equivalents of the present Siple Coast ice streams existed, they did not simply expand allowing West Antarctic-derived ice to dominate the LGM Ross Ice Sheet.     

Cenozoic Exhumation of Larsemann Hills,East Antarctica: Evidence from Apatite Fission-track Thermochronology

<正>Does Cenozoic exhumation occur in the Larsemann Hills,East Antarctica? In the present paper,we conducted an apatite fission-track thermochronologic study across the Larsemann Hills of East Antarctica.Our work reveals a Cenozoic exhumation event at 49.8±12 Ma,which we interpret to be a result of exhumation caused by crustal extension.Within the uncertainty of our age determination, the timing of extension in East Antarctica determined by our study is coeval with the onset time of rifting in West Antarctica at c.55 Ma.The apatite fission-track cooling ages vary systematically in space, indicating a coherent block rotation of the Larsemann Hills region from c.50 Ma to c.10 Ma.This pattern of block tilting was locally disrupted by normal faulting along the Larsemann Hills detachment fault at c.5.4 Ma.The regional extension in the Larsemann Hills,East Antarctica was the result of tectonic evolution in this area,and may be related to the global extension.Through the discussion of Pan-Gondwanaland movement,and Mesozoic and Cenozoic extensions in West and East Antarctica and adjacent areas,we suggest that the protracted Cenozoic cooling over the Larsemann Hills area was caused by extensional tectonics related to separation and formation of the India Ocean at the time of Gondwanaland breakup.     

Nature and significance of the late Mesozoic granitoids in the southern Great Xing’an range,eastern Central Asian Orogenic Belt

ABSTRACT

Abundant late Mesozoic granitic rocks are widespread in the southern Great Xing’an Range (GXAR), which have attracted much attention due to its significance for the Mesozoic tectonic evolution in the eastern Central Asian Orogenic Belt. However, controversy has still surrounded the late Mesozoic geodynamic switching in the continental margin of east China, especially the spatial and temporal extent of the influence of the Mongol-Okhotsk and Palaeo-Pacific tectonic regimes. In order to better understand the Late Mesozoic evolutionary history of the southern GXAR, a number of geochemical, geochronological, and isotopic data of the granitoids in this region are collected. Magmatism in the southern GXAR can be divided into six phases: Late Carboniferous (325–303 Ma), Early-Middle Permian (287–260 Ma), Triassic (252–220 Ma), Early Jurassic (182–176 Ma), Late Jurassic (154–146 Ma), and Early Cretaceous (145–111 Ma). Mesozoic magmatic activities in the southern GXAR peaked during the Late Jurassic to Early Cretaceous, accompanied by large-scale mineralization. Sr–Nd–Hf isotopic evidence of these granitic rocks suggested they were likely originated from a mixed source composed of lower crust and newly underplated basaltic crust. Assimilation-fractional crystallization (AFC) or crustal contamination possibly occurred in the magma evolution, and a much more addition of juvenile component to the source of the Early Cretaceous granitoids than that of Late Jurassic. The closure of Mongol-Okhotsk ocean and the break-off of the Mongol-Okhotsk oceanic slab at depth in the Jurassic triggered extensive magmatism and related mineralization in this region. The Jurassic intrusive activities was affected by both the subduction of the Palaeo-Pacific plate and the closure of Mongol-Okhotsk ocean. Less influence of the Mongol-Okhotsk tectonic regime on the Early Cretaceous magmatism, whereas, in contrast the Palaeo-Pacific tectonic regime possibly continued into the Cenozoic.     

华南晚中生代陆弧迁移与海域盆地演化

陆弧和弧前盆地是俯冲体系中具有密切联系的构造单元。中生代以来,华南受多期板块俯冲的控制,发育大规模岩浆岩带及海域广泛分布的弧前盆地。但陆域弧岩浆岩较少,海域又缺乏足够钻井,各时期陆弧的位置存在较大争议,同时,南海北部至东海一带弧前盆地也缺乏系统认识,因此,亟须新的研究思路深化对华南晚中生代俯冲体系和俯冲过程的认识。本文以前人研究为基础,对海域钻遇中生界的典型钻井进行了详细分析,系统开展了海域盆地区域构造和沉积对比,将弧前盆地发育与岛弧变迁相结合综合分析。结果表明早侏罗世—早白垩世陆弧位于南海北部—东海靠近陆域一侧,经历了早侏罗世局限陆弧、中晚侏罗世沿海陆弧带、早白垩世向海沟方向的迁移。在此过程中,华南海域弧前盆地群于中侏罗世正式形成,早白垩世发育盆缘角度不整合,粗碎屑相带向海沟方向迁移,晚白垩南海北部与东海各自进入新的构造体制,结束弧前盆地的发育。华南沿海海域中生代盆地的发育可为陆弧的展布提供重要约束,弧岩浆岩带的迁移控制了弧前盆地的演化。     

北黄海盆地构造演化特征分析

依据最新油气资源调查资料,在简述北黄海盆地区域构造特征的基础上,重点分析了盆地的沉降史与构造演化特征。研究表明:(1)北黄海盆地的基本沉降曲线型式为7段折线状,其中晚侏罗世、早白垩世、始新世、渐新世、新近纪为曲线下降段,代表盆地5幕较明显的沉降;晚白垩世—古新世以及中新世早期为曲线上升段,反映盆地的抬升剥蚀。(2)盆地沉降作用自中生代至新生代总体由东向西迁移,东部坳陷以中生代沉降作用最为显著,中部坳陷主沉降期为始新世,而西部坳陷的快速沉降主要发生在始新世,并一直持续到渐新世。(3)盆地构造演化大致可划分为中生代断陷盆地、古近纪叠加断陷盆地以及新近纪坳陷盆地等3大发展阶段,其中,中生代断陷盆地发育阶段是北黄海盆地油气勘探研究的重点。     

放射虫硅质岩对华南古地理的启示

放射虫硅质岩在中国南方及邻区广泛分布,有重要的古地理意义。按其时空分布,可分为南区及北区和东带。南区包括滇西、滇东南、桂西和桂南,主要为晚古生代至中生代早期放射虫硅质岩。滇西硅质岩带南延至泰国和马来西亚,代表古特提斯主支。滇东南、桂西和桂南的硅质岩则指示古特提斯多岛洋的分支海盆。北区包括两广中北部、湘赣中南部和长江中下游一带,主要为二叠纪中晚期放射虫硅质岩,标志当时扬子台缘与古特提斯洋连通的深水盆地。东带沿南海和东海外侧的岛弧分布,从菲律宾北巴拉望经琉球到西南日本内带,主要为中二叠世至晚侏罗世放射虫硅质岩,与古地磁证据一起指示了该期间华南南方一个低纬度的远洋盆地,可称为“古南中国海”。它的张开可能是中晚二叠世云开地体和中国东南部其他地方造山事件的原因,它的随后发展对华南东部三叠纪和侏罗纪古地理演化也有重大影响。晚侏罗世太平洋伊泽奈崎板块的迅速北移,使“古南中国海"俯冲消减,导致东南沿海大规模的钙碱性岩浆活动。     

Kinematics of syn-tectonic unconformities and implications for the tectonic evolution of the Hala'alat Mountains at the northwestern margin of the Junggar Basin,Central Asian Orogenic Belt

The Hala’alat Mountains are located at the transition between the West Junggar and the Junggar Basin.In this area,rocks are Carboniferous,with younger strata above them that have been identified through well data and high-resolution 3D seismic profiles.Among these strata,seven unconformities are observed and distributed at the bases of:the Permian Jiamuhe Formation,the Permian Fengcheng Formation,the Triassic Baikouquan Formation,the Jurassic Badaowan Formation,the Jurassic Xishanyao Formation,the Cretaceous Tugulu Group and the Paleogene.On the basis of balanced sections,these unconformities are determined to have been formed by erosion of uplifts or rotated fault blocks primarily during the Mesozoic and Cenozoic.In conjunction with the currently understood tectonic background of the surrounding areas,the following conclusions are proposed:the unconformities at the bases of the Permian Jiamuhe and Fengcheng formations are most likely related to the subduction and closure of the Junggar Ocean during the late Carboniferous-early Permian;the unconformities at the bases of the Triassic Baikouquan and Jurassic Badaowan formations are closely related to the late Permian-Triassic Durbut sinistral slip fault;the unconformities at the bases of the middle Jurassic Xishanyao Formation and Cretaceous Tugulu Group may be related to reactivation of the Durbut dextral slip fault in the late Jurassic-early Cretaceous,and the unconformity that gives rise to the widely observed absence of the upper Cretaceous in the northern Junggar Basin may be closely related to large scale uplift.All of these geological phenomena indicate that the West Junggar was not calm in the Mesozoic and Cenozoic and that it experienced at least four periods of tectonic movement.     

Geological and tectonic evolution of the Transantarctic Mountains,from ancient craton to recent enigma

The Transantarctic Mountains (TAM) are one of Earth's great mountain belts and are a fundamental physiographic feature of Antarctica. They are continental-scale, traverse a wide range of latitudes, have high relief, contain a significant proportion of exposed rock on the continent, and represent a major arc of environmental and geological transition. Although the modern physiography is largely of Cenozoic origin, this major feature has persisted for hundreds of millions of years since the Neoproterozoic to the modern. Its mere existence as the planet's longest intraplate mountain belt at the transition between a thick stable craton in East Antarctica and a large extensional province in West Antarctica is a continuing enigma. The early and more cryptic tectonic evolution of the TAM includes Mesoarchean and Paleoproterozoic crust formation as part of the Columbia supercontinent, followed by Neoproterozoic rift separation from Laurentia during breakup of Rodinia. Development of an Andean-style Gondwana convergent margin resulted in a long-lived Ross orogenic cycle from the late Neoproterozoic to the early Paleozoic, succeeded by crustal stabilization and widespread denudation during early Gondwana time, and intra-cratonic and foreland-basin sedimentation during late Paleozoic and early Mesozoic development of Pangea. Voluminous mafic volcanism, sill emplacement, and layered igneous intrusion are a primary signature of hotspot-influenced Jurassic extension during Gondwana breakup. The most recent phase of TAM evolution involved tectonic uplift and exhumation related to Cenozoic extension at the inboard edge of the West Antarctic Rift System, accompanied by Neogene to modern glaciation and volcanism related to the McMurdo alkaline volcanic province. Despite the remote location and relative inaccessibility of the TAM, its underlying varied and diachronous geology provides important clues for reconstructing past supercontinents and influences the modern flow patterns of both ice and atmospheric circulation, signifying that the TAM have both continental and global importance through time.     

南海东北部潮汕坳陷中生代构造特征及其油气勘探潜力

钻探资料证实南海东北部发育海相中生界。潮汕坳陷是南海东北部最大残留坳陷，面积达3. 7×10 4 km2，经历了晚三叠世张裂初期、侏罗纪坳陷期、晚侏罗世末期第一次构造反转期、早白垩世再沉降期、晚白垩世晚期第二次构造反转期及新近纪区域热沉降期等6个构造演化阶段，充填了滨浅海、半深海等海相沉积及河湖相等陆相沉积。潮汕坳陷侏罗系半封闭海湾型烃源岩有机质丰度相对较高，泥岩地层厚，生烃能力强，油气地质条件好，具有较好的油气勘探前景。