阿拉善地块东北缘狼山地区大红山组沉积时代、物质来源及区域构造意义

阿拉善地块位于中亚造山带南缘,是研究中亚造山带南缘二叠纪构造背景及演化的关键地区。本研究在阿拉善地块东北缘狼山地区野外调查的基础上,对狼山地区大红山组地层进行古流向、碎屑锆石LA-ICP-MS U-Pb定年和砂岩碎屑组分分析。研究表明砾石最大扁平面倾向为SWW—NWW,指示大红山组地层沉积时的古水流的流向总体呈现自西向东,推测大红山组砾石主要来自狼山西部地区。砂岩中碎屑锆石最小年龄峰值为275 Ma和278 Ma,表明大红山组沉积时代不早于中二叠世早期。砂岩的碎屑组分分析和碎屑锆石年龄谱指示大红山组可能来自于晚古生代诺尔公—狼山弧,砾石的古流向分析和碎屑锆石年龄谱推测大红山组砾石极有可能来自于阿拉善地块前寒武纪变质基底。结合诺尔公—狼山构造带晚古生代大陆岩浆弧的存在,认为二叠系大红山组地层沉积于弧背前陆盆地的构造背景。     

大兴安岭中段乐平统-中三叠统沉积物源分析:来自重矿物组合及碎屑锆石年代学证据

黑龙江西部龙江地区位于中亚造山带东段,黑河-贺根山缝合带与西拉木伦缝合带之间,地层记录了两大古板块之间古亚洲洋闭合过程的信息。本文对龙江地区乐平统林西组和下-中三叠统老龙头组的砂岩样品进行碎屑重矿物和碎屑锆石U-Pb同位素年代学研究。碎屑重矿物组合以锆石+磷灰石+金红石+角闪石+绿帘石+重晶石的组合为特征,表明物源主要来自于中酸性岩浆岩,并有少量变质岩及沉积岩组分。林西组样品最年轻的锆石年龄为278±3Ma,老龙头组样品最年轻的锆石年龄为247±3Ma、243±4Ma及237±3Ma,结合前人的研究,限定了林西组沉积于乐平世,老龙头组沉积于早三叠世-中三叠世。碎屑锆石年龄谱明显分为五组:237～258Ma、270～329Ma、357～558Ma、680～1633Ma及1893～1966Ma。其中237～258Ma的碎屑锆石主要来自与古亚洲洋洋壳消亡前的俯冲增生过程相关的火山活动,270～329Ma的碎屑锆石主要来自大石寨组火山岩及其同期侵入岩,357～558Ma的碎屑锆石来自早古生代-晚古生代早期岩浆弧,680～1633Ma的碎屑锆石可能来自兴安及额尔古纳地块的变质基底,而较古老的～1800Ma的锆石年龄暗示了华北克拉通基底的物源信息。通过研究发现林西组及老龙头组样品前30%年轻的碎屑锆石年龄与地层沉积年龄之差都小于100Ma,结合对砂岩碎屑组成、重矿物组合及盆地与火山弧位置关系的研究,认为研究区乐平世-中三叠世沉积盆地具有汇聚背景,为弧前盆地。     

新疆准噶尔古生代洋盆闭合时限——来自卡拉麦里地区石炭纪碎屑锆石U-Pb年代学的约束

新疆准噶尔古生代洋盆闭合时限对中亚造山带古生代构造格局及演化研究具有重要意义。东准噶尔卡拉麦里断裂带南缘广泛出露石炭纪陆相粗碎屑岩系,沉积相分析表明其形成于扇三角洲沉积环境。依据区域地层对比、岩石组合特征及地层接触关系,将其重新厘定为山梁砾石组。选择西段滴水泉和东段双井子2个地区的山梁砾石组剖面进行地层对比,并在2个剖面底部采集粗砂岩样品进行LA-ICP-MS锆石U-Pb年龄测定,获得最年轻的碎屑锆石年龄分别为349±4Ma和355±3Ma,代表山梁砾石组沉积时代晚于349Ma,应为早石炭世早期。碎屑锆石年龄分布特征及砾石成分表明,其物源主要来自断裂带北侧的泥盆纪火山岩。在分析前人资料的基础上,认为山梁砾石组碎屑岩系是卡拉麦里造山带强烈隆升造山过程的沉积学响应,形成于前陆盆地,限定了准噶尔古生代洋盆闭合时限在早石炭世早期之前。     

阿拉善地块北缘恩格尔乌苏地区发现志留纪侵入体

阿拉善地块北缘地区位于中亚造山带的南缘中段,连接了兴蒙造山带和北山造山带等构造单元,其古生代的构造演化对于中亚造山带南缘构造单元的对比连接具有重要的意义,是研究中亚造山带古生代构造演化的关键位置。统计归纳近年来阿拉善地块北缘地区的年代学数据发现,该地区的岩浆活动主要集中在晚古生代期间,特别是二叠期间,尚没有早古生代侵入岩的报道。恩格尔乌苏蛇绿混杂岩是阿拉善地块北缘地区出露的一条重要蛇绿岩带,本次研究在该混杂岩带中发现了早古生代的黑云母花岗岩。通过锆石LA-ICP-MS U-Pb年代学测试发现其时代为423±4.5 Ma和434±1Ma,代表了其岩浆结晶年龄,表明该侵入岩形成于志留纪期间,是阿拉善地块北缘地区最早发现的早古生代侵入体之一。该志留纪岩体的发现,表明恩格尔乌苏混杂岩在带志留纪期间已经出现岩浆活动,具有多期活动的特征。该志留纪岩体的发现,是研究、认识阿拉善地块北缘地区早古生代构造环境的重要对象,对于连接对比东、西相邻构造单元具有重要的意义。结合相邻白山组地层的碎屑锆石时代及晚泥盆世侵入岩的发现等研究成果推断,阿拉善地块北缘地区在早古生代开始就存在岩浆活动,该地区可能并非是早古生代的稳定被动大陆边缘。     

中亚造山带北山南部柳园洋晚古生代两阶段古地理演化

甘蒙北山地区位于中亚造山带中段,其间的柳园洋是古亚洲洋的重要分支之一,关于该洋盆的演化过程存在两阶段裂谷盆地和单阶段长期俯冲两种认识。柳园洋位于北山南部石板山地块和双鹰山地块之间,石板山地块的晚古生代沉积序列和物源变化完整记录了洋盆的古地理演化过程,对于重建区域构造演化有重要意义。此次研究聚焦石板山地块独山地区的上古生界火山- 沉积序列,通过砂岩碎屑颗粒组分和碎屑锆石U- Pb- Hf同位素分析,提供柳园洋古地理演化的约束证据。本文数据表明：独山地区下—中泥盆统碎屑锆石年龄为早古生代单峰式分布（~415 Ma）,来自于柳园洋向南俯冲在石板山地块边缘而形成的岩浆弧;上石炭统—下二叠统样品中出现了明显的中元古代碎屑锆石年龄（~1426 Ma）,来自于北侧的双鹰山地块和中天山地块,指示洋盆闭合事件;下二叠统碎屑锆石年龄主要为晚石炭世—早二叠世单峰式分布（301~290 Ma）,来自于裂谷火山活动。此外,本次研究通过对北山南部已发表物源学数据的统计计算,进一步证明并完善了古生代柳园洋两阶段演化模型：中奥陶世—中泥盆世,柳园洋双向俯冲至敦煌- 石板山地块和双鹰山地块之下;晚泥盆世,柳园洋闭合,直至石炭纪晚期,敦煌- 石板山- 双鹰山地块形成了统一的陆缘环境;早—中二叠世,柳园裂谷盆地逐步发育至原洋盆地。     

鄂尔多斯盆地南部二叠系砂岩碎屑锆石年代学特征及地质意义

陆源碎屑岩物质来源及变化与沉积盆地及构造演化密切相关。通过对鄂尔多斯盆地南部铜川地区晚古生代二叠系山西组、石盒子组及石千峰组砂岩样品岩石薄片鉴定、定量矿物学分析以及碎屑锆石U-Pb年代学分析,结合古流向特征,对物源进行了追溯,并讨论了盆地南部二叠系的构造—沉积过程。研究结果表明,早二叠世山西组碎屑锆石年龄具364 Ma、450 Ma、946Ma和2 446 Ma四个主要峰值;中二叠世下石盒子组碎屑锆石年龄具294 Ma、1 963.4 Ma和2 499 Ma三个主要峰值;晚二叠世石千峰组碎屑锆石年龄主要峰值出现在1 876.5 Ma,缺乏北秦岭造山带的新元古代和早古生代碎屑锆石记录。分析认为山西组主要物源区为北秦岭造山带,次要物源区为华北南缘构造带;石盒子组物源由北秦岭造山带、华北板块南缘构造带和内蒙古隆起西段共同提供;石千峰组物源区为华北南缘构造带。早二叠世山西期,华北南缘隆起幅度较低,不影响北秦岭造山带供源。石盒子期,勉略洋由被动拉张转换为主动挤压,秦岭造山带处于持续隆升状态,并造成了华北南缘构造带的不断抬升。石千峰期华北南缘强烈隆升,在为铜川地区提供物源的同时也阻挡了北秦岭造山带...     

早古生代阿拉善地块与华北地块之间的关系:来自阿拉善东缘中奥陶统碎屑锆石的信息

阿拉善东缘奥陶纪地层位于鄂尔多斯(华北地块)与北祁连早古生代造山带之间的过渡地区,该区的构造背景一直是长期争论的问题,它涉及到阿拉善地块是否与华北地块相连、奥陶系的物源以及"贺兰拗拉槽"是否存在等问题。分布于阿拉善地块东缘的中奥陶统米钵山组的碎屑锆石LA-ICP-MSU-Pb年龄测试表明,样品中数量最多的锆石年龄为900～950Ma,Alxa-1的峰值年龄为916Ma,Alxa-2的峰值年龄为953Ma,次者在494～623Ma之间,这个区间内存在多个峰值,如Alxa-1存在505Ma和588Ma两个主要峰值,Alxa-2则存在494Ma、517Ma、623Ma等几个峰值。在2.5Ga左右两个样品都存在一个弱的峰值,Alxa-1峰值为2517Ma,而Alxa-2峰值为2552Ma和2670Ma。除此之外,两个样品都有个别大于3.0Ga的成分,Alxa-1样品中最年轻的锆石为451±8Ma,Alxa-2样品则为483±4Ma。这些年龄以及沉积特征表明:(1)传统认为的奥陶纪"贺兰拗拉槽"并不存在,鄂尔多斯西南缘地区以及阿拉善东部地区当时属于北祁连早古生代周缘前陆盆地系统;(2)早古生代主要物源来自北祁连造山带,新元古代物源来自阿拉善地块;(3)鄂尔多斯西缘整个米钵山组的锆石年龄分布及其变化,指示出北祁连造山带(岛弧)逐渐靠近阿拉善地块,其间洋盆逐渐消失的过程;(4)阿拉善地块基底与华北有明显差别,阿拉善地块明显受到新元古代和古生代构造热事件的影响,两者可能是在中奥陶世或之后才拼贴在一起。     

东昆仑东段布青山地区上二叠统格曲组物源分析及其构造意义

对东昆仑东段布青山得力斯坦地区出露的上二叠统格曲组砾岩层进行砾石成分、砾度统计及系统的LA-ICP-MS锆石UPb年龄谱分析。结果表明,格曲组砾岩层砾石成分以石英岩和花岗岩为主,硅质岩和基性岩次之,砂岩和灰岩较少,砾石的分散系数为1.54~2.02,该套砾岩为近源快速堆积的产物。砾岩碎屑锆石U-Pb年龄可分为3组:1早奥陶世—晚志留世年龄组为499~409Ma,峰值年龄为426Ma,对应早古生代末期原特提斯洋向北俯冲碰撞产生的一系列构造岩浆事件;2新元古代年龄组为744~619Ma,峰值年龄为744Ma,对应于全球Rodinia超大陆裂解事件;3古元古代年龄组为2443Ma,对应东昆仑地区古元古代构造岩浆热事件。结合碎屑锆石年龄及沉积学特征综合分析,花岗质砾石来源于北侧东昆仑造山带加里东期岩浆弧,沉积岩砾石则可能来自造山带早期的沉积地层,石英岩及其他变质岩砾石则多来自东昆仑基底变质岩系。综合判别,格曲组为一套沉积于活动大陆边缘环境的滨浅海相磨拉石建造,代表南侧古特提斯洋向北俯冲开始的构造阶段,是初始俯冲的沉积构造响应。     

黔南晚古生代早期碎屑锆石记录及物源转换响应

贵州黔南独山地区处扬子陆块东南缘,出露较完整的下古生界地层,对该区开展碎屑锆石U-Pb年龄谱研究可为晚古生代之前扬子地块与华夏地块结合带构造属性的进一步确定和对华南大地构造演化的深入研究提供新依据。本文对该区下泥盆统丹林组5件石英砂岩分析了375颗碎屑锆石:锆石阴极发光具有典型的振荡环带、不规则分带,Th/U比值多大于01,强Ce正异常、弱Eu负异常特征;346组谐和年龄显示来自多个源区,5组主要年龄峰值2 456 Ma、1 366 Ma、970 Ma、536 Ma、402 Ma,以970 Ma为最突出峰值。研究认为古生代锆石源于桂北-湘西内陆加里东期花岗岩、新元古代锆石主要来自江南造山带内新元古代四堡群、丹州群的火成岩;中元古代-太古宙锆石可能从华夏板块内部搬运到扬子板块。进一步论证了古生代华夏板块和扬子板块之间不存在沉积阻隔区,是一个整体板块;丹林组沉积于华南地块内的一个克拉通盆地。     

内蒙古白云鄂博上石炭—下二叠统阿木山组碎屑锆石年代学特征及其地质意义

内蒙古白云鄂博地区阿木山组砂岩的碎屑锆石LA—ICP—MS U—Pb同位素年代学分析结果显示,早二叠世阿木山组的碎屑锆石主要由古生代(354~479 Ma)和元古宙(934~1 941 Ma)及少量的古元古—新太古代(2 330~2 688 Ma)碎屑锆石组成。结合该组模式剖面的实测和?蜓化石再研究,笔者认为,阿木山组含934~1 941 Ma碎屑锆石的砂岩物源来自于佳蒙地块,而非华北板块;含有Sphaeroschwagerina化石带的阿木山组应当属于佳蒙地块的大陆边缘沉积。这一认识对于研究西拉木伦河缝合带和古亚洲洋的构造演化、以及将内蒙古草原—松花江地层区划归佳蒙地层大区等具有重要意义。     

南秦岭下地壳组成及岩石圈的拆离俯冲作用

根据新提供的Pb同位素组成及岩石地球化学研究成果，本文进一步证实了位于北秦岭北界的明港地区发育的早中生代安山玄武质火山角砾岩岩筒所携带的下地壳捕虏体属于南秦岭。所恢复的南秦岭下地壳剖面自下而上为：底侵成因的变辉长岩-基性麻粒岩(其中含有榴辉岩及辉石岩的透镜体)-酸性麻粒岩。秦岭造山带总体的岩石因模型为：南秦岭(扬子块体)向北拆离俯冲，北秦岭地壳向华北仰冲，华北岩石因呈楔状插入秦岭造山带，拆离面约在中、下地壳之间。南秦岭俯冲岩片延伸的范围在平面上有可能达到400km。     

青藏高原综合观测研究站的回顾与展望

中国科学院青藏高原综合观测研究站从１９８８年建站到１９９８年以来,在各个方面均取得了长足的发展,横向生产性项目的开展和完成不仅解决了部队和地方的实际问题,而且缓和了观测研究站在运行过程中所面临的经费严重不足的问题,同时也为我所冻土专业研究人员提供了在生产中实践的机会,在基础理论研究方面,承担了国家攀登计划项目,国家基金项目,中国科学院重点项目和中国科学院冰冻圈专项项目等的研究工作,在多年冻土变化,     

铀钍的地球化学及对地壳演化和生物进化的影响

本文论述了在含挥发份和贫挥发份条件下Ｕ、Ｔｈ的迁移行为及其对地球和行星演化的影响,并阐述了造成地球独特地质演化历史的原因。提出了Ｕ、Ｔｈ在地球中的迁移模式以及该模式对地壳形成、演化的控制作用和对生物发展演化的可能影响。     

Wavelets and the Generalization of the Variogram

The experimental variogram computed in the usual way by the method of moments and the Haar wavelet transform are similar in that they filter data and yield informative summaries that may be interpreted. The variogram filters out constant values; wavelets can filter variation at several spatial scales and thereby provide a richer repertoire for analysis and demand no assumptions other than that of finite variance. This paper compares the two functions, identifying that part of the Haar wavelet transform that gives it its advantages. It goes on to show that the generalized variogram of order k=1, 2, and 3 filters linear, quadratic, and cubic polynomials from the data, respectively, which correspond with more complex wavelets in Daubechies's family. The additional filter coefficients of the latter can reveal features of the data that are not evident in its usual form. Three examples in which data recorded at regular intervals on transects are analyzed illustrate the extended form of the variogram. The apparent periodicity of gilgais in Australia seems to be accentuated as filter coefficients are added, but otherwise the analysis provides no new insight. Analysis of hyerpsectral data with a strong linear trend showed that the wavelet-based variograms filtered it out. Adding filter coefficients in the analysis of the topsoil across the Jurassic scarplands of England changed the upper bound of the variogram; it then resembled the within-class variogram computed by the method of moments. To elucidate these results, we simulated several series of data to represent a random process with values fluctuating about a mean, data with long-range linear trend, data with local trend, and data with stepped transitions. The results suggest that the wavelet variogram can filter out the effects of long-range trend, but not local trend, and of transitions from one class to another, as across boundaries.     

共和盆地层状地貌系统与青藏高原隆升及黄河发育

利用卫星遥感影像,结合实地调查和测年结果,对共和盆地层状地貌系统进行了解译、分析。研究表明,共和盆地层状地貌系统由山麓剥蚀面、洪积扇面、盆地面以及黄河阶地面构成,其空间结构、物质组成对发生于早更新世早期的青藏运动C幕和中更新世末期的共和运动反映清晰。青藏运动C幕使青藏高原主夷平面在高原差异性隆升中彻底解体,垂直变形量高达1700m。共和运动使黄河在0.11Ma进入共和盆地,其后黄河平均以3.5mm/a的侵蚀速率下切盆地,同时在盆地边部的山前古冲洪积扇以大致相近的速率被抬升,最终导致高差在2000m左右的层状地貌系统的出现。     

从榴辉岩与围岩的关系论苏鲁榴辉岩的形成与折返

位于华北和扬子两板块碰撞带中的苏鲁榴辉岩形成的温压条件不但是超高压，而且是高温。榴辉岩的PTt轨迹表明其为陆-陆磁撞俯冲带的产物。榴辉岩的区域性围岩花岗质片麻岩为新元古代同碰撞期花岗岩，榴辉岩及其他直接围岩皆呈包体存在于其中，并见新元古代花岗岩呈脉状侵入榴辉岩包体中。区域性围岩新元古代花岗岩的锆石中发现有柯石英、绿辉石等包裹体，表明新元古代花岗岩的组成物质也经受过超高压变质作用，且榴辉岩与围岩新元古代花岗岩的锆石U-Pb体系同位素年龄基本相同。但新元古代花岗岩所记录的变质作用和变形作用期次（或阶段）却少于榴辉岩。椐上述可得如下推断：超高压榴辉岩与新元古代花岗岩岩浆是同时在碰撞带底部（俯冲板块前部）形成的；榴辉岩的第一折返阶段是由新元古代花岗岩岩浆携带上升的，其第二折返阶段是和新元古代花岗岩一起由逆冲及区域性隆起而上升，遭受剥蚀。     

南海的形成演化与新特提斯在南海的重新活化

南海位于印度板块、欧亚板块和太平洋板块之间,是世界上最大的边缘海,其构造位置处于太平洋构造域和特提斯构造域,地质构造复杂.关于南海形成演化的动力学机制存在有多种不同观点,其中最重要的一个观点是印度板块与欧亚板块的碰撞致使华南地块和印支地块地幔物质沿东南方向蠕动,从而导致南海的海底扩张.从特提斯的演化规律,以及新特提斯的闭合过程来看,南海并不是特提斯洋的残留海,而是新特提斯在闭合过程中配合印度板块与欧亚板块碰撞导致华南地块和印支地块地幔物质东南方向蠕动的动力学机制下,在南海重新活化的结果.     

Principles of spatial organization and evolution of the biosphere and the noosphere

In his last lifetime essay, “A Few Words about the Noosphere”, Academician V.I. Vernadsky (1944) wrote that all living organisms on the planet, including man, are integral to the biosphere of the Earth, its material and energy structure and cannot be physically independent of it even for a minute. However, the substrate that generates all living beings and is no less tightly bound to the biosphere has always been characterized by a significant geochemical heterogeneity, traced both in the vertical and in the lateral structure of all geospheres.

The present work is devoted to three most important aspects of modern geochemistry and biogeochemistry:

• — evolution of the ecological and geochemical state of the environment under conditions of a virgin (anthropogenically untouched) biosphere;
• — structural features of the geochemical organization of the modern noosphere;
• — specificity of the interaction of living matter with the environment under increasing anthropogenic load.

On the basis of theoretical concepts of biogeochemistry and geochemical ecology, formulated in the works of V.I. Vernadsky, A.P. Vinogradov, A.E. Fersman, B.B. Polynov, A.I. Perel’man, M.A. Glazovskaya, V.V. Kovalsky, E. Odum, B. Commoner, E.I. Kolchinskii and others, the author puts forward a hypothesis that there exist two qualitatively different stages in the evolution of the biosphere.The first stage is recognized as the period of natural evolution of the biosphere during which it evolves successively into a more complex and more biogeochemically specialized object. In the course of the geological time, this constantly results, on the one hand, in an increase in species diversity and the perfection of individual species, and, on the other hand, to directed improvement and a greater differentiation of the geochemical conditions of the environment. At this stage, the evolution of all systems of the biosphere that were controlled by the mechanisms of self-organization and self-regulation resulted in the establishment of a dynamic equilibrium, which was responsible for the cycling of all essential chemical elements and therefore providing ecologically optimal geochemical conditions in all ecological niches and for all species and biocenoses inhabiting the biosphere at any given moment.The beginning of the second stage is related to the appearance of reason and qualitative changes in the biosphere caused by the goal-directed activity of the human mind, as an entirely new geological force that appeared to be able not only to disrupt the functioning of natural mechanisms of self-regulation and selforganization, but also to transform the environment in the intersts of a single biological species, Homo sapiens. A direct consequence of this change was the uncontrolled transformation of the natural environment, during which the primary structure (geochemical background) created in the course of billions of years was eventually superimposed by a qualitatively new layer of anthropogenically-derived chemical elements and compounds, thus building an interference pattern of a new geochemical field with which practically all modern living organisms are now forced to interact.An outstanding feature of the new evolutionary stage of the natural environment, called by Vernadsky the noosphere, is that biogeochemical changes at this stage proceed at a rate which exceeds that required for the living matter to adapt to these changes. The result is the disruption of the existing parameters of the biological cycle, leading to the emergence of a significant number of endemic diseases of geochemical nature.The proposed approach was used to prove the anthropogenic genesis of existing geochemical endemic diseases and explain the mechanisms of their appearance. In addition, this approach allowed us to develop a new methodology for mapping zones of ecological and geochemical risk and noticeably simplify the procedure of monitoring distribution and prevention of all diseases of geochemical nature.