日本岛弧增生及其对太古宙绿岩成因的意义

西太平洋现代日本本土（本州岛弧）与Ｉｚｕ－Ｂｏｎｉｎ岛弧之间的弧－弧碰撞带（被称为Ｉｚｕ碰撞带或ＩＣＺ），为许多太古宙绿岩带的发展演化提供了一个非常适用的运动学模式。ＩＣＺ中地壳的成分组合、热结构和构造样式与许多太古宙绿岩带的非常相似，它们都是具有高热流值的、厚的、较年轻的片状岛弧地壳与另一个地壳块体的碰撞产物。ＩＣＺ导致了地壳厚层片体的叠瓦状构造，并伴有与古老增生柱相并置的沉积物。许多太古宙绿岩带也显示出类似的地质特征。我们认为地壳的这种递增叠瓦式构造是许多太古宙会聚型边缘的普遍样式。     

秦岭镇—甸地区微细浸染型锑金矿床成矿条件及其找矿前景分析

镇（安）旬（阳）地区锑金矿化分布，与其区域地质地球化学因素，陆源断陷盆地沉积岩相变化，后期构造作用密切相关，认为镇旬地区为扬子与华北板块边缘对接过渡活动带，形成局部扩张断陷沉积盆地环境。     

吉林省板石沟—旺文川绿岩带岩石地球化学特征及成岩环境分析

吉林省南部晚太古宙绿岩带位于龙岗古陆核南部边缘,它包括板石沟、四方山和旺文川绿岩带,其岩石主要为变质镁铁质火山岩和变质长英质火山岩,反映出具双峰式火山岩的特征。另外,本区绿岩带岩石的岩石化学和地球化学特征与龙岗古陆核北部边缘的夹皮沟绿岩带具有明显的差异,表明两者成岩环境不同。本区绿岩带斜长角闪岩属板内玄武岩,其成岩环境与大陆裂谷环境相似。     

中国太古宙地质体组成、阶段划分和演化

我国太古宇陆壳主要见于华北克拉通区内，由高级变质的麻粒岩相带、角闪宕相区和低、中级变质的绿岩－花岗岩区组成。按地质时序可划分为始、古、中、新太古４个阶段。麻粒岩相带的组成主要由英云闪长质片麻岩为主和少量表壳岩或主要由表壳岩含一些花岗质岩石。绿岩－花岗岩区时代主要属新太古代，绿岩属基性火山－沉积建造，基性岩的原岩物质来自相对亏损的上地幔，形成于大陆边缘的裂谷环境。太古宙末，板块体制已经形成，麻粒岩相带是板块体制的俯冲碰撞机制的产物。对克拉通古陆块能长期成为大陆的解释，应认为是下地壳的挤压环境，促使陆壳以板底垫托叠置、垂直增生所致。     

华北古陆的形成与构造演化史

以华北古陆为例，论述了地球演化史中经历的三大阶段：（１）古陆的形成阶段（４６００～１８００Ｍａ）：地球形成早期，以地幔对流为主导作用，到早太古宙出现初始古陆核，地幔对流驱动的地体拼贴和板底垫托是陆壳形成的主要方式；中太古宙开始出现一定规模的坳陷盆地，发育了基性火山岩 碎屑岩 镁质碳酸盐岩等表壳岩，同时伴随着大量中基性、花岗质岩浆活动；晚太古宙和早元古宙是陆壳形成的主要时期，并已具现今板块活动特征。地幔热柱与板块构造共同控制着地壳运动。（２）古陆稳定发展阶段（１８００～２５０Ｍａ）：地幔热柱活动较弱，古陆主要表现为缓慢的升降运动（造陆运动）。（３）地球新活动时期（２５０Ｍａ至今）：地幔热柱活动进入一个新的活跃时期。岩石圈发生明显的热减薄，地幔热柱表现为多级演化，并导致盆岭系的形成。     

台湾岛以南海域新近纪的弧-陆碰撞造山作用

台湾岛以南海域(台南滨海)弧—陆碰撞带位于欧亚板块、菲律宾海板块和南海的结合部位,是新近纪弧—陆碰撞研究的理想场所。本文通过对南海973航次在该区域的多道地震剖面的解释,认为台南滨海弧—陆碰撞带增生的火山—沉积楔由恒春海脊和高屏斜坡两部分组成,前者是菲律宾海板块的增生楔,后者是欧亚板块的增生楔,在增生楔体和火山弧之间是作为弧前盆地的北吕宋海槽。自中新世中期以来,南海洋壳开始沿着马尼拉海沟向菲律宾海板块俯冲,形成活动大陆边缘的增生部分——恒春海脊;与此同时菲律宾海板块开始向北西方向移动,前缘的吕宋岛弧距今6.5Ma以来朝着亚洲陆缘斜向汇聚,形成了被动大陆边缘的增生部分——高屏斜坡。由于菲律宾海板块和欧亚板块之间的斜向汇聚,弧—陆碰撞具有穿时性,造山作用首先发生在台湾岛的北部,然后向南部及台南滨海发展。     

扬子板块的地壳演化与地层对比

扬子板块是在古元古－新太古宙的古陆核基础上发展演化而成。吕梁运动以前，以川中微型陆块为主体的若干个小型古陆块组成向北西突出的牛轭形陆块带。中元古宙在牛轭形陆块带的东西两侧形成海沟岛弧系，沉积一套弧前及弧后的优地槽和旰地槽建造。１０－１１亿年时的东川运动使沟弧系褶皱回返，固结为陆新元古宙早期产生大陆裂谷，形成五一套裂谷建造，晋宁运动使扬子板块整体固结新元古宙晚发育山前磨拉建造、冰碛层及碳酸盐盖层。全     

东天山觉罗塔格地区夹白山一带晚古生代构造格局及演化

研究区早石炭世经历了中天山古陆北缘被动陆缘向活动陆缘沟弧盆体系演化的全过程。阿齐山-雅满苏岛弧带于维宪期发育在广宽陆棚海之上。岛弧为大型背形结构,雅满苏断裂带为火山喷发的主要通道,弧前盆地生成于弧沟间隙部位。晚石炭世早期,弧后区发生扩张作用而塌陷形成向形的边缘盆地。晚石炭世末,北侧康古尔洋区以弧弧对接方式关闭,弧区伴有深成花岗岩浆侵位。早二叠世早期进入松弛阶段,在弧间及弧后南缘产生上叠断陷盆地。晚二叠世右旋走滑变动席卷全区,最后大型造山带与地块之间发生块体右旋滑移错位,由此奠定了现今的盆山构造格局初貌。     

东天山觉罗塔格地区夹白山一带晚古生代构造格局及演化

研究区早石炭世经历了中天山古陆北缘被动陆缘向活动陆缘沟弧盆体系演化的全过程.阿齐山-雅满苏岛弧带于维宪期发育在广宽陆棚海之上.岛弧为大型背形结构,雅满苏断裂带为火山喷发的主要通道,弧前盆地生成于弧沟间隙部位.晚石炭世早期,弧后区发生扩张作用而塌陷形成向形的边缘盆地.晚石炭世末,北侧康古尔洋区以弧弧对接方式关闭,弧区伴有深成花岗岩浆侵位.早二叠世早期进入松弛阶段,在弧间及弧后南缘产生上叠断陷盆地.晚二叠世右旋走滑变动席卷全区,最后大型造山带与地块之间发生块体右旋滑移错位,由此奠定了现今的盆山构造格局初貌.     

华夏古陆的地球物理场信息

近20年来,在东南沿海发现了较多的古元古代-太古宙的地质信息,这些"古信息"集中出现在武夷隆起周围,称之为"武夷古信息区"."武夷古信息区"在多种地球物理场上有明显的反映,表现为残存古陆核(块)的地球物理特征.通过进一步对比和综合分析多种地球物理场资料,认为东南沿海残存多个古陆核(块),华夏板块可能是由多个古陆核(块)增生形成的.     

额尔古纳地块基底地质构造

额尔古纳地块是额尔古纳-马门-加格达奇拼合地块中的典型代表.研究表明,其基底由前中元古代绿岩及与之伴生的花岗质杂岩组成,它们具有地壳早期演化的地质构造特征.绿岩带为典型的变质基性-酸性火山岩及部分变质沉积岩系构成的火山-沉积建造,火山岩以拉斑玄武岩为主,向上过渡为钙碱性火山岩系列,表现为双峰态型特点.花岗岩类为TTG岩系及石英二长岩-花岗岩组合.花岗岩-绿岩地体内各岩石类型的岩石地球化学特征与国外太古宙及我国华北陆台花岗岩-绿岩带内同类岩石极为相似.双峰态型火山岩及绿岩建造组合,以及类似于TH2、FII型的变质基性火山岩和长英质火山岩特征,结合高铝型英云闪长岩-奥长花岗岩组合,指示了研究区绿岩带的形成环境类似于大陆边缘弧后裂谷型火山-沉积盆地.     

辽北－吉南地区太古宙花岗岩－绿岩带地质地球化学

辽北－吉南地区是我国典型太古宙花岗岩－绿岩带出露区之一。根据其地质地球化学特征，本区绿岩带可划分为清原型和夹皮沟型，其形成的古构造环境分别为与现代岛弧的大陆边缘活动带和弧后盆地或大陆边缘裂谷相类似的裂谷型构造环境。与绿岩带有关的花岗质岩石可划分为三类：即片麻状花岗质杂岩体、花岗闪长岩和英云闪长岩底辟岩基以及钾质花岗岩。花岗岩－绿岩带的形成时代为２．５－２．９Ｇａ。     

双山子太古代绿岩带金矿的基本特征

文章简要介绍了双山子太古代绿岩带的基本特征,指出双山子绿岩带同加拿大阿比提比绿岩带有许多相似之处;论述了绿岩带中三期不同类型金矿的各自主要成矿地质特征,指出早期含金石英脉是太古代的产物,为冀东地区典型的太古代绿岩带金矿;毒砂型金矿可能是太古代最晚期的产物;晚期石英脉型金矿形成于燕山期.在该区东部南北长约30km的矿带中...     

The development of a Meso- to Neoarchean rifting-convergence-collision-collapse cycle over an ancient thickened protocontinent in the south São Francisco craton,Brazil

The south São Francisco craton (SSFC) in Brazil is one of the few areas that are key to unveiling the Archean evolution of South America. Despite economic interest since the 18th century, the SSFC was not studied in detail until the beginning of the present decade. The two main greenstone belts in the SSFC, namely, the Rio das Velhas (RVGB) and the Pitangui (PGB), have traditionally been considered to represent a single Archean basin. Here, new geochemistry and geochronology data from both greenstone and TTG-granite rocks are integrated and suggest that these belts evolved as separate domains. These are marked by distinct basal komatiite geochemistry, indicating that the PGB evolved as a back-arc rift on a thick lithosphere section at 2.86 Ga, in contrast to the RVGB basin, which developed near an exotic juvenile TTG terrain. Approximately 100 Ma later, the PGB basin transitioned to a calc-alkaline dominated setting, coeval with the emplacement of two large TTG igneous bodies at the margins of a poly-recycled ancient terrain. This protracted recycling is marked by extremely negative ƐHf values, which are not common for Archean terrains. The dominant strong crustal signature of the SSFC Archean rocks implies the existence of an anomalous overthickened crust or a Meso- to Neoarchean protocontinent. This thickened crust developed by continuous magmatism, delamination and differentiation in a flat-subduction setting. These mechanisms suggest that modern-style plate tectonics or a similar process such as “dripduction” was operating in this area prior to 3.0 Ga, the time at which a thick continental crust regime and horizontal tectonics were thought to have been established. Late TTG magmatism in the PGB suggests the western SSFC experienced an episode of late crustal thickening at ~2.71 Ga in response to collision, while coeval shallower K-rich magmatism in the RVGB corroborates the diachronous evolution of both belts and the surrounding crystalline terrains.     

Geochemistry of the Archean Kam Group, Yellowknife Greenstone Belt, Slave Province, Canada

The geochemistry and isotope systematics of Archean greenstone belts provide important constraints on the origin of the volcanic rocks and tectonic models for the evolution of Archean cratons. The Kam Group is a approximately 10-km-thick pile of submarine, tholeiitic mafic, and subordinate felsic volcanic rocks erupted between 2712 and 2701 Ma that forms the bulk of the Yellowknife greenstone belt in the dominantly granite-metasedimentary Slave Province. Mafic rocks range from Normal-mid-ocean range basalt-like basalts to slightly light-rare-earth-element-enriched (LREE-enriched) but Nb-depleted basaltic andesites and andesites, whereas dacitic to rhyodacitic felsic rocks are strongly LREE-enriched and highly depleted in Nb. The varepsilonTNd range from +5 to -3 in the mafic to intermediate rocks and from 0 to -5.5 in the felsic rocks. The varepsilonTNd decreases with increasing La/Sm, SiO2 and decreasing Nb/La, suggesting that as the mafic magmas evolved they were contaminated by older basement rocks. Gneissic granitoids >2.9 Ga in age, found at the base of the Kam Group, have varepsilonTNd between -6 and -9 and are excellent candidates for the contaminant. The geochemical and isotopic data, combined with the submarine eruptive setting and field evidence for existing continental basement, support a continental margin rift model for the Kam Group. Similar geochemical-isotopic studies are required on other Slave greenstone belts in order to test evolutionary models for the Slave Province.     

Early Precambrian Earth history: Plate and plume tectonics and extraterrestrial controls

The Hadean and Archean geologic history of the Earth is discussed in the context of available knowledge from different sources: space physics and comparative planetology; isotope geochronology; geology and petrology of Archean greenstone belts (GB) and tonalite-trondhjemite-granodiorite (TTG) complexes; and geodynamic modeling review to analyse plate-tectonic, plume activity, and impact processes. Correlation between the age peaks of terrestrial Hadean-Early Archean zircons and late heavy bombardment events on the Moon, as well as the Hf isotope composition of zircons indicating their mostly mafic sources, hint to an important role of impact processes in the Earth’s history between 4.4 and 3.8 Ga. The earliest continental crust (TTG complexes) formed at 4.2 Ga (Acasta gneisses), while its large-scale recycling left imprint in Hf isotope signatures after 3.75 Ga. The associations and geochemistry of rocks suggest that Archean greenstone belts formed in settings of rifting, ocean floor spreading, subduction, and plume magmatism generally similar to the present respective processes. The Archean history differed in the greater extent of rocks derived from mantle plumes (komatiites and basalts), boninites, and adakites as well as in shorter subduction cycles recorded in alternation of typical calc-alkaline andesite-dacite-rhyolite and adakite series that were generated in a hotter mantle with more turbulent convection and unsteady subduction. The Archean is interpreted as a transient period of small plate tectonics.     

华北克拉通的形成以及早期板块构造

地球上最早的地壳岩石是高钠的花岗质(TTG)岩石,但是否有更老的洋壳存在过、以及陆壳是怎样形成的,涉及到地球动力学几乎所有的问题。其中板块构造是在什么时候开始的,就是个延续了数十年热度不减的前沿科学问题。流行的说法是板块构造始于新元古代,也有一些学者认为在新太古代就已经开始,或者认为自从地球上有了水的记录,就开始有板块构造。在众多的判别板块构造的标志中,蛇绿岩残片和古老的高压变质岩无疑是两个最具影响力的问题。前者可以确定有远古的古老洋壳存在过并成为缝合带中的残片,后者可以指示曾有地表的岩石单元被俯冲到深部,是俯冲、消减与碰撞的岩石学证据。本文在讨论和比较了太古宙绿岩带与蛇绿岩,以及早前寒武纪高温高压(HTHP)麻粒岩/高温—超高温(HT-UHT)麻粒岩与造山带高压变质带之后,认为尚不能作为板块构造的证据。本文还对华北的新太古代末的稳定大陆形成以及古元古代活动带的裂谷-俯冲-碰撞进行了论述。提出华北克拉通在新太古代末的绿岩带-高级区格局可能标志着热体制下有限的横向活动构造,微陆块被火山-沉积岩系焊接,随后发生变质作用和花岗岩化,完成稳定大陆的克拉通化过程。其构造机制可能是适度规模且多发的地幔柱构造控制下小尺度的横向构造运动的机制。华北克拉通的古元古代活动带有与绿岩带-高级区不同的构造样式,表壳岩带状分布,经受了强烈的变形以及中级变质作用,伴随花岗岩的侵入,虽然没有蛇绿岩和高压变质带,但已表现出板块构造的雏形特征。     

大陆的起源

太阳系固体星球都有类似的核-幔-壳结构,但唯独人类居住的地球具有长英质组成的大陆壳.太古宙大陆克拉通主要由英云闪长岩(Tonalite)-奥长花岗岩(Trondhjemite)-花岗闪长岩(Granodiorite)为主的TTG深成侵入体变质而成的正片麻岩和由基性-超基性酸性火山岩及少量沉积岩变质的表壳岩(绿岩)组成....     

Detrital zircon U-Pb geochronology of stromatolitic carbonates from the greenstone belts of Dharwar Craton and Cuddapah basin of Peninsular India

Oldest rocks are sparsely distributed within the Dharwar Craton and little is known about their involvement in the sedimentary sequences which are present in the Archean greenstone successions and the Proterozoic Cuddapah basin.Stromatolitic carbonates are well preserved in the Neoarchean greenstone belts of Dharwar Craton and Cuddapah Basin of Peninsular India displaying varied morphological and geochemical characteristics.In this study,we report results from U-Pb geochronology and trace element composition of the detrital zircons from stromatolitic carbonates present within the Dharwar Craton and Cuddapah basin to understand the provenance and time of accretion and deposition.The UPb ages of the detrital zircons from the Bhimasamudra and Marikanve stromatolites of the Chitradurga greenstone belt of Dharwar Craton display ages of 3426±26 Ma to 2650±38 Ma whereas the Sandur stromatolites gave an age of 3508±29 Ma to 2926±36 Ma suggesting Paleo-to Neoarchean provenance.The U-Pb detrital zircons of the Tadpatri stromatolites gave an age of 2761±31 Ma to1672±38 Ma suggesting Neoarchean to Mesoproterozoic provenance.The Rare Earth Element(REE)patterns of the studied detrital zircons from Archean Dharwar Craton and Proterozoic Cuddapah basin display depletion in light rare earth elements(LREE)and enrichment in heavy rare earth elements(HREE)with pronounced positive Ce and negative Eu anomalies,typical of magmatic zircons.The trace element composition and their relationship collectively indicate a mixed granitoid and mafic source for both the Dharwar and Cuddapah stromatolites.The 3508±29 Ma age of the detrital zircons support the existence of 3.5 Ga crust in the Western Dharwar Craton.The overall detrital zircon ages(3.5-2.7 Ga)obtained from the stromatolitic carbonates of Archean greenstone belts and Proterozoic Cuddapah basin(2.7-1.6 Ga)collectively reflect on^800-900 Ma duration for the Precambrian stromatolite deposition in the Dharwar Craton.     

早前寒武纪洋壳的地质记录及其板块构造意义

元古宙蛇绿岩的不断发现表明威尔逊旋回至少在早元古代已经明显起作用，部分太古宙绿岩带由不同的构造单元拼合而成，并发育不同于显生宙蛇绿岩的大洋壳岩石组合，地幔柱在早太古代构造演化过程中起重要作用，是板块构造的重要补充机制，地球早期热产量较高，可能是造成板块规模较小，洋壳较厚，板块运动速度较快的原因，并以缓倾角俯冲为特征。