• 中国科技核心期刊
  • 荷兰《文摘与引文数据库》(Scopus)收录期刊
高级搜索

巴西卡拉加斯地区变质基底的岩浆作用与构造演化

曾勇, 刘一, 郭维民, 沈莽庭, 徐鸣

曾勇, 刘一, 郭维民, 等. 巴西卡拉加斯地区变质基底的岩浆作用与构造演化[J]. 中国地质调查, 2023, 10(5): 57-70. DOI: 10.19388/j.zgdzdc.2023.05.08
引用本文: 曾勇, 刘一, 郭维民, 等. 巴西卡拉加斯地区变质基底的岩浆作用与构造演化[J]. 中国地质调查, 2023, 10(5): 57-70. DOI: 10.19388/j.zgdzdc.2023.05.08
shu
ZENG Yong, LIU Yi, GUO Weimin, et al. Magmatism and tectonic evolution of metamorphic basement in Carajás area of Brazil[J]. Geological Survey of China, 2023, 10(5): 57-70. DOI: 10.19388/j.zgdzdc.2023.05.08
Citation: ZENG Yong, LIU Yi, GUO Weimin, et al. Magmatism and tectonic evolution of metamorphic basement in Carajás area of Brazil[J]. Geological Survey of China, 2023, 10(5): 57-70. DOI: 10.19388/j.zgdzdc.2023.05.08
shu

巴西卡拉加斯地区变质基底的岩浆作用与构造演化

  • 中国地质调查局南京地质调查中心,江苏 南京 210016

基金项目: 中国地质调查局“华东地区矿山开发与生态修复状况遥感监测(编号: DD20211390)”和中央地质勘查基金“南美地台优势矿产资源成矿规律与潜力分析(编号: 201130D6200119)”项目联合资助
详细信息
    作者简介:

    曾勇(1965—),男,教授级高级工程师,主要从事拉美地区地质构造研究与找矿勘查工作。Email: larryzeng@163.com。

    通信作者:

    刘一(1980—),女,高级工程师,主要从事区域成矿研究和自然资源管理工作。Email: njliuyi025@163.com。

  • 中图分类号: P681.7

Magmatism and tectonic evolution of metamorphic basement in Carajás area of Brazil

  • Nanjing Center, China Geological Survey, Jiangsu Nanjing 210016, China

HTML全文

    摘要
  • 摘要: 巴西卡拉加斯(Carajás)地区发育古老的太古宙变质基底,是世界上矿床类型最丰富、资源聚集程度最高的成矿区之一。在太古宙花岗岩-绿岩为主体的结晶基底中,含有大量紫苏花岗岩、奥长花岗岩-英云闪长岩-花岗闪长岩(trondhjemite-tonalite-granodiorite,TTG)岩套和未完全解体的变质深成岩,目前对其认识仍存在较大分歧。岩浆岩的正确划分和精细研究是深入认识南美克拉通演化的重要手段,在调查卡拉加斯地区基底中变质侵入岩的基础上,结合前人资料将其进一步划分为中太古代的紫苏花岗岩、层状基性—超基性岩和TTG岩套,新太古代的基性—超基性杂岩、TTG岩套、同构造花岗岩、后构造花岗岩等,以及古元古代的碱性花岗岩。结合岩石学、地球化学和年代学方法综合分析了卡拉加斯地区的花岗质深成岩,锆石U-Pb测年获得的花岗岩207Pb/206Pb表面年龄集中在2 899~2 831 Ma、2 742~2 622 Ma和1 919 Ma 3个时期,认为南美克拉通在经历了古太古代陆核形成、中太古代古大陆增生后,在太古宙末期和古元古代发生了二阶段的克拉通化过程,在中元古代—新元古代克拉通开始被破坏。通过对比南美克拉通与华北克拉通的早期演化过程,推测南美克拉通的构造演化早期受地幔柱控制,晚期转变为以板块构造为主导的大陆增生机制。研究有助于深入认识和对比矿集区成矿过程及其成矿效应。
    Abstract: The Archean metamorphic basement is developed in Carajás area of Brazil, which is one of the most abundant mineral deposits and the highest degree of resource accumulation deposits in the world. A large amount of charnockite, (trondhjemite-tonalite-granodiorite,TTG) rock series and metamorphic plutons that haven't completely disintegrated exsit in the crystalline basement of Archean granite-greenstone, with large perception diffe-rence. The correct division and fine study of igneous rocks are important means to further understand the evolution of South American Craton. Based on the investigation of metamorphic basement intrusive rocks, and combined with previous data, the authors decomposed it into the charnockite of Paleoarchean, the mafic-ultramafic rocks and the TTG gneiss suite of Mesoarchean, and the mafic-ultramafic rocks, the TTG gneiss suite, the syntectonic granite and the post-tectonic granite of Neoarchean, and the alkaline granite of Paleoproterozoic. The granitic plutons in Carajás area were comprehensively analyzed with geological, geochemical and geochronological methods. The 207Pb/206Pb surface ages of granite by Zircon U-Pb method is concentrated in three periods: 2 899~2 831 Ma, 2 742~2 622 Ma and 1 919 Ma. After the formation of continental nucleus in Paleoarchean and continental hyperplasia in Mesoarchean, South America craton experienced two stage cratonic consolidation process in Late Archaean and Paleoproterozoic, and it began to destroyed in Mesoproterozoic and Neoproterozoic. Comparing the similarities and differences between North China Craton and South America Craton, the authors presumed that the mechanism of tectonic evolution was controlled by mantle plume tectonics in the early continental tectonics, and transformed into tectonics accretion mechanism dominated by plate motion. This research is beneficial to deepening knowledge and comparison of metallogenic process and its effects in ore concentrate area.
    • HTML全文
    • 参考文献(30)
  • [1] Santos J O S,Hartmann L A,Gaudette H E,et al.A New understanding of the provinces of the Amazon Craton based on integration of field mapping and U-Pb and Sm-Nd geochronology[J].Gondwana Research,2000,3(4):453-488.
    [2] Grainger C J,Groves D I,Tallarico F H B,et al.Metallogenesis of the Carajás mineral province,southern Amazon Craton,Brazil:Varying styles of Archean through Paleoproterozoic to Neoproterozoic base- and precious-metal mineralisation[J].Ore Geology Reviews,2008,33(3/4):451-489.
    [3] 卢民杰,朱小三,郭维民.南美安第斯地区成矿区带划分探讨[J].矿床地质,2016,35(5):1073-1083.
    Lu M J,Zhu X S,Guo W M.Division of Andean metallogenic domain in South America[J].Mineral Deposits,2016,35(5):1073-1083.
    [4] 曾勇,郭维民,姚春彦,等.巴西卡拉加斯地区基底杂岩的地质特征与时代约束[J].中国地质,2017,44(4):766-780.
    Zeng Y,Guo W M,Yao C Y,et al.Geological features and age constraint of basement complex in Carajás province of Brazil[J].Geology in China,2017,44(4):766-780.
    [5] Souza Z S,Potrel A,Lafon J M,et al.Nd,Pb and Sr isotopes in the Identidade Belt,an Archaean greenstone belt of the Rio Maria region (Carajás Province,Brazil):Implications for the Archaean geodynamic evolution of the Amazonian Craton[J].Precambrian Research,2001,109(3/4):293-315.
    [6] Avelar V G,Lafon J M,Correia F C Jr,et al.O magmatismo arqueano da região de Tucumã-Província Mineral de Carajás:Novos resultados geocronológicos[J].Revista Brasileira de Geociências,1999,29(4):453-460.
    [7] Moreto C P N,Monteiro L V S,Xavier R P,et al.Mesoarchean (3.0 and 2.86 Ga) host rocks of the iron oxide-Cu-Au Bacaba deposit,Carajás Mineral Province:U-Pb geochronology and metallogenetic implications[J].Mineralium Deposita,2011,46(7):789-811.
    [8] Pidgeon R T,Macambira M J B,Lafon J M.Th-U-Pb isotopic systems and internal structures of complex zircons from an enderbite from the Pium Complex,Carajás Province,Brazil:Evidence for the ages of granulite facies metamorphism and the protolith of the enderbite[J].Chemical Geology,2000,166(1/2):159-171.
    [9] Feio G R L,Dall'Agnol R,Dantas E L,et al.Archean granitoid magmatism in the Canaã dos Carajás area:Implications for crustal evolution of the Carajás province,Amazonian craton,Brazil[J].Precambrian Research,2013,227:157-185.
    [10] Silva Leite A A,Dall'Agnol R,Macambira M J B,et al.Geologia e geocronologia dos granitóides arqueanos da região de Xinguara-PA e suas implicações na evolução do Terreno Granito-Greenstone de Rio Maria,cráton amazônico[J].Revista Brasileira de Geociências,2004,34(4):447-458.
    [11] Mansur E T,Filho C F F.Magmatic structure and geochemistry of the Luanga Mafic-Ultramafic Complex:Further constraints for the PGE-mineralized magmatism in Carajás,Brazil[J].Lithos,2016,266-267:28-43.
    [12] Sardinha A S,de Mesquita Barros C E,Krymsky R.Geology,geochemistry,and U-Pb geochronology of the Archean (2.74 Ga) Serra do Rabo granite stocks,Carajás Metallogenetic Province,northern Brazil[J].Journal of South American Earth Sciences,2006,20(4):327-339.
    [13] Martin H,Smithies R H,Rapp R,et al.An overview of adakite,tonalite-trondhjemite-granodiorite (TTG),and sanukitoid:Relationships and some implications for crustal evolution[J].Lithos,2005,79(1/2):1-24.
    [14] 黎彤,倪守斌.中国大陆岩石圈的化学元素丰度[J].地质与勘探,1997(1):31-37.
    Li T,Ni S B.Element abundances of the continental lithosphere in China[J].Geology and Prospecting,1997(1):31-37.
    [15] Taylor S R,McLennan S M.The Continental Crust:Its Composition and Evolution.An Examination of the Geochemical Record Preserved in Sedimentary Rocks[M].Oxford:Blackwell Scientific Publications,1985.
    [16] 卢俊浩,张达,狄永军,等.赣东北船坑—铜山推覆构造及其与同构造成矿岩浆的关系[J].中国地质调查,2016,3(3):29-37.
    Lu J H,Zhang D,Di Y J,et al.The relationship between thrust-fault and the syntectonic magmatism in Chuankeng-Tongshan,northeastern Jiangxi Province[J].Geological Survey of China,2016,3(3):29-37.
    [17] 刘勇胜,胡兆初,李明,等.LA-ICP-MS在地质样品元素分析中的应用[J].科学通报,2013,58(36):3753-3769.
    Liu Y S,Hu Z C,Li M,et al.Applications of LA-ICP-MS in the elemental analyses of geological samples[J].Chinese Science Bulletin,2013,58(32):3863-3878.
    [18] 李怀坤,耿建珍,郝爽,等.用激光烧蚀多接收器等离子体质谱仪(LA-MC-ICP MS)测定锆石U-Pb同位素年龄的研究[J].矿物学报,2009,29(S1):600-601.
    Li H K,Geng J Z,Hao S,et al.The isotope age study of U-Pb in zircon through LA-MC-ICPMS[J].Acta Mineralogica Sinica,2009,29(S1):600-601.
    [19] 唐华,陈永东,魏龙,等.冈底斯南缘拉隆地区变形花岗岩地质特征及其构造意义[J].中国地质调查,2020,7(4):85-94.
    Tang H,Chen Y D,Wei L,et al.Geological characteristics and tectonic implications of the deformed granite in Lalong area in the southern margin of Gangdise[J].Geological Survey of China,2020,7(4):85-94.
    [20] Siepierski L,Filho C F F.Spinifex-textured komatiites in the south border of the Carajas ridge,Selva Greenstone belt,Carajás Province,Brazil[J].Journal of South American Earth Sciences,2016,66:41-55.
    [21] Torresi I,Xavier R P,Bortholoto D F A,et al.Hydrothermal alteration,fluid inclusions and stable isotope systematics of the Alvo 118 iron oxide-copper-gold deposit,Carajás Mineral Province (Brazil):Implications for ore genesis[J].Mineralium Deposita,2012,47(3):299-323.
    [22] 曾勇,郭维民,姚春彦,等.巴西卡拉加斯地区氧化铁型铜-金矿床研究进展[J].地质科技情报,2013,32(5):72-78.
    Zeng Y,Guo W M,Yao C Y,et al.Research progress on iron oxide-Cu-Au deposit in Carajás,Brazil[J].Geological Science and Technology Information,2013,32(5):72-78.
    [23] 侯增谦. 大陆碰撞成矿论[J].地质学报,2010,84(1):30-58.
    Hou Z Q.Metallogensis of continental collision[J].Acta Geologica Sinica,2010,84(1):30-58.
    [24] 曾勇,郭维民,项红莉,等.巴西卡拉加斯地区大规模铁-铜-金多金属矿床的成矿作用[J].矿床地质,2015,34(4):828-841.
    Zeng Y,Guo W M,Xiang H L,et al.Massive Fe-Cu-Au polymetallic deposits metallogenesis in Carajás mineral province of Brazil[J].Mineral Deposits,2015,34(4):828-841.
    [25] 沈莽庭,徐鸣,高天山,等.巴西圣弗朗西斯科克拉通Ibitiara岩体的锆石U-Pb年代学、地球化学特征及地质意义[J].世界地质,2020,39(1):1-15.
    Shen M T,Xu M,Gao T S,et al.Zircon U-Pb geochronology,geochemical characteristics and geological implication of Ibitiara pluton from Sãn Francisco Craton in Brazil[J].Global Geology,2020,39(1):1-15.
    [26] 万渝生,董春艳,颉颃强,等.华北克拉通太古宙研究若干进展[J].地球学报,2015,36(6):685-700.
    Wan Y S,Dong C Y,Xie H Q,et al.Some progress in the study of Archean basement of the North China Craton[J].Acta Geoscientica Sinica,2015,36(6):685-700.
    [27] 翟明国. 华北克拉通的形成以及早期板块构造[J].地质学报,2012,86(9):1335-1349.
    Zhai M G.Evolution of the North China Craton and early plate tectonics[J].Acta Geologica Sinica,2012,86(9):1335-1349.
    [28] 张传林,马华东,李怀坤,等.塔里木北缘库鲁克塔格地区古元古界——祝贺芮行健先生90华诞[J].华东地质,2022,43(2):133-140.
    Zhang C L,Ma H D,Li H K,et al.Paleoproterozoic in Quruqtagh terrane in Northern Tarim[J].East China Geology,2022,43(2):133-140.
    [29] 李三忠,李玺瑶,戴黎明,等.前寒武纪地球动力学(Ⅵ):华北克拉通形成[J].地学前缘,2015,22(6):77-96.
    Li S Z,Li X Y,Dai L M,et al.Precambrian geodynamics (Ⅵ):Formation of North China Craton[J].Earth Science Frontiers,2015,22(6):77-96.
    [30] 王天刚,郑璐,朱意萍,等.澳大利亚前寒武纪超大陆演化与成矿作用[J].华东地质,2022,43(3):255-267.
    Wang T G,Zheng L,Zhu Y P,et al.Precambrian supercontinent evolution and metallogeny of Australia[J].East China Geology,2022,43(3):255-267.
    • 相关文章
    • 施引文献
    • 资源附件(0)
计量
  • 文章访问数:  227
  • HTML全文浏览量:  0
  • PDF下载量:  323
  • 被引次数: 0
出版历程
  • 收稿日期:  2022-09-21
  • 修回日期:  2023-03-14
  • 刊出日期:  2023-10-19

目录

摘要
HTML全文
    参考文献(30)
    相关文章
    施引文献
    资源附件(0)

    /

    返回文章
    返回

    网站访问总数: 8197

    网站版权所有 ©《中国地质调查局》编辑部 

    地址:北京市海淀区学院路29号邮政编码:100083京ICP备05064691号-3

    电话:010-66554889/66554890/66554746/66554885电子邮箱:zgdzdc@126.com

    本系统由 北京仁和汇智信息技术有限公司 开发  百度统计

    x 关闭 永久关闭