华北克拉通东北部新元古代花岗岩岩浆活动和地球动力学过程

IF 3.9 1区 地球科学 Q1 GEOSCIENCES, MULTIDISCIPLINARY Geological Society of America Bulletin Pub Date : 2024-05-22 DOI:10.1130/b37584.1
Guozheng Sun, Shuwen Liu, Sanzhong Li, Han Bao, Wei Wang, Rongrong Guo, Jinghao Fu, Lei Gao, Yalu Hu, Xi Wang, Shengyao Yu, Liming Dai
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引用次数: 0

摘要

阿新世花岗岩岩石的组成从早期阿新世(4-3 Ga)的主要为黑云母-黑云母-花岗闪长岩(TTG)片麻岩转变为晚期阿新世(3.0-2.5 Ga)的多样化花岗岩岩石组合,标志着早期地球地球动力过程的关键转变。然而,由于对不同时期不同花岗岩组合的岩石成因特征及其地壳与地幔之间的相互作用知之甚少,这一重大转变的原因仍是一个谜。我们利用新元古代(2.7-2.5 Ga)花岗岩的时空分布、岩性关联、化学成分和岩石成因的变化,以及推断的华北克拉通东北部辽宁东部山脉(ELR)的相关地壳-地幔相互作用,来探讨这一地球动力学转变。新元古代早期(约2.7 Ga)的东辽岭花岗岩以TTG片麻岩为主,新元古代晚期(2.6-2.5 Ga)的东辽岭花岗岩类型和成分变得更加复杂,转变为TTG和富含更多K2O的花岗岩。TTGs可细分为高钙组和低钙组:2.71-2.68Ga高Ca组TTG岩浆源于俯冲幼年洋壳的部分熔融,而低Ca组TTG岩浆则源于高Ca组TTG岩浆的分馏结晶。岩浆源的化学成分对2.60-2.50 Ga TTG岩浆活动起着主导作用:高Ca组和低Ca组TTG岩浆分别来自低K岩浆岩和英安岩。2.58-2.49Ga富K2O花岗岩可分为三个岩石成因系列:(1)高钙镁组富K2O花岗岩岩浆来源于高K岩浆岩的部分熔融;(2)低钙镁组富K2O花岗岩岩浆来源于沉积岩的部分熔融;(3)过渡组富K2O花岗岩岩浆来源于元古宙。2.71-2.68Ga过渡组岩浆生成于一个岛弧带,俯冲板块熔融和随后的岩浆分异是过渡组岩浆形成的主要机制。2.60-2.50Ga的多样化花岗岩是在活动大陆边缘下的大洋-大陆俯冲过程中形成的;复杂的大洋板块俯冲和弧-弧、弧-大陆碰撞造就了新元古代晚期花岗岩岩浆的多样性。
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Neoarchean granitoid magmatism and geodynamic process in the northeastern North China craton
The composition of Archean granitoid rocks changed from predominantly tonalite-trondhjemite-granodiorite (TTG) gneisses in the early Archean (4−3 Ga) to diversified granitoid rock assemblages in the late Archean (3.0−2.5 Ga), marking a crucial transformation in the geodynamic processes of early Earth. However, the reason for this major transition remains enigmatic because the petrogenetic features of different granitoid assemblages and their crust-mantle interactions during different periods are poorly understood. We use variations in the spatial-temporal distribution, lithological association, chemical composition, and petrogenesis of Neoarchean (2.7−2.5 Ga) granitoids and inferred correlative crust-mantle interactions in the Eastern Liaoning Range (ELR) of the northeastern North China craton to explore this geodynamic transition. The early Neoarchean (ca. 2.7 Ga) ELR granitoids were dominated by TTG gneisses, and the late Neoarchean (2.6−2.5 Ga) ELR granitoid typology and compositions became more complex, changing into TTGs and more K2O-rich granitoid rocks. The TTGs can be subdivided into a high-Ca group and a low-Ca group: The 2.71−2.68 Ga high-Ca group TTG magma originated from partial melting of subducted juvenile oceanic crust, and the low-Ca group TTG magma was derived from fractionation crystallization of the high-Ca group TTG magma. The chemical composition of the magmatic sources played a dominant role on the 2.60−2.50 Ga TTG magmatism: the high-Ca and low-Ca group TTG magmas came from low-K mafic rocks and tonalites, respectively. The 2.58−2.49 Ga K2O-rich granitoids can be divided into three petrogenetic series: (1) The high-Ca-Mg group K2O-rich granitoid magma originated from partial melting of high-K mafic rocks, (2) the low-Ca-Mg group K2O-rich granitoid magma was derived from partial melting of sedimentary rocks, and (3) the transition group K2O-rich granitoid magma was sourced from metagreywackes. The 2.71−2.68 Ga TTGs were generated in an island arc belt, and subducted slab melting and subsequent magmatic differentiation were the dominant mechanisms of the TTG magmatism. The 2.60−2.50 Ga diversified granitoids were formed in the oceanic-continental subduction process under the active continental margin; the complicated oceanic slab subduction and arc-arc and arc-continent collisions contributed to the diversity of late Neoarchean granitoid magmatism.
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来源期刊
Geological Society of America Bulletin
Geological Society of America Bulletin 地学-地球科学综合
CiteScore
9.30
自引率
8.20%
发文量
159
审稿时长
4-8 weeks
期刊介绍: The GSA Bulletin is the Society''s premier scholarly journal, published continuously since 1890. Its first editor was William John (WJ) McGee, who was responsible for establishing much of its original style and format. Fully refereed, each bimonthly issue includes 16-20 papers focusing on the most definitive, timely, and classic-style research in all earth-science disciplines. The Bulletin welcomes most contributions that are data-rich, mature studies of broad interest (i.e., of interest to more than one sub-discipline of earth science) and of lasting, archival quality. These include (but are not limited to) studies related to tectonics, structural geology, geochemistry, geophysics, hydrogeology, marine geology, paleoclimatology, planetary geology, quaternary geology/geomorphology, sedimentary geology, stratigraphy, and volcanology. The journal is committed to further developing both the scope of its content and its international profile so that it publishes the most current earth science research that will be of wide interest to geoscientists.
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