晚太古代Sanukite（赞岐岩）与地球早期演化

Shirey and Hanson(1984)将某些太古代的高镁闪长岩套称为sanukite(赞岐岩),类似于日本中新世(11～15Ma)Setouchi火山岩带的高镁安山岩。Sanukitoids由闪长岩-二长闪长岩-花岗闪长岩组成,不同于TTC岩套(奥长花岗岩-英云闪长岩-花岗闪长岩)。Sanukitoids具有下列地球化学特征:富Mg,Mg~#>0.60,Ni和Cr>100μg/g,Sr和Ba>500μg/g,LREE富集(大于球粒陨石100倍),无Eu异常。高镁安山岩在太古代很少见,而其相应的侵入岩高镁闪长岩或sanukitoids,虽然数量也很少,但却是各地晚太古代地体中随处可见的。Sanukitoids的原始岩浆是交代的地幔楔部分熔融形成的,随后可能经历了广泛的分离结晶作用。TTC和sanukitoids岩套可以相伴产出,二者均与板片熔融有关,TTG与其直接有关,sanukitoids可能与其间接有关。全球Sanukitoids主要集中在晚太古代时期,可能暗示板块的消减作用在～3.0Ga以后才起了重要的作用。     

广西大瑶山东南缘侏罗纪埃达克质花岗岩的特征、成因及构造意义

对钦杭结合带西南段大瑶山东南缘的中晚侏罗世埃达克质花岗岩（165~153 Ma）进行了岩石学、地球化学研究,并探讨了埃达克质和TTG岩类的特征属性。岩石SiO₂含量63.76%~72.13%,总体具高Al₂O₃（Al₂O₃≥15%）、低MgO （<3%）,亏损重稀土元素（HREE）、正Eu异常或弱的负Eu异常,低Y （≤18×10^-6）和Yb （≤1.9×10^-6）,高Sr （>300×10^-6）和Sr/Y值（>20）等埃达克岩独特的地球化学特征。结合区域构造演化分析认为,该侏罗纪埃达克质花岗岩形成于陆内伸展构造背景,为大陆板内加厚（隆起区）的下地壳底部岩石部分熔融的产物,属大陆板内环境I型花岗岩。具有类似于低镁安山岩/闪长岩系列（LMA）和镁安山岩/闪长岩系列（MA）两种高压型TTG亚类的属性,为古俯冲增生带下地壳弧型岩石熔融的继承性特征,与中生代古太平洋俯冲板片熔融过程无关,属非俯冲成因的埃达克/TTG岩类。其空间上与大瑶山东南缘早古生代俯冲增生带高度重合,且与早古生代TTG侵入岩组合紧密相邻,提示它们可能源自于早古生代洋壳俯冲带或大陆边缘弧下地壳玄武质岩石的部分熔融,因而具有洋俯冲成因的特征属性。     

吉林省太古宙TTG岩类固结的温度压力条件

吉林省太古宙ＴＴＧ岩类型成于变质上壳岩系麻粒岩相变质作用晚期阶段。详细的岩相学研究表明，ＴＴＧ岩类中存在岩浆结晶的绿帘石，角闪石和黑云母等。绿帘石的出现标志了一定的压条件。     

TTG岩套的成因及其形成环境

TTG岩套是一类包含了三种岩性的岩石组合,即英云闪长岩(tonalite)—奥长花岗岩(trondhjemite)—花岗闪长岩(granodiorite)。TTG岩套的规模在太古宙最大,是早期陆壳的主体且在各地质历史时期均有发育。该岩石组合是岩石学定名,多数样品的地球化学特征相似:富Na,高Al2O3(平均15%),低Mg、Ni、Cr,富集LREE、亏损HREE、高Sr、低Y、低Yb且无明显的负Eu异常。其微量元素特征与Adakite(高锶低钇中酸性岩,"埃达克岩")类似。目前多数学者认同其为变玄武质岩石部分熔融后的熔体,主要争论在于其源岩的变质程度。笔者认为TTG岩套的源区不应局限于某个变质相,而是涵盖了较大的P—T范围。对于其形成环境的探讨,笔者认为应该以地球演化不同时期的地球动力学背景为前提,盲目地"将今论古"是不合理的。本文在总结前人研究成果的基础上提出3.8Ga之前的TTG岩套可能是在板块构造未启动的非俯冲条件下形成的;3.8~1.9Ga的TTG岩套产生在发育俯冲式板块构造且板块构造具有间歇式特点的背景下,此时可能既存在非俯冲环境下产出的TTG岩套也存在俯冲环境下产出的TTG岩套,而且其产出应该具有幕式特征;古元古代之后的TTG岩套可能无一例外均是俯冲板片熔融的产物。     

地球早期大陆地壳的形成与演化

现代地球岩石圈主要由镁铁质上地幔和长英质地壳两个储集层组成,研究大陆地壳的形成和演化对揭示地球早期地质过程和物质循环、厘定板块构造启动时限具有重要意义。冥古宙—始太古代具有更高的地幔潜能温度和地温梯度,岩浆海冷却形成薄的原始地壳;大洋岩石圈表现为韧性,主要构造机制应为停滞盖层模式,有地幔柱参与。太古宙片麻岩中奥长花岗岩—英云闪长岩—花岗闪长岩(TTG)的出现标志着镁铁质原始地壳向长英质陆壳转变的开始。本文总结了地球早期停滞盖层模式到现代板块构造模式下含水玄武岩部分熔融、结晶分异形成大陆地壳的过程,主要包含幔源岩浆停滞盖层(“自下而上”的热管火山岩和“自上而下”的深成侵入岩构造模式)、增厚镁铁质地壳部分熔融、俯冲洋壳、岛弧及洋底高原部分熔融模式;陆壳的破坏和消减主要受陨石撞击、分层沉降、重力不稳导致拆沉控制;板块构造的出现进一步促进了地球内部的热量扩散,俯冲作用加快了洋壳和陆壳之间的物质循环。最后,结合太古宙变质岩、古老克拉通岩石学特征和锆石Hf、O及全岩Nd、Sr、Ar、Ti同位素组成,讨论了陆壳的形成时间和演化过程：3.0 Ga之前形成了现有陆壳体积的60%～70%,厚度约为20～4...     

地球早期大陆地壳的形成与演化

现代地球岩石圈主要由镁铁质上地幔和长英质地壳两个储集层组成,研究大陆地壳的形成和演化对揭示地球早期地质过程和物质循环、厘定板块构造启动时限具有重要意义。冥古宙—始太古代具有更高的地幔潜能温度和地温梯度,岩浆海冷却形成薄的原始地壳;大洋岩石圈表现为韧性,主要构造机制应为停滞盖层模式,有地幔柱参与。太古宙片麻岩中奥长花岗岩—英云闪长岩—花岗闪长岩（TTG）的出现标志着镁铁质原始地壳向长英质陆壳转变的开始。本文总结了地球早期停滞盖层模式到现代板块构造模式下含水玄武岩部分熔融、结晶分异形成大陆地壳的过程,主要包含幔源岩浆停滞盖层（“自下而上”的热管火山岩和“自上而下”的深成侵入岩构造模式）、增厚镁铁质地壳部分熔融、俯冲洋壳、岛弧及洋底高原部分熔融模式;陆壳的破坏和消减主要受陨石撞击、分层沉降、重力不稳导致拆沉控制;板块构造的出现进一步促进了地球内部的热量扩散,俯冲作用加快了洋壳和陆壳之间的物质循环。最后,结合太古宙变质岩、古老克拉通岩石学特征和锆石Hf、O及全岩Nd、Sr、Ar、Ti同位素组成,讨论了陆壳的形成时间和演化过程： 3.0 Ga之前形成了现有陆壳体积的60%~70%,厚度约为20~40 km;3.0~2.5 Ga,地壳改造速率明显增加,陆壳生长和破坏速率达到动态平衡,表明全球性现代板块构造体制逐渐成为控制大陆形成、裂解和陆壳演化的主要因素。     

华北克拉通怀安陆块新太古代低铝和高铝TTG片麻岩的地球化学特征与成因

英云闪长岩-奥长花岗岩和花岗闪长岩(简称TTG)是太古宙高级变质地体的主要物质组成,对深入理解早期大陆生长及其机制具有重要的科学意义。目前,人们对其成因过程与机制仍有不同认识。本文以怀安陆块中广泛分布的TTG片麻岩为例,探讨其成因演化和机制。研究区位于华北克拉通中北部,主要由新太古代英云闪长岩及少量奥长花岗岩、花岗闪长岩组成。我们从该区识别出富硅富重稀土和负铕异常的低铝奥长花岗质片麻岩,形成时代与广泛分布的高铝TTG质片麻岩一致(锆石SHRIMP U-Pb年龄2.53Ga)。岩石地球化学数据显示,低铝奥长花岗质片麻岩的主量元素具有富SiO 2(76%~79%),低Al2O3(11.01%~12.61%)、CaO(1.27%~1.59%)、MgO(0.74%~0.24%)和Mg#(18~53)等特征,而广泛分布的高铝TTG岩系的主量元素含量变化大,例如,SiO 2=63%~77%、Al2O3=13.2%~17.77%、CaO=1.8%~5.78%、MgO=0.18%~3.84%和Mg#=35~64。微量元素方面,低铝奥长花岗质片麻岩具有Eu/Eu*负异常(除1个样品为弱正异常1.38外,其余样品分布在0.59~0.44),富集重稀土((La/Yb)N=4~7,(Gd/Yb)N=0.36~1.27),而高铝TTG岩系从弱负铕异常到正异常(Eu/Eu*=0.8~5.35),轻重稀土分馏明显((La/Yb)N=10~103、(Gd/Yb)N=1.97~5.72)。在微量蛛网图中二者的区别除重稀土明显存在区别外,低铝奥长花岗质片麻岩显示出Ba、Sr的相对亏损,而高铝TTG岩系则相反。二者Lu/Hf比值差异明显,低铝奥长花岗质片麻岩变化在0.1~0.16,而高铝TTG岩系变化在0.01~0.07。在Lu/Hf与相关元素以及SiO 2与相关元素哈克图解中,二者差异更加明显,表明它们之间不存在直接的成因联系。综合锆石U-Pb、Lu-Hf同位素特征以及岩石地球化学特征,我们认为低铝奥长花岗质片麻岩是低压下由新太古代新生基性地壳物质低程度部分熔融而成,源区残留矿物相以辉石+斜长石为主,岩浆可能存在过独居石的分异作用。高铝TTG岩系主要由新生基性地壳在相对高压下部分熔融而成,源区残留相以石榴石+辉石+角闪石以及无或少量斜长石为特征。岩浆经历过角闪石和辉石分离结晶作用,铕正异常增大的现象可能与斜长石堆晶有关。本区同时形成高铝和低铝TTG岩系的机制还需深入研究。俯冲机制、地幔柱机制以及二者共同作用等机制均能解释TTG的成因。依据本区同期还形成大量辉长质-闪长质岩浆和稍晚(2.5~2.45Ga)形成的钾质花岗岩类岩浆的侵入活动,我们认为本区高铝和低铝TTG岩系分别来自底侵作用导致的下地壳不同深度不同程度的部分熔融有关。引起底侵作用的机制可能与地幔柱或地幔柱与板块俯冲共同作用有关。     

REE-HFSE distribution/partitioning between garnetiferous restites and TTG from Nademavinapura area,Western Dharwar craton

The major part of the Peninsular Gneiss in Dharwar craton is made up of Trondjhemite-Tonalite-Granodiorite (TTG) emplaced at different periods ranging from 3.60 to 2.50 Ga. The sodic-silicic magma precursors of these rocks have geochemical features characteristic of partial melting of hydrated basalt. In these TTGs, enclaves of amphibolites (± garnet) are abundant. These restites are considered to be the residue of a basaltic crust after its partial melting. A detailed study of these (residue) enclaves reveals textures formed due to the process of partial melting. Major, trace and REE analysis of these residue enclaves and the melt TTGs and microprobe analysis of the coexisting minerals show partitioning of REE and HFSE between the precursor melt of TTGs and the upper amphibolite facies residues. Formation of garnetiferous amphibolites with biotite, Cpx and plagioclase consequent to melting, has squeezed the original MORB type of basaltic crust and given rise to the TTGs, depleted in Y, Yb, K₂O, MgO, FeO, TiO₂ and enriched in La, Th, U, Zr and Hf. Coevally during the process of melting, the hydrated basalt was depleted in Na₂O, Al₂O₃, LREE, Th, U and enriched in K₂O, MgO, Nb, Ti, Yb, Y, Sc, Ni, Cr and Co. Mineral chemistry of co-existing garnet-biotite and amphibole-plagioclase in these amphibolitic (restite) enclaves indicates an average temperature of 700 ± 50° C and pressure of 5 ± 1 Kbar. These data are inferred to indicate that during the garnet stability field metamorphism, effective fractionation of HREE and HFSE has taken place between the restites having Fe-Mg silicates, ilmenites and the extracted melt generated from the MORB type of hydrated basalt. These results are strongly substantiated by the reported melting experiments on hydrated basalts.     

Geochemistry of granitoids of Bilgi area,northern part of eastern Dharwar craton,southern India — Example of transitional TTGs derived from depleted source

Mildly deformed granitoids exposed around Bilgi in the northernmost part of the eastern Dharwar craton are divided into two groups viz. granodiorites and monzogranites. The granodiorites contain microgranular enclaves and amphibolite xenoliths, and show low-Al TTG affinity with high SiO₂ (71–74 %), Na₂O, Y and Sr/Y, moderate to moderately high Mg#, Cr and Ni, low to moderate LILE, and low Nb and Ta. However, compared to similar TTGs from different cratons the Bilgi granodiorites have distinctly higher K₂O, K₂O/Na₂O, Rb and lower REE and Th. The amphibolite xenoliths are characterized by variable enrichment of K₂O, Rb, Ba and Th and depletion of Ti, Zr and P compared to MORB. The microgranular enclaves are quartz diorite to granodiorite in composition with high Mg, Ni and Cr, and compared to MORB, are enriched in LILE and depleted in Ti and Y. The monzogranites, compared to the granodiorites, display higher SiO₂, K₂O and Rb with lower Mg#, although still maintaining the high Na₂O, Ni and Cr and low REE character. The Bilgi granodiorites are explained as transitional TTGs late synkinematic with respect to regional deformation. Geochemical signatures and regional geological set up suggest that they are probably derived from partial melting of a highly depleted slab material (metabasalt) followed by variable contamination or assimilation of intermediate crustal rocks in a subduction zone set up. Late stage fluid activity on the granodioritic magma is probably responsible for the generation of monzogranites. The amphibolite xenoliths predate the granodiorites and possibly represent fragments of a schist belt carried away by the granitic magma. They are probably island arc basalt derived from mantle source that has been metasomatized by slab-derived fluids. The microgranular enclaves are coeval with the Bilgi granodiorites and also likely to be island arc magmas derived from mantle variably enriched in slab-derived and within-plate components.