浙东白垩纪北漳和梁弄花岗岩体及其暗色岩石包体研究

浙东地区晚中生代花岗岩类在岩性上分为三类：花岗岩-二长花岗岩、钾长花岗岩和A型花岗岩。对后两类花岗岩已有较多研究,但对前一类,尤其是二长花岗岩的研究还较薄弱。选择浙东具代表性的北漳和梁弄二长花岗岩体及其所含暗色岩石包体,以及共生的石英闪长岩类,通过系统的岩石学与地球化学对比研究,提出浙东二长花岗岩属准铝质、高钾钙碱性Ⅰ型花岗岩类演化系列,暗色岩石包体是由花岗质岩浆在深部析离出的镁铁质微粒包体(MME),成分特征类似于石英闪长岩,说明三者具内在成因联系,均与俯冲作用关系密切。     

赣南营前岩体的年代学、地球化学、Sr-Nd-Hf同位素组成及其地质意义

赣南营前岩体由早期似斑状花岗闪长岩和晚期细粒黑云母花岗岩组成,在前者中普遍发育暗色基性包体。SHRIMP锆石U-Pb测年显示似斑状花岗闪长岩为172.2±3.1Ma,细粒黑云母花岗岩为168±3Ma,包体为167.6±3.3Ma。所有的岩石均为钙碱性系列,稀土元素显示LREE富集,HREE亏损,Eu负异常并不明显的特征,Nb-Ta负异常显示壳源物质的特征。晚期细粒黑云母花岗岩、早期似斑状花岗闪长岩、暗色包体的(87Sr/86Sr)i和εNd(t)值分别为0.70885～0.70965、0.71058～1.46393、0.70788～0.70923和-6.38～-5.31、-6.51～-5.17、-5.47～-4.31;锆石εHf(t)值分别为-12.4～-5.7、-9.2～-4.2、-9.4～+0.1。结合岩相学、地球化学研究,初步认为营前岩体的两期花岗质岩石源于地壳重熔,地幔底侵导致地壳熔融形成营前岩体,基性岩浆加入到未冷却的酸性岩浆中形成了目前所见到的暗色包体。结合区域上的研究资料,认为中侏罗世期间,沿"十杭"断裂带及与其相平行的一些深断裂发生了板块的撕裂,这些缝合带是岩石圈相对薄弱的地带,有利于幔源物质底侵上升以及壳幔相互作用。     

东天山哈密地区早二叠世花岗岩体及镁铁质包体的年代学, 岩石地球化学特征及其构造意义

花岗岩中包体是区域构造与深部过程研究结合的良好窗口,对研究花岗岩的成因和壳-幔相互作用有非常重要的意义。东天山南山口黑云母二长花岗岩中广泛发育镁铁质包体。主量元素组成上,寄主花岗岩岩具有中酸性、准铝质、富碱、富钾等特征;镁铁质包体则偏基性、贫钾。微量和稀土元素组成上,富集Rb、K、Th、U,贫Sr、P、Nb、Ta、Ti,且Zr、Hf含量相对较高,具中-强的铕负异常(0.46~0.57)。镁铁质包体与寄主岩具有相似的微量元素特征,但相对富集Sr、P,贫Zr、Hf,铕负异常中等或不明显(0.80~0.93)。闪长质包体属于同源包体,为寄主花岗岩同源母岩浆经结晶分异形成的早期产物。运用LA-ICP-MS锆石U-Pb定年技术,该南山口岩体暗色镁铁质微粒包体与寄主黑云母二长花岗岩的锆石U-Pb年龄分别为298.2±2.0Ma和294.0±2.7Ma,包体与寄主岩样品具有相似的Hf同位素组成,暗示其母岩浆来自新元古代晚期和早古生代亏损地幔中分离的新生地壳。该高钾钙碱性的花岗岩及其包体可能形成于东天山后碰撞背景下的板片断离后引起软流圈上涌,底侵体带来的热能使得新元古代晚期和早古生代的新生地壳发生部分熔融。     

北京房山侵入岩体：微量元素、稀土元素及Sr同位素组成对其成因的制约

房山岩体是由 3次脉动式侵位形成的复式岩体 ,不同期次侵位的岩石及其中的包体来自相同的岩浆源区 ,为下地壳的中、基性火成岩。全岩 矿物Rb Sr等时线年龄为 12 6± 3Ma。第 1期至第 2期 ,主要是由以斜长石为主的矿物平衡结晶造成的 ;第 2期至第 3期 ,则可能是批式熔融的结果。包体的成因机制可能不止一种 :英安玢岩质包体和石英粗安玢岩质包体可能分别代表第 2期和第 3期脉动式侵入体的冷凝壳 ;石英正长岩包体则可能代表该侵入体演化到最后的产物 ;而石英闪长质和石英二长闪长质包体则可能为同源岩浆早期结晶的产物。     

内蒙古解放营子花岗闪长岩岩浆混合机制——来自斜长石和角闪石的矿物化学证据

为揭示华北克拉通北缘中晚三叠世解放营子花岗闪长岩的岩浆混合机制,对寄主岩石和镁铁质包体中斜长石和角闪石开展了电子探针分析.分析结果显示,多斑和少斑包体边部的斜长石斑晶发育An值增加的突变环带,环带的An值为32～46,明显高于核部和边部斜长石的An值(18～31),而核部的An值与寄主岩石中斜长石的An值一致,该特征指...     

试析安哥拉卡宾达飞地的跨界族群问题及治理困境

跨界族群以及由此造成的分离主义运动一直是民族学、社会学与国际关系等学科研究的重点议题。本研究对安哥拉卡宾达飞地分离主义运动的研究着重探讨特殊地理位置为安哥拉政府带来的治理困境。对卡宾达分离主义运动的发展历史进行回顾,发现跨界族群问题是卡宾达分离主义运动产生的根源,而飞地属性则从不同角度增加了安哥拉在治理该问题上的难度,主要表现为未能使当地人产生对安哥拉的国家认同,大幅降低了外部干涉难度以及难以满足该地居民的发展诉求。本研究还认为跨界族群的分离主义思潮看似合理,但其文化特殊性并不一定能转化为分离主义运动的政治合理性。虽然非洲国家很多现有边界存在不合理之处,但对它的改变未必能让跨界族群获得更好的社会经济发展。另外,边界对分离主义组织运行模式的影响也是一个值得深入研究的议题。     

桂东北大宁岩体中镁铁质微粒包体的混合成因——来自野外分形特征的制约

大宁岩体是一个多期次侵入的复式岩体,主要由石英闪长岩、花岗闪长岩和二长花岗岩等花岗质岩石组成,其中富含镁铁质微粒包体(MME),MME主要出露在花岗闪长岩中.花岗闪长岩中部和边部MME个数与单位测量面积的特征值(直径)之间均存在对数线性关系(p>0.75),表明MME-花岗质侵入岩体系为分形体.结合MME的形态、结构特征,认为大宁岩体中MME为岩浆混合成因.花岗闪长岩中部和边部MME的分维数分别是1.293和0.991,表明混合程度在空间上具有不均一性.MME长轴展布方向与寄主岩体的原生流动线理方向一致,暗示着在镁铁质岩浆注入之前,长英质岩浆已部分结晶.对流作用可能是MME分布、变形和岩浆混合程度差异的主要驱动力.     

Generation of Porphyritic and Equigranular Mafic Enclaves During Magma Recharge Events at Unzen Volcano, Japan

Mafic to intermediate enclaves are evenly distributed throughoutthe dacitic 1991–1995 lava sequence of Unzen volcano,Japan, representing hundreds of mafic recharge events over thelife of the volcano. This study documents the morphological,textural, chemical, and petrological characteristics of theenclaves and coexisting silicic host lavas. The eruptive productsdescribed in this study appear to be general products of magmamingling, as the same textural types are seen at many othervolcanoes. Two types of magmatic enclaves, referred to as Porphyriticand Equigranular, are easily distinguished texturally. Porphyriticenclaves display a wide range in composition from basalt toandesite, are glass-rich, spherical and porphyritic, and containlarge, resorbed, plagioclase phenocrysts in a matrix of acicularcrystals and glass. Equigranular enclaves are andesitic, non-porphyritic,and consist of tabular, medium-grained microphenocrysts in amatrix glass that is in equilibrium with the host dacite magma.Porphyritic enclaves are produced when intruding basaltic magmaengulfs melt and phenocrysts of resident silicic magma at theirmutual interface. Equigranular enclaves are a product of a moreprolonged mixing and gradual crystallization at a slower coolingrate within the interior of the mafic intrusion. KEY WORDS: mafic enclaves; quenched mafic inclusions; magma mingling; Unzen volcano; Unzen Scientific Drilling Project; resorbed plagioclase     

南祁连西北缘肃北红庙沟地区早奥陶世花岗岩年代学、地球化学特征及其地质意义

笔者对南祁连西北缘红庙沟地区发育的黑云二长花岗岩体进行了精细的年代学和地球化学研究。LA-ICP-MS测定结果表明,黑云二长花岗岩加权平均年龄为（479.7±3.4）Ma（MSWD=0.047）,岩体侵位时代为早奥陶世。在地球化学组成上,黑云二长花岗岩表现为过铝质（A/CNK=0.96~1.04）的Ⅰ型花岗岩特征,稀土元素总量相对较低（∑REE=67.55×10-6~83.07×10-6）,轻稀土相对富集,具Eu负异常;富集Rb、Ba和K等大离子亲石元素,亏损Sr和高场强元素（Nb、Ti、P）,显示弧岩浆特征。综合研究表明,本区早奥陶世黑云二长花岗岩是南祁连洋向祁连陆块俯冲过程中引起岛弧岩浆活动而形成的产物,记录了该时期重要的板块构造运动事件,为认识南祁连造山带的构造演化提供了有益资料和重要依据。     

Timing of Magma Mixing in the Gangdisě Magmatic Belt during the India-Asia Collision： Zircon SHRIMP U-Pb Dating

Abstract  Abundant mafic microgranular enclaves (MMEs) extensively distribute in granitoids in the Gangdisê giant magmatic belt, within which the Qüxü batholith is the most typical MME‐bearing pluton. Systematic sampling for granodioritic host rock, mafic microgranular enclaves and gabbro nearby at two locations in the Qüxü batholith, and subsequent zircon SHRIMP II U‐Pb dating have been conducted. Two sets of isotopic ages for granodioritic host rock, mafic microgranular enclaves and gabbro are 50.4±1.3 Ma, 51.2±1.1 Ma, 47.0±1 Ma and 49.3±1.7 Ma, 48.9±1.1 Ma, 49.9±1.7 Ma, respectively. It thus rules out the possibilities of mafic microgranular enclaves being refractory residues after partial melting of magma source region, or being xenoliths of country rocks or later intrusions. Therefore, it is believed that the three types of rocks mentioned above likely formed in the same magmatic event, i.e., they formed by magma mixing in the Eocene (c. 50 Ma). Compositionally, granitoid host rocks incline towards acidic end member involved in magma mixing, gabbros are akin to basic end member and mafic microgranular enclaves are the incompletely mixed basic magma clots trapped in acidic magma. The isotopic dating also suggested that huge‐scale magma mixing in the Gangdisê belt took place 15–20 million years after the initiation of the India‐Asia continental collision, genetically related to the underplating of subduction‐collision‐induced basic magma at the base of the continental crust. Underplating and magma mixing were likely the main process of mass‐energy exchange between the mantle and the crust during the continental collision, and greatly contributed to the accretion of the continental crust, the evolution of the lithosphere and related mineralization beneath the portion of the Tibetan Plateau to the north of the collision zone.