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.     

Eocene tonalite–granodiorite from the Havza (Samsun) area,northern Turkey: adakite-like melts of lithospheric mantle and crust generated in a post-collisional setting

ABSTRACT

Eocene intermediate to felsic plutons of different sizes and compositions are widespread in the Eastern Pontides Orogenic Belt in northern Turkey. Of these, the Ta?l?k Tepe pluton in the Havza (Samsun) area is fine-to-medium-grained, with granular, porphyritic, and micrographic textures, and include mafic microgranular enclaves (MMEs). LA-ICP-MS U-Pb zircon dating yielded emplacement ages of 42.9 (± 1.4) and 40.5 (± 1.3) Ma for the host granodioritic pluton and the dioritic MMEs, respectively. Petrochemically, the host pluton has I-type, high-K calc-alkaline, and metaluminous-to-slightly peraluminous features (A/CNK = 0.95–1.06). The host pluton also shows geochemical features of adakite-like rocks with high SiO₂ (67–68 wt%) and Al₂O₃ (15.5–16.0 wt%) content and Ba/La (17–23), Sr/Y (40.7–61.6), and La_N/Yb_N (14.4–23.7) ratios and low Y (8.2–9.9 ppm) and Yb_N (3.1–4.4) contents. Whole-rock major and trace element variations suggest that fractional crystallisation played a significant role in the pluton evolution. The N-MORB normalised trace element patterns of the pluton are similar to those of MMEs with enrichment in large-ion lithophile elements, Th and Ce, and negative Nb and Ti anomalies. Chondrite-normalised rare earth element plots show moderate-to-highly enriched concave patterns (La_N/Lu_N = 14.2–21.6) with insignificant negative Eu anomalies (Eu_N/Eu* = 0.86–1.14), all of which imply hornblende fractionation during magmatic evolution. The pluton samples have ⁸⁷Sr/⁸⁶Sr ratios of 0.704767 to 0.704927, ¹⁴³Nd/¹⁴⁴Nd ratios of 0.512767–0.512774, εNd values of (+2.52) – (+2.65), and δ¹⁸O values of 7.9–9.7‰. The isotopic compositions of the host pluton and MMEs are similar to I-type granitoids derived from mantle sources. The MMEs show incomplete magma mixing/mingling, representing small bodies of mafic parental magma. Combined with regional studies, these new data suggest that the parental magma of the studied adakite-like pluton was generated from the lithospheric mantle and then modified by fractional crystallisation and assimilation in a post-collisional setting.     

海南岛琼中地区琼中岩体锆石U-Pb年龄及其地质意义

琼中地区琼中岩体为钙碱性的铝弱过饱和型花岗岩,具有壳源物质来源,岩石普遍发育定向组构,生成于同碰撞期—晚造山期。其锆石U-Pb年龄为226. 5±2. 9~234. 2±2. 3Ma,为晚三叠世。通过区域分析,认为海南岛海西—印支期花岗岩从西往东,具有由老至新的演化规律,形成了略向南面突出的弧状面理构造。表明同期造山活动消减方向由西至东,呈现出剪刀式闭合的特征。     

江西彭山岩体的地球化学特征及成矿关系探讨

彭山岩体是由白云母碱长花岗岩、二云母碱长花岗岩和黑云母二长花岗岩组成的钙碱性花岗复式岩体。其地球化学特征表明它是一种富硅、富碱、贫钙、过铝且轻稀土相对富集的陆壳重熔型花岗岩。通过与典型矿区铅、硫同位素及稀土元素的对比，发现其侵位与多金属矿床的形成有着密切的联系。区域上基底深断裂的活化及板块间的相互作用，为该区燕山晚期的岩浆活动创造了条件。岩浆活动在提供了大量热动力的同时，也为本区带来了丰富的成矿物质，岩浆在侵位过程中进行了较为彻底的结晶分异，最终成矿物质在彭山穹窿构造及各级次级构造中富集成矿。     

中祁连西段晚寒武世埃达克岩的发现及地质意义

乌尔格拉特岩体位于中祁连西段,由花岗闪长岩和二长花岗岩组成。花岗闪长岩锆石LA-ICPMS U-Pb年龄为490.5±1.4 Ma(MSWD=0.85),侵位时代为晚寒武世。岩石中Si O2含量为65.10%~71.21%,Al2O3含量为14.94%~16.82%,Mg O含量为0.23%~1.24%,A/NKC为0.9~1.0,Na2O/K2O为1.01~2.33,属准铝质花岗岩类;富集轻稀土元素和大离子亲石元素(Ba、U和Sr),亏损高场强元素(Nb、Ta、Ti和P)和重稀土元素,其中Sr含量为345×10-6~541×10-6(平均402×10-6),Yb为0.72×10-6~1.19×10-6(平均0.97×10-6),Y为6.09×10-6~11.3×10-6(平均8.67×10-6),无铕异常(δEu=0.91~1.27),高Sr/Y值(32.6~74.3),具埃达克岩地球化学特征。结合区域地质背景,认为乌尔格拉特岩体形成于俯冲环境,为晚寒武世北祁连洋向中祁连地块俯冲的产物。     

桂北豆乍山岩体放射性地球化学特征及其干热岩资源潜力研究

对桂北豆乍山岩体钻孔样品进行了放射性生热元素含量、岩石密度和岩石热导率测试.结果 显示该岩体花岗岩U平均含量为17.49×10-6,Th平均含量为27.54×10-6,K2O平均含量为4.64％,放射性生热率平均值6.46 μW/m3,高于地壳平均值及大部分华南其他岩体的放射性生热率值;岩石密度平均在2.57 g/cm...     

北祁连造山带东段老虎山石英闪长岩成因及其地质意义

以北祁连造山带东段老虎山石英闪长岩体为研究对象，进行了锆石U-Pb年龄及全岩元素与Sr-Nd同位素组成的系统 测定，据此探讨了岩石的成因及其对北祁连构造演化的启示。锆石LA-ICP-MS U-Pb定年结果表明，石英闪长岩体的形成 年龄为440 Ma。岩石具有亚碱、准铝以及贫钙、镁、铁的特征，碱铝指数（AKI值） 均低于0.85，铝饱和指数（A/NKC 值） 多小于1.0，属钙碱性I型花岗岩类岩石。在稀土和微量元素组成上，岩石富集轻稀土和大离子亲石元素（如Rb、Cs、 Th和U），亏损高场强元素（如Nb和Ta），显示弧岩浆岩的地球化学特征。岩体具有相对均一的Sr-Nd同位素组成，初始Sr同 位素值为0.7058~0.7071，εNd(t)值为-1.06~-0.31。综合分析表明，老虎山石英闪长岩应起源于玄武质下地壳物质的部分熔 融，并在成岩过程中有少量幔源物质的混入。对区内火成岩地质地球化学特征与产出背景的全面分析，表明受北祁连洋俯 冲及随后岛弧与祁连—柴达木陆块碰撞拼贴影响，弧后盆地的北向俯冲消减作用可能是诱发民乐窑沟和老虎山弧岩浆岩以 及导致毛藏寺—老虎山花岗岩带内埃达克质岩石侵位的基本动力机制。     

江南造山带东段旌德岩体锆石LA-ICPMS年龄和Nd-Sr-Hf同位素地球化学

提要：旌德花岗质杂岩体位于安徽南部,由花岗闪长岩和二长花岗岩组成。本研究得到岩体中锆石U-Pb年龄为(141.0±1.0) Ma,认为该年龄代表岩体的侵位年龄。岩体全岩主量元素特征显示出中偏酸性 (SiO2＝66.01%~70.87%),富Al (Al2O3＝14.91%~16.24%),富碱 (alk = 6.64%~8.01%),K2O/Na2O变化范围在0.78~1.04,镁、铁含量较低,MgO：0.68%~1.06%,TFe2O3 (2.0%~3.34%),以及低磷 (P2O5 =0.10%~0.14%)的特点;微量元素主要富集Sr (189×10-6~452×10-6),贫Nb、Ta、P、Ti、Y、Yb,高Sr/Y比值 (23~66)和 (La/Yb)N (13~58),Eu有轻微的负异常到弱的正异常 (δEu＝0.81~1.18)。旌德岩体的地球化学特征与中国东部中生代埃达克质岩相似。ISr＝0.7096~0.7101, εNd(t)＝-6.28~-7.32,εHf(t)值变化于-6.5~-1.1,两阶段模式年龄 tDM2=1.4~1.5 Ga。较年轻的Nd同位素模式年龄、较高的εNd(t)值和εHf(t)值,以及岩体中发育有岩浆混合成因的暗色包体,指示源区可能有地幔物质的贡献。幔源岩浆底侵使下地壳发生部分熔融,并发生了岩浆混合作用,形成了旌德岩体。     

内蒙古贺根山北乌兰德勒花岗岩体锆石U——Pb 测年、地球化学特征及其构造意义

乌兰德勒岩体为一个由两次岩浆侵入形成的大型复式岩体,主要由黑云母正长花岗岩和黑云母二长花岗岩组成,两种岩石的形成年龄分别为140 ± 2 Ma 和161 ± 1 Ma。黑云母正长花岗岩显示高分异花岗岩的地球化学特征,该类岩石与成矿关系密切。黑云母二长花岗岩表现为低Sr 高Yb 的地球化学特征。地球化学资料显示黑云母二长花岗岩为A 型花岗岩,形成时的构造环境为伸展体制。     

北秦岭中生代沙河湾岩体环斑结构特征及有关问题的讨论

该岩体的环斑结构主要发育于边部含巨斑状黑云角闪石英二长岩中 ,环斑长石粒径一般 2cm× 4cm。形态多呈自形、半自形 ,有些为卵形。环斑长石由核部钾长石和多层或单层斜长石外壳两部分构成。钾长石内核呈肉红色 ,一般是由单颗粒组成 ,具卡氏双晶 ,普遍发育规则的条纹结构 ;中心部分钾长石分子含量Or为 95 ,边部为 84。外壳斜长石牌号一般为An2 0± ,为奥长石。内核和外壳中均发育石英、斜长石、黑云母、角闪石等矿物的包裹体 ;包裹体在其边部较多 ,中部较少 ,钾长石斑晶中的石英包裹体呈不规则的凹面状和水滴状。岩石中主要矿物具有 2个世代。这些特征显示 ,沙河湾岩体中的环斑结构与典型的环斑结构是相同的。亦表明典型的环斑结构可以出现于不同的时代和构造环境。由于其形成时代和产出背景不同于典型环斑花岗岩 ,该岩体属典型环斑花岗岩还是一种新的似环斑花岗岩还有待于进一步研究。