Petrogenesis and tectonic implications of the Silurian adakitic granitoids in the eastern segment of the Qilian Orogenic Belt,Northwest China

Geodynamic mechanism responsible for the generation of Silurian granitoids and the tectonic evolution of the Qilian orogenic belt remains controversial. In this study, we report the results of zircon U–Pb age, and systematic whole-rock geochemical data for the Haoquangou and Liujiaxia granitoids within the North Qilian orogenic belt and the Qilian Block, respectively, to constrain their petrogenesis, and the Silurian tectonic evolution of the Qilian orogenic belt. Zircon U–Pb ages indicate that the Haoquangou and Liujiaxia intrusions were emplaced at423 ± 3 Ma and 432 ± 4 Ma, respectively. The Haoquangou granodiorites are calc-alkaline, while the Liujiaxia granites belong to the high-K calc-alkaline series.Both are peraluminous in composition and have relatively depleted Nd isotopic [ε_(Nd)(t) =(-3.9 – + 0.6)] characteristics compared with regional basement rocks, implying their derivation from a juvenile lower crust. They show adakitic geochemical characteristics and were generated by partial melting of thickened lower continental crust. Postcollisional extensional regime related to lithospheric delamination was the most likely geodynamic mechanism for the generation of the Haoquangou granodiorite, while the Liujiaxia granites were generated in a compressive setting during continental collision between the Qaidam and Qilian blocks.

琼东南盆地二叠纪-三叠纪长英质岩浆作用:对南海北部陆缘构造属性与演化过程的启示

琼东南盆地发育二叠纪-三叠纪岩浆岩类,为研究南海北部陆缘古构造属性与大地构造演化过程提供了岩石探针。本文以基底长英质岩浆岩为研究对象,开展岩石学、锆石U-Pb年代学、岩石地球化学和锆石Lu-Hf同位素研究,探讨琼东南盆地二叠纪-三叠纪岩浆岩的时空分布、岩石成因及动力学背景。LA-ICP-MS锆石U-Pb年代学表明,琼东南盆地发育二叠纪-早三叠世、中三叠世和晚三叠世三期长英质岩浆作用(271~217Ma),且岩浆活动具有自南向北迁移的趋势。岩石地球化学分析揭示,二叠纪-早三叠世长英质岩具有较低的FeO/MgO和10000×Ga/Al比值,且强烈亏损Zr、Hf、Nb、Ta等元素,属于典型的陆缘弧I型花岗岩类;中三叠世和晚三叠世岩浆岩均具有较高的SiO_(2)、Mg^(#)、10000×Ga/Al和FeO/MgO比值,大多属于A型花岗岩类。同时,二叠纪-早三叠世长英质岩具有较低的Hf同位素组成(ε_(Hf)(t)=-7.61~-0.65),而中-晚三叠世长英质岩则大多具有较高的Hf同位素组成。岩石成因分析揭示,二叠纪-早三叠世I型花岗岩类起源于古老陆壳的部分熔融,而中三叠世和晚三叠世A型花岗岩类则部分起源于古老长英质地壳熔融,部分则起源于新生地壳熔融,并伴随有壳幔相互作用。综合分析表明,二叠纪-三叠纪期间南海北部陆缘主要受控于古特提斯造山作用控制,且先后经历了二叠纪至早三叠世的古特提斯洋壳俯冲、中三叠世印支板块与华南板块碰撞以及晚三叠世碰撞后伸展等动力学过程。

基于机器学习的埃达克质岩构造背景判别研究

埃达克质岩具有重要的地球动力学和金属成矿意义,其构造背景的准确识别为探讨区域构造-岩浆演化过程提供了重要依据。由于埃达克质岩源区、热源和岩浆产生机制的多样性,传统低维度地球化学手段在识别构造背景时存在局限性。随着地学数据的指数增长和人工智能的发展,机器学习为解决该问题提供了新方法。因此,本文将机器学习与地质大数据相结合,构建高精度埃达克质岩构造背景判别模型和可视化图解。文中收集了1 075条全球埃达克质岩主、微量地球化学数据,使用主成分分析和t分布-随机近邻嵌入等无监督学习方法进行高维数据降维,采用随机森林、支持向量机、人工神经网络和K近邻等机器学习方法进行数据训练,得出准确率为98.5%的高斯核支持向量机埃达克质岩构造背景判别器,并提出Ba-Sr/Nd图解,为汇聚板块边缘、板内火山活动和太古宙克拉通(包括绿岩带)3种构造背景判别提供依据。这项工作将拓展机器学习在埃达克质岩构造背景研究中的应用,为构造-岩浆作用研究带来新的思路。

东天山印支期闪长质岩墙岩石成因及构造意义

东天山地区发育大量的印支期岩浆岩,其岩石成因及其动力学背景对于理解中亚造山带晚期构造演化过程具有重要意义。本文对东天山尾亚和天湖地区新发现的闪长质岩墙开展了岩石学、地球化学及锆石U-Pb年代学和Hf同位素综合研究。锆石U-Pb测年结果表明,天湖地区闪长质岩墙形成时代为246.6±1.9Ma和248.4±3.8Ma,为早三叠世岩浆活动的产物;尾亚地区闪长质岩墙形成时代为237.7±1.3Ma、234.4±2.1Ma、238.3±1.6Ma和233.9±1.6Ma,为中三叠世岩浆活动的产物。岩石地球化学特征显示研究区闪长质岩墙总体呈现出较高硅(SiO_(2)为60.51%~67.56%)、富碱(K_(2)O+Na_(2)O为6.39%~8.23%)和准铝质(A/CNK为0.91~0.98)特征,属于高钾钙碱性系列。岩石相对富集K、Rb、Ba等大离子亲石元素(LILE),亏损Nb、Ti、Ta等高场强元素(HFSE),具有微弱Eu负异常(δEu=0.83~1.03)。锆石Hf同位素分析显示样品具有正的ε_(Hf)(t)值(+1.26~+6.32)和较年轻的亏损地幔模式年龄(tDM1=638~828Ma)。结合岩石地球化学特征,表明闪长质岩墙可能为交代地幔楔部分熔融形成的幔源岩浆底侵诱发新生下地壳熔融,随后由底侵的玄武质岩浆与壳源长英质岩浆混合形成。结合区域地质和相关构造环境分析,指示闪长质岩墙形成于板内伸展环境。结合前人研究,本文认为东天山发育的闪长质岩墙群可作为区域伸展作用的重要标志,表明东天山在印支期为陆内伸展的构造环境。

硬质岩滑坡深大抗滑桩一体化旋挖成孔技术及应用

硬质岩深大抗滑桩桩孔成孔效率是滑坡灾害防治的难点问题之一。选取川西南典型复杂山区硬质岩滑坡抗滑桩成孔为研究对象,系统分析了裂隙弱发育深部硬质玄武岩地层抗滑桩传统工艺成孔存在的问题,对此设计了9种组合旋挖成孔工艺方案进行现场试桩试验,从钻进效率、技术及经济可行性等方面进行了分析论证。现场试验及分析结果表明:采用“大扭矩截齿筒钻旋挖+扩孔直径差0.4 m”分级扩孔一体化成孔技术在硬质岩地层中钻进效率较高、钻具损耗较低、成本较低,验证了硬质岩抗滑桩高效旋挖分级扩孔技术的可行性和高效性,对比现有人工成孔、冲击钻成孔、旋挖一次成孔等工艺,从安全、效率、成本等方面均得到了极大提升。该技术成功应用于白鹤滩迁建集镇后缘滑坡桩基施工,每延米综合耗时1.43 h,较改进前旋挖一次成孔效率提升3倍,成本降低了60%。该技术为复杂地质条件下水敏型、震敏型硬质岩滑坡抗滑桩快速成孔施工提供了高效、可行的技术方案。

深水硬质岩嵌入式承台无封底施工关键技术

深水嵌入式承台基础施工中,需将泥面开挖至封底混凝土以下并对基底进行清理,以保证封底混凝土的高度和浇筑质量。对于地质条件良好的硬质岩,存在开挖困难、水下作业工期长、质量控制难、施工成本高等问题。该文依托重庆嘉华轨道专用桥主墩承台施工,采用理论分析、数值计算和工程实施验证相结合的方法,形成一种深水硬质岩嵌入式承台无封底施工技术。该施工技术,采用开挖壁体基槽并浇筑基槽混凝土的方式取代大体积封底混凝土,达到为承台施工提供干作业环境的目的,可将承台范围内基坑开挖由水下作业转为干作业,缩短水下开挖作业工期,节约水下混凝土用量,提高施工质量和施工效率,降低施工成本。

伸展背景下的埃达克质岩:黑龙江呼玛地区早白垩世侵入岩的年代学和地球化学特征

为理清大兴安岭兴安地块中生代岩体的岩石成因及构造背景,本文通过岩石学、年代学、全岩地球化学等方法,对大兴安岭东北部的黑龙江省呼玛地区早白垩世侵入岩进行了研究。结果显示:研究区早白垩世中性侵入岩为钙碱性-高钾钙碱性系列准铝质-弱过铝质岩石,成岩时间在(121.3±1.2)~(118.7±0.9)Ma之间,稀土元素配分曲线显示为右倾模式,Eu微弱正异常(0.98~1.11),富集K、Sr、Ba等大离子亲石元素,亏损Nb、Ta、Ti、P等高场强元素。岩石同时具有高的Sr/Y(57.66~145.76)、LaN/YbN(11.66~29.52)和较高的Mg^(#)(50.93~57.63)、w(Cr)(77.00×10^(-6)~92.60×10^(-6))、w(Ni)(23.20×10^(-6)~32.60×10^(-6))值,显示出埃达克质岩特征。综合本次研究认为该期侵入岩主要形成于蒙古-鄂霍茨克洋闭合后的伸展环境,由加厚下地壳导致的岩石圈拆沉,软流圈幔源岩浆上涌形成埃达克质岩石。

滇西古近纪钾质—超钾质岩浆岩成岩成矿作用及构造意义

滇西地区广泛发育古近纪钾质—超钾质岩浆岩,形成沿金沙江—哀牢山断裂带富碱岩浆岩带,因缺乏对该钾质—超钾质岩浆岩带的系统研究,岩石成因及其与成矿之间的关系尚存在诸多争论。通过收集该富碱岩浆岩带已发表的全岩主微量元素、Sr-Nd同位素、锆石Hf同位素及年代学数据,根据构造位置,将该岩带划分为南、中、北岩带3个部分。通过系统对比分析得出:滇西古近纪钾质—超钾质岩浆岩成岩年龄基本一致,峰值为35 Ma,为同一期构造热事件的产物;基性—超基性和中酸性岩类具有不同成因,前者富集大离子亲石元素(LILE),亏损高场强元素(HFSE),高(87Sr/86Sr)i比值,低εNd(t)值,可能来源于板片交代的富集岩石圈地幔,后者具有较高的SiO2含量,可能为壳幔混合的产物;基性—超基性和中酸性岩类的形成均与金沙江—哀牢山断裂的剪切走滑和拉伸作用相关,是同一构造热事件下岩石圈不同深度部分熔融的产物;南中岩带钾质—超钾质岩浆岩与斑岩型金—(铜—钼)矿床关系密切,其岩浆形成过程可能为成矿提供了高氧逸度和含水量的有利条件,以及成矿物质和成矿流体。

干湿循环作用下石膏质岩隧道衬砌结构受力特征研究

基于室内三轴压缩试验获得干湿循环作用后石膏质岩的破坏特征及力学特性演化规律,结合数值模拟研究石膏质岩经干湿循环作用劣化后对隧道初期支护结构的力学影响规律。研究结果表明:随着干湿循环次数增加,石膏质岩破坏时剪切面减少,且岩样表面出现大面积岩块剥落;同时,泊松比增加,弹性模量和峰值偏应力降低,其中弹性模量劣化最为严重,同比降低约49%。在11次干湿循环后,水平位移于边墙最大,同比提高约1.5倍,竖直位移峰值出现在拱顶,同比提高1.2倍;初期支护各位置安全系数均降低,其中拱顶、墙脚和边墙出现大幅下降,分别下降约63%、36%和53%;初期支护结构的拱顶、墙脚和边墙为薄弱点,需重点进行加固和补强,以保证隧道安全运营。

煤矿泥质岩吸水膨胀规律研究

吸水膨胀是泥质岩的物理特性,泥质岩遍布我国各个煤矿,吸水膨胀会使围岩发生明显变形,改变岩体结构,造成围岩体系破坏导致巷道失去使用价值,并造成泥质岩膨胀危害,甚至造成安全生产事故。为研究煤矿巷道泥质岩吸水膨胀规律,本文以某煤矿泥岩为研究对象,研究基本物理力学性质,并对岩石各参数进行统计;通过开展吸水膨胀实验,本研究对泥质岩膨胀应变-时间关系、膨胀应力-时间关系及吸水过程进行分析。同时采用浸水过程中的单轴抗压强度测试,得到泥质岩浸水过程中单轴抗压强度。

福建德化蒲洋、浦城仙阳地区早古生代埃达克质岩成因探讨及其地质意义

华南加里东造山作用的类型仍存在争议,焦点集中在是否存在加里东期的大洋俯冲造山作用。根据福建德化蒲洋花岗闪长岩和浦城黄墩、仙阳等地的二长花岗岩年代学,岩石地球化学特征研究认为,岩石具埃达克质岩特征,成岩年龄为450~455 Ma,侵位时间与早古生代华夏地块西南部的云开造山运动的俯冲时限(460~440 Ma)吻合,结合区域资料,认为是大洋俯冲板片部分熔融成因,为该时期华南板块存在洋板块俯冲造山作用提供了重要证据,且指示初始俯冲时限不晚于455 Ma。

徐淮地区早白垩世adakitic岩石的年代学和Pb同位素组成:对岩浆源区与华北克拉通东部构造演化的制约

本文报道了徐淮地区5个早白垩世 adakitic 岩体全岩的 Pb 同位素组成和其中3个岩体的锆石 LA-ICP-MS U-Pb 定年结果,并讨论了岩浆源区的性质和华北克拉通东部中生代早期的构造演化。结果表明,班井、丰山和蔡山岩体形成于早白垩世,其^(206)Pb/^(238)U 加权平均年龄分别为127±1Ma、129±2Ma 和131±1Ma。利国、班井、夹沟、丰山和蔡山岩体的全岩(^(206)Pb/^(204)Pb)_t、(^(207)Pb/^(204)Pb)_t 和(^(208)Pb/^(204)Pb)_t 初始比值分别变化于17.957～18.620、15.508～15.655和38.129～38.710之间。综合早白垩世adakitic 岩石高的放射成因 Pb 同位素组成以及继承锆石年代学和其中榴辉岩类捕虏体锆石 U-Pb 年代学和地球化学的研究成果,可以认为华北克拉通东部徐淮地区早白垩世 adakitic 岩石的岩浆源区以断离的扬子克拉通俯冲板片(基底物质)为主,并有拆沉的华北克拉通基底物质的参与。这与扬子克拉通沿北西方向俯冲于华北克拉通之下的构造模式相吻合。

鄂东南铜山口、殷祖埃达克质(adakitic)侵入岩的地球化学特征对比:(拆沉)下地壳熔融与斑岩铜矿的成因

鄂东南地区铜山口花岗闪长斑岩体是与斑岩铜钼矿床共生的岩体,但殷祖花岗闪长岩体是与金属成矿无关的岩体。铜山口和殷祖侵入岩的元素地球化学特征与埃达克岩的地球化学特征非常类似,如高Al2O3、Sr含量与La/Yb、Sr/Y比值,富Na2O(Na2O/K2O>1.0),亏损Y与Yb,极弱负Eu异常-正Eu异常以及正Sr异常等。但是铜山口和殷祖侵入岩也存在 明显的差别:前者比后者更偏酸性,但具有较高的K2O,MgO,Cr,Ni和Sr含量,较低的Y和Yb含量,轻重稀土元素分异更明显,并主要显示出正铕异常,区别于后者的极弱负Eu异常-不明显Eu异常。这表明铜山口埃达克质侵入岩的岩浆来源可能比殷祖埃达克质侵入岩的岩浆来源更深:前者可能由拆沉的下地壳熔融形成,残留物主要含石榴子石;而后者可能由增厚的下地壳熔融形成,残留物可能为石榴子石±斜长石±角闪石。另外,热的地幔上涌,底辟(diapir)进入下地壳,导致含角闪石的榴辉岩发生熔融也可形成铜山口埃达克质岩浆。铜山口埃达克质岩浆在穿过地幔的过程中,将会与地幔橄榄岩发生交换反应:一方面由于受橄榄岩的混染而使得岩浆的MgO,Cr和Ni增高;另一方面岩浆中的Fe2O3不断加入到地幔中,导致地幔的氧逸度(fo2)增高,地幔中金属硫化物被氧化并进入岩浆中。

Adakitic火成岩对大陆地壳增厚过程的指示:以青藏北部火山岩为例

Adakitic火成岩可以通过几种不同的岩浆作用方式产生,其中下地壳镁铁质岩石的直接部分熔融和拆沉下地壳的部分熔融可能是两种重要的adakitic火成岩形成方式。在一个大陆厚地壳背景,adakitic火成岩的产生指示了它们的岩浆源区位于大于40 km的下地壳之中,因此,暗示该大陆地壳的最小厚度超过40 km。青藏高原腹地的羌塘地区分布有40 Ma左右的“低镁”和“高镁”adakitic安山岩-英安岩-流纹岩,它们应分别是青藏高原厚大陆地壳下部镁铁质岩石直接部分熔融和拆沉的下地壳脱水熔融的产物。这套adakitic火山岩的厘定指示出在40 Ma左右时,青藏羌塘地区或更大范围的大陆地壳已经加厚到超过40 km,其地表在当时或稍后可能已经开始了隆升。

中国三大陆块中—新元古代泥质岩与碳酸盐岩元素地球化学特征

中国三大陆块中—新元古代地层格架中广泛分布低变质程度的泥质岩与碳酸盐岩,其元素地球化学特征为研究地表圈层的历史演化提供了重要的基础资料。本文收集了近十几年国内外已发表的近2000组泥质岩/碳酸盐岩中地球化学数据,包括40种常量、微量元素含量组成,涉及华北陆块长城系、蓟县系、待建系及青白口系,扬子和塔里木陆块南华系、震旦系。结合文献中样品的岩性、实验方法以及地质背景特征,主要得出了以下认识:①泥质岩中常量元素的平均含量与中国东部未变质泥质岩中的相似,但其整体上受到了新元古代冰期的影响,化学风化作用较弱,易流失的Na、K及Ca元素含量相对较高;碳酸盐岩中的常量元素含量组成与中国东部未变质富泥碳酸盐岩对比,具有少量的陆源物质输入且以白云岩为主,Mg含量较高。②碳酸盐岩中较高的Mn/Sr比值应与成岩蚀变作用有关,虽然硅酸盐矿物少于泥质岩,但Sc、REE+Y以及氧化还原敏感元素更加富集,Sc和REE+Y元素与陆源碎屑的混染作用有关,而后者与氧化的海洋环境有关。③中元古代早期,华北沉积物中记录了Ce元素负异常以及氧化还原敏感元素含量的增高,响应了一次浅海的氧化事件,并促使了生物的演化。④进入新元古代,“雪球地球”事件被塔里木陆块泥质岩大范围变化的化学蚀变指数所记录,伴随着间冰期及冰期后海洋的增氧,扬子陆块新元古代沉积物部分微量元素含量又一次增加,对应着伊迪卡拉生物群的出现。

泥质岩定义及分类问题的探讨

泥质岩为细粒沉积岩的主要类型,但国内外对其概念及分类有多种不同的理解,这给学术研究带来诸多困扰。文中梳理了国内外沉积学发展中泥质岩相关概念和定义的变迁,并试图建立一个实用的泥质岩(mudrock)分类体系。欧美国家多倾向于使用“泥质岩”一词,用于指粒径小于0.063 mm的细粒陆源碎屑岩,包括粉砂岩(粉砂含量大于2/3)、泥岩(粉砂和黏土含量都不超过2/3)和黏土岩(黏土含量超过2/3),其中发育纹层的岩石称为页岩;而前苏联学者则倾向于使用“黏土岩”一词,用于指黏土矿物含量大于50%的沉积岩,其中可劈裂成薄层的岩石称为页岩。国内外泥质岩及细粒沉积岩分类命名主要依据结构(粒级)、成分和沉积构造等特征,目前分类方案主要有2种,一种是多要素岩石综合分类方案,另一种是端元图式分类方案。笔者建议采用“泥质岩”一词作为细粒陆源沉积岩(物)的总称,指示主要由粒径0.004~0.063 mm的粉砂和小于0.004 mm的黏土组成的细粒陆源沉积岩;采用三棱柱图解分类方法,以碎屑矿物(主要是长英质碎屑矿物)、黏土矿物和内源矿物为三端元,划分出细粒陆源沉积岩(泥质岩)和细粒内源沉积岩2个大类,前者可进一步分为粉砂岩、泥岩和黏土岩3个亚类,若具纹层和页理构造则称为页岩;并以TOC含量0.5%和2.0%为界,将细粒陆源沉积岩划分为贫有机质、含有机质和富有机质3类。期望该分类方案能够对泥质岩行业分类方案制定起到推动作用。

Post-collisional Adakitic Porphyries in Tibet:Geochemical and Sr-Nd-Pb Isotopic Constraints on Partial Melting of Oceanic Lithosphere and Crust-Mantle Interaction

The distribution of Neogene felsic porphyries intruding in earlier granitic batholiths was mainly controlled by north-south-tending rifting zones and normal faults. The main rock types of the felsic porphyries include granodiorite-porphyry, monzonitic granite-porphyry and quartz monzonitic porphyry. The porphyries are characterized by high SiO2 ((?)64.26%) and Al2O3 (>15% at 70% SiO2), low Y and HREE (Yb) contents, strong enrichment of LILE and LERR, especially K and ST. Geochemical features of the porphyries show distinct adakitic magma affinity. Nd, Sr and Pb isotopic compositions of the porphyries form a linear alignment from MORB to EM2, suggesting a mixing of the MORB reservoir with the metasomatized mantle reservoir. Considering also the geochemical characteristics of the porphyries and the sequence of observable structural-thermal-magmatic events at Gangdise, it is thought that the Neogene porphyries were formed by partial melting of dead subducted oceanic crust in a post-collision setting. K-enrichment in the porphyries is attributed to the interaction of slab-derived melts, i.e., adakites, with the metasomatized mantle during the ascent. There might be a delamination of residual eclogites or amphibole eclogites before the eruption of potassic lava on the Tibetan plateau since 13 Ma.

Zircon LA-ICP MS U-Pb Age,Sr-Nd-Pb Isotopic Compositions and Geochemistry of the Triassic Post-collisional Wulong Adakitic Granodiorite in the South Qinling,Central China,and Its Petrogenesis

The Indosinian post-collisional Wulong pluton intruded into the Mesoproterozoic Fuping Group, South Qinling, central China. In the southern part of the pluton, some mafic enclaves have sharp or gradational contact relationships with the host biotite granodiorite. Geochemistry, zircon LA-ICP MS （laser ablation inductively-coupled plasma mass spectrometry） U-Pb chronology and Sr- Nd-Pb isotope geochemistry of the pluton are reported in this paper. The biotite granodiorite shows close compositional similarities to high-silica adakite. Its chondrite-normalized REE patterns are characterized by strong HREE depletion （Yb = 0.33--0.96 10-6 and Y = 4.77-11.19 ×10^-6）, enrichment of Ba （775-1386 x 10-6） and Sr （643-1115 × 10^-6） and high Sr/Y （57.83-159.99） and Y/Yb （10.99-14.32） ratios, as well as insignificant Eu anomalies （6Eu = 0.70-0.83）, suggesting a feldspar-poor, garnet±amphibole-rich residual mineral assemblage. The mafic enclaves have higher MgO （4.15- 8.13%）, Cr （14.79-371.31 × 10-6）, Ni （20.00-224.24× 10^-6） and Nb/Ta （15.42-21.91） than the host granodiorite, implying that they are mantle-derived and might represent underplated mafic magma. Zircon LA-ICP MS dating of the granodiorite yields a ^206pb/^238U weighted mean age of 208±2 Ma （MSWD=0.50, 1σ）, which is the age of emplacement of the host biotite granodiorite. This age indicates that the Wulong pluton formed during the late-orogenic or post-collisional stage （〈242±21 Ma） of the South Qinling belt. The host biotite granodiorite displays ^87Sr/^86Sr = 0.7059-0.7062, Isr = 0.7044-- 0.7050,^143Nd/^144Nd = 0.51236-0.51238, εNd（t）= -2.26 to -2.66 to ^206Pb/^204pb = 18.099-18.209, ^207pb/^204pb = 15.873-15.979 and ^208pb/^204pb = 38.973-39.430. Those ratios are similar to those of the Mesoproterozoic Yaolinghe Group in the South Qinling. Furthermore, its Nd isotopic model age （-1.02 Ga） is consistent with the age （-1.1 Ga） of the Yaolinghe Group. Based on the integrated geological and geochemical studies, coupled with previous studies, the authors suggest that the Wulong adakitic biotite granodiorite was probably generated by dehydration melting of the Yaolinghe Group-like thickened mafic crust, triggered by underplating of mafic magma at the boundary of the thickened mafic crust and hot lithospheric mantle, and that the Wulong adakitic biotite granodiorite may have resulted from thinning and delamination of the lower crust or breakoff of the subducting slab of the Mianlue ocean during the Indosinian post-collisional orogenic stage of the Qinling orogenic belt.

Association of Late Paleozoic Adakitic Rocks and Shoshonitic Volcanic Rocks in the Western Tianshan, China

The late Paleozoic adakitic rocks are closely associated with the shoshonitic volcanic rocks in the western Tianshan Mountains, China, both spatially and temporally. The magmatic rocks were formed during the period from the middle to the late Permian with isotopic ages of 248-268 Ma. The 87Sr/86Sr initial ratios of the rocks are low in a narrow variation range (-0.7050). The 143Nd/144Nd initial ratios are high (-0.51240) with positive εND(t) values (+1.28-+4.92). In the εNd(t)-(87Sr/86Sr)i diagram they fall in the first quadrant. The association of the shoshonitic and adakitic rocks can be interpreted by a two-stage model: the shoshonitic volcanic rocks were formed through long-term fractional crystallization of underplated basaltic magma, while the following partial melting of the residual phases formed the adakitic rocks.

Adakitic rocks associated with the Shilu copper–molybdenum deposit in the Yangchun Basin,South China,and their tectonic implications

South China is famous for the extensive magmatism and polymetallic mineralization that took place there in the Mesozoic. Shilu is a large porphyry–skarn Cu–Mo deposit in the Yangchun Basin, South China. The lithology of the Shilu intrusion is granodiorite and quartz diorite, both of which are high-K calc-alkaline series, with high Sr([400 ppm) content along with low Y and Yb contents. Most of the samples have characteristics of adakite except for a few samples that have slightly higher Y and Yb contents, which may be plausibly explained by crustal contamination. Laser Ablation Inductively Coupled Plasma Mass Spectrometry zircon U–Pb dating revealed ages between 106.6 ± 1.3 and 103.9 ± 0.5 Ma, with multiple magmatic pulses. Molybdenite Re–Os isochron age of 102.2 ± 2.9 Ma(MSWD = 9.4) was determined, which is identical to the youngest zircon U–Pb age(103.9 ± 0.5 Ma) within error.The Shilu intrusion has high oxygen fugacity as indicated by high zircon Ce^(4+)/Ce^(3+) and Eu_N/Eu_N* ratios. Considering the geochemical characteristics(high Sr, and low Y and Yb contents), high oxygen fugacity, and copper mineralization of the Shilu intrusion, it was most likely formed by partial melting of a subducted young oceanic slab. Whole-rock Sr–Nd isotope-, zircon Hf isotope-, and whole-rock trace element analyses show that Shilu adakitic magmas may have interacted with type II enriched mantle and/or crustal materials during ascent. South China was affected by the Pacific tectonic regime to the east and the Neo-Tethys tectonic regime to the south in the Cretaceous. Based on the Pacific Plate drifting and rotation history, it is hard to explain how the Pacific Plate would have subducted and melted, forming adakitic rocks in the Shilu region. Considering the tectonic history of Southeast Asia and the South China Sea, the Neo-Tethys trench should have been much closer to the South China Block in the Cretaceous, and thus have had a greater impact on the South China Block. Based on the subduction direction, time of subduction,and distance between the Neo-Tethys subduction zone and the Shilu deposit, subduction of the Neo-Tethys ridge is the best mechanism for explaining the Shilu adakitic rocks and Cu–Mo mineralization.