松辽盆地长岭断陷早白垩世火山岩地球化学研究

长岭断陷早白垩世火山岩富硅、富碱,岩石以非碱性系列为主,包括钙碱性和高钾钙碱性系列,碱性系列火山岩为钾玄岩系列。酸性岩与中、基性岩的微量元素特征差别明显,岩石总体微量元素特征与造山带火山岩相似,富集LREE、Rb、K和大离子亲石元素,TiO2含量低,贫Sr。火山岩的形成与造山带岩石圈拆沉作用引起地壳拉张减薄的大地构造背景有关。研究区基性火山岩为地幔岩部分熔融作用的产物,岩浆演化过程中存在单斜辉石和橄榄石等矿物的分离结晶作用,中性岩为原生玄武质岩浆分异演化的产物,营城组酸性火山岩的形成与构造活动存在直接关系,为构造剪切挤压应力致使上地壳重熔的结果。     

青藏高原北部黑石北湖新生代钾质火山岩的成因

昆仑岩带新生代钾质火山活动是青藏高原北缘深部动力学过程的重要记录。有关岩浆源区的性质和岩浆产生的机制一直存在较大的认识分歧。阐述了昆仑岩带黑石北湖钾质火山岩的岩石学和地球化学特征,并与西昆仑康西瓦和泉水沟新生代火山岩进行了成因对比分析。研究表明,昆仑火山岩带玄武质岩石的K2O和Na2O含量变化较大,从钠质过渡到钾质,硅碱图显示玄武质初始岩浆向钾质安粗岩方向演化。黑石北湖火山岩的高场强元素和Sr、Nd同位素组成显示岩浆源区具有EMⅡ的性质。岩石LREE的强烈富集和HREE的强烈分馏指示岩浆来自富集型含石榴子石地幔源区。不相容元素K/Nb、Ba/La等比值具有岛弧火山岩与OIB型玄武岩的过渡特征,指示源区为曾遭受软流圈流（熔）体交代的古俯冲地幔楔。     

大兴安岭北段中—新生代玄武岩成分变异:对地幔热演化过程意义

近年来,东北地区地幔热演化过程的相关研究相对较少,而揭示东北地区地幔热演化过程的有效手段就是研究东北地区玄武岩的成分变异特征.系统总结并对比了大兴安岭北段早白垩世玄武质岩石和新生代玄武质岩石的化学成分变异,以便揭示研究区中生代晚期-新生代的地幔热演化过程.大兴安岭北段早白垩世玄武岩在化学上属于拉斑玄武岩系列,以亏损Nb、Ta、Ti等高场强元素为特征,它们的La/Nb和La/Ta比值分别介于1.8~5.6和30~87,暗示岩浆起源于岩石圈地幔;它们的初始87Sr/86Sr值、ε_Nd（t）和ε_Hf（t）值分别介于0.704 5~0.706 9、-1.52~+3.60和+1.74~+7.77,表明岩浆源区属于弱亏损-弱富集的岩石圈地幔;早白垩世玄武质岩石的Sr-Nd-Pb同位素成分指示岩浆源区是由DM和EMⅡ型地幔端元混合而成,并经历了俯冲流体的交代.表明大兴安岭北段早白垩世玄武质岩浆源区为受早期俯冲流体交代的岩石圈地幔.新生代超钾质和钾质玄武岩具有Nb-Ta的弱负异常,87Sr/86Sr值为0.704 7~0.705 7、ε_Nd（t）值为-6.3~-0.8,而地幔捕掳体具有Sr-Nd同位素亏损特征;钠质玄武岩具有Nb-Ta的正异常,较超钾质和钾质玄武岩具有低的87Sr/86Sr（0.703 5~0.704 2）以及高的ε_Nd（t）值（+3.4~+6.6）,类似MORB的同位素组成,这些特征说明大兴安岭北段新生代玄武质岩石起源于软流圈地幔.综上所述,大兴安岭北段早白垩世和新生代玄武质岩石成分的差异不仅指示其岩浆源区从岩石圈地幔转变为软流圈地幔,更为重要的是它揭示了研究区地幔的热演化过程——从早白垩世高的地温梯度到新生代低的地温梯度的转变.这一过程也是岩石圈从中生代晚期到新生代逐渐增厚的过程.结合区域构造演化,可以得出大兴安岭北段早白垩世的玄武质岩浆作用与岩石圈伸展、减薄形成的裂陷作用相关,而新生代玄武质岩浆作用则与陆内裂谷作用相关.      

埃达克质岩的构造背景与岩石组合

本文介绍了埃达克质岩形成的构造背景与岩石组合。埃达克质岩可以形成于不同的构造背景并与不同类型的岩石同时出现：1）火山弧环境中常出现埃达克质岩一高镁安山岩-富Nb玄武质岩组合,它的形成可能与板片熔融以及熔体一地幔橄榄岩的相互作用有关;2）大陆活动碰撞造山带环境（如羌塘）中埃达克质岩常与同期钾质或橄榄玄粗质岩共生,这可能与俯冲陆壳熔融和俯冲陆壳熔体交代的地幔橄榄岩熔融有关;3）造山带伸展垮塌环境（如大别山）中埃达克质岩会伴随有镁铁质一超镁铁质岩浆出露,增厚下地壳产生埃达克质岩浆后的榴辉岩质残留体拆沉进入地幔,与地幔橄榄岩的混合可能形成后期镁铁质一超镁铁质岩浆的源区;4）大陆板内伸展环境中埃达克质岩常与同期橄榄玄粗质的岩石共生,增厚、拆沉下地壳,以及富集地幔的熔融或岩浆混合在岩石的成因中发挥了重要作用。     

云南九顶山正长斑岩年代学、岩石地球化学及Sr-Nd-Hf同位素特征

九顶山复式岩体沿北西向金沙江–红河断裂与南北向程海断裂交汇处发育,处于南北地洼区与滇西地洼区接触带,是滇西地洼期斑岩成矿带中段的代表性富碱斑岩体之一。该岩体由呈岩株、岩脉、岩墙或岩床等产出的斑状花岗岩、正长斑岩、(二长)花岗斑岩、碱长花岗斑岩和煌斑岩等组成。本文着重对正长斑岩的形成年代、岩石地球化学和成因特征开展研究,结果表明:正长斑岩的LA-ICP-MS锆石U-Pb年龄为34.6±0.7 Ma,即岩浆侵位于始新世(E2),属滇西地洼激烈期及新生代富碱岩浆活动高峰期(45~30 Ma)的产物;岩石具高硅(Si O256%)、高钾(K2O=3.38%~8.92%,K2O/Na2O1)、富碱(ALK=8.15%~11.15%)和低Mg O(3%)的特征,属钾玄岩系列–高钾钙碱性系列过铝质(A/CNK=0.71~1.22)花岗岩;在微量元素组成上,岩石高Sr(400×10-6)、低Y(18×10-6)和Yb(1.9×10-6),与陆内造山环境形成的"C型"钾质埃达克岩地球化学特征类似;全岩的Sr-Nd-Hf同位素组成特征显示岩浆源区是壳幔物质混合的"EMII型"富集地幔源。正长斑岩的形成应与印度–欧亚板块碰撞俯冲背景下,金沙江–红河断裂大规模左行走滑引起的热扰动和局部引张作用有关,在这种区域热–动力学条件下,地幔部分熔融与地壳物质发生混合作用,形成活化型壳幔混合源高钾富碱岩浆。     

Early Paleozoic continental crust accretion in the North Qinling: Evidences from geochronology,geochemistry and Sr-Nd-Hf isotopes of arc magmatic rocks in Taipingzhen areaSCIEI北大核心CSCD

二郎坪单元是位于北秦岭构造带中部的一个年轻地体,发育了大量的花岗岩类,是研究北秦岭早古生代大陆地壳增生的理想场所。本文对北秦岭构造带太平镇北英云闪长岩-奥长花岗岩体和蛮子营黑云母二长花岗岩体开展了岩石学、年代学、地球化学及Sr-Nd-Hf同位素研究。LA-ICP-MS锆石U-Pb测年表明,太平镇北奥长花岗岩和蛮子营黑云母二长花岗岩的形成时代分别为468.8±2.8Ma和462.2±1.9Ma。太平镇北岩体为高硅(71.79%-78.66%)、富钠贫钾(K_(2)O/Na_(2)O=0.27-0.77)的低钾拉斑-钙碱性系列岩石;蛮子营岩体为高硅(72.20%-74.90%)、富钾(K_(2)O/Na_(2)O=0.97-1.36)的高钾钙碱性岩石。两者轻重稀土分异均较明显,均具有富集Rb、Ba、Th、U、K等大离子亲石元素,而亏损Nb、Ta、P、Ti等高场强元素的特征。太平镇北岩体和蛮子营岩体具有类似的锆石εHf(t)值(奥长花岗岩8.2-12.7;黑云母二长花岗岩8.9-13.2)、全岩(87Sr/86Sr)i(奥长花岗岩0.704038-0.705221;二长花岗岩0.703876-0.705371)和全岩εNd(t)值(奥长花岗岩1.49-2.03;黑云母二长花岗岩1.68-1.92)。研究表明,太平镇北岩体岩浆源区为玄武质弧下地壳,岩浆结晶分异作用形成英云闪长岩和奥长花岗岩;蛮子营岩体岩浆为早期形成的英云闪长岩部分熔融形成。太平镇北岩体和蛮子营岩体均形成于洋内弧的构造环境,从弧玄武岩到富钠英云闪长岩、奥长花岗岩再到富钾的二长花岗岩,代表了地幔物质经过多阶段岩浆演化形成富硅富钾长英质地壳的过程。综上,认为洋内弧的形成和岩浆演化是北秦岭大陆地壳增生的重要方式之一。     

安徽庐枞盆地枞阳地区玄武质火山岩地球化学特征及其地质意义

庐枞盆地是长江中下游成矿带重要的矿集区之一,枞阳地区玄武质火山岩位于庐枞盆地中部。通过对枞阳地区玄武质火山岩进行岩石地球化学特征研究,探讨其源区性质及玄武质岩浆的演化过程。该区玄武质火山岩贫硅、富碱、低钛、低Mg^#值,属于钾玄质系列岩石; 稀土元素总量较高,具有LREE富集的右倾型稀土元素配分模式,有较弱的负Eu异常; 岩石富集Rb、K、Sr等大离子亲石元素,亏损Nb、Ta、Zr、Hf等高场强元素,Nb、Ta负异常。在岩石圈拉张作用下,枞阳地区富集岩石圈地幔发生部分熔融,形成的玄武质原始岩浆经历了地壳混染和分离结晶作用,沿区域深大断裂上侵,快速上升至地表,形成玄武质火山岩。     

研究"钾质和钠质两个地幔富碱岩浆体系"的刍议

钾质富碱岩浆岩组成的岩带研究表明,这类岩石普遍富碱和CaO,高钾,富Rb,Sr,Ba和放射性元素Th,U等,Rb/Sr相对较低;稀土元素总量较高,强烈富轻稀土,δEu较小;ISr多数介于0.705～0.706之间;INd较低,铅同位素较均一.Sr-Nd-Pb同位素特征表明,该岩类岩石的岩浆来源于EMⅡ型地幔源区,岩浆很可能直接来源于钾质富碱地幔.钠质富碱岩浆岩带岩石具富碱、高钠(Na2O＞K2O)的特点,同时富钛及大离子亲石元素和相对富集Nb,Ta,Zr以及Rb/Sr偏高等;ISr相对低,而INd稍高.这类岩石起源于钠质的富碱地幔源区.这些异常地幔源的形成与地幔流体交代作用有关.而超深大断裂作为岩浆上升的通道,是钾质和钠质地幔富碱岩系形成的重要条件.     

胶东金矿区高钾-钾质脉岩地球化学与俯冲-壳幔作用研究

胶东金矿区与金矿成矿伴生的脉岩为一套高钾 -钾质脉岩。根据地质、岩相学及与金矿化的时空关系 ,将主要岩石类型划分为煌斑岩、安山玢岩、英安玢岩类 ,它们分别形成与金矿化早期、同期和晚期 ;主要元素成分以富碱高钾、低钛为特征 ,成分变异具同源岩浆结晶分异演化的一般规律 ,早期以辉石和橄榄石、中晚期以角闪石和斜长石为主的矿物相分离结晶控制岩浆的演化 ;岩石明显富 Ba、Sr、Rb、K、L REE等大离子元素、强烈亏损 Cr、Ni及相对亏损 Th、Nb、Ti、Y等高场强元素元素 ,体现初始岩浆起源于富集地幔源区 ;大量的挥发组分及强烈的富集 Ba、Sr及低的 Sr/ Nd比值 ,指示源区为以俯冲陆源沉积为主、有玄武质洋壳参与的脱水、脱气等作用交代早期地幔楔形成的富集地幔源 ,初始岩浆是在中生代印支期形成的富集地幔向燕山期亏损方向演化的特定阶段发生低程度熔融形成 (熔融程度为 6 %～ 8% ) ;就位环境的不同是导致石英脉岩型与蚀变岩型矿区脉岩成岩作用有一定差别的主要原因     

西藏甲玛埃达克质斑岩的地球化学特征及意义

分析了西藏甲玛石英闪长玢岩-二长花岗斑岩-花岗闪长斑岩岩相学、年代学及地球化学特征,研究其形成演化及构造环境,并建立岩浆成因模式。甲玛石英闪长玢岩-二长花岗斑岩-花岗闪长斑岩是具弧岩浆地球化学特征的准铝质高钾钙碱性岩岩石系列,同时具有O型(向C型过渡)埃达克质岩和I型(或磁铁矿型)花岗岩的特征。其成因与新特提斯洋板片脱水熔融形成的流体与地幔楔发生地幔交代作用形成的EMⅡ型富集地幔有关。中新世兰格期(15 Ma左右),由于拉萨地体东西向的"崩塌",导致拉萨地体开始伸展减薄,从而使交代地幔(EMⅡ型富集地幔)减压熔融,形成了富含Cu、Au等成矿物质的具I型(或磁铁矿型)弧岩浆地球化学特征的准铝质富钾O型埃达克质铁镁质岩浆,并在沿该时期的正断层及裂谷系统侵位过程中,不断与下地壳高钾及中—高Fe/Mg的花岗质岩浆发生不同程度的岩浆混合作用,伴随着相对较弱的岩浆结晶分异过程不断侵位浅地表,进而形成了独特的石英闪长玢岩-二长花岗斑岩-花岗闪长斑岩岩石组合。     

Geochemistry, Petrogenesis and Geodynamic Relationships of Miocene Calc-alkaline Volcanic Rocks in the Western Carpathian Arc, Eastern Central Europe

We report major and trace element abundances and Sr, Nd andPb isotopic data for Miocene (16·5–11 Ma) calc-alkalinevolcanic rocks from the western segment of the Carpathian arc.This volcanic suite consists mostly of andesites and dacites;basalts and basaltic andesites as well as rhyolites are rareand occur only at a late stage. Amphibole fractionation bothat high and low pressure played a significant role in magmaticdifferentiation, accompanied by high-pressure garnet fractionationduring the early stages. Sr–Nd–Pb isotopic dataindicate a major role for crustal materials in the petrogenesisof the magmas. The parental mafic magmas could have been generatedfrom an enriched mid-ocean ridge basalt (E-MORB)-type mantlesource, previously metasomatized by fluids derived from subductedsediment. Initially, the mafic magmas ponded beneath the thickcontinental crust and initiated melting in the lower crust.Mixing of mafic magmas with silicic melts from metasedimentarylower crust resulted in relatively Al-rich hybrid dacitic magmas,from which almandine could crystallize at high pressure. Theamount of crustal involvement in the petrogenesis of the magmasdecreased with time as the continental crust thinned. A strikingchange of mantle source occurred at about 13 Ma. The basalticmagmas generated during the later stages of the calc-alkalinemagmatism were derived from a more enriched mantle source, akinto FOZO. An upwelling mantle plume is unlikely to be presentin this area; therefore this mantle component probably residesin the heterogeneous upper mantle. Following the calc-alkalinemagmatism, alkaline mafic magmas erupted that were also generatedfrom an enriched asthenospheric source. We propose that bothtypes of magmatism were related in some way to lithosphericextension of the Pannonian Basin and that subduction playedonly an indirect role in generation of the calc-alkaline magmatism.The calc-alkaline magmas were formed during the peak phase ofextension by melting of metasomatized, enriched lithosphericmantle and were contaminated by various crustal materials, whereasthe alkaline mafic magmas were generated during the post-extensionalstage by low-degree melting of the shallow asthenosphere. Thewestern Carpathian volcanic areas provide an example of long-lastingmagmatism in which magma compositions changed continuously inresponse to changing geodynamic setting. KEY WORDS: Carpathian–Pannonian region; calc-alkaline magmatism; Sr, Nd and Pb isotopes; subduction; lithospheric extension     

浙闽沿海早白垩世玄武岩锶、钕、铅同位素特征——古老富集型地幔的证据

浙闽沿海大面积出露的中生代酸性火山岩区有少量早白垩世玄武岩分布,它们具典型钾富集和铌等元素亏损特征,其同位素组成表现为较高ISr(0.7055-0.7106)、低的εNd(1.2--10.6,大多介于-3.2--10.6之间)及富放射性成因铅(²⁰⁶Pb/²⁰⁴Pb=18.355-18.726,²⁰⁷Pb/²⁰⁴Pb=15.455-15.799,²⁰⁸Pb/²⁰⁴Pb=38.530-39.319).这些特征表明玄武岩源区为一富集型的陆下岩石圈地幔,由古老的俯冲地壳物质再循环进入并交代地幔而形成。没有证据表明本区早白垩世基性和酸性岩浆之间发生过大规模的化学混合,但不排除同位素之间的交换以及局部的化学和机械混合。壳-幔混合与地壳混染仅在少数玄武岩的形成过程中起着较重要的作用。     

Estimation of the average contents of H2O, Cl, F, and S in the depleted mantle on the basis of the compositions of melt inclusions and quenched glasses of mid-ocean ridge basalts

Using our database of the compositions of melt inclusions and quenched glasses of basaltic magmas from mid-ocean ridges (MORB), the average concentrations and ratios of H₂O, Cl, F, S, K₂O, Ce, and Dy were determined in these magmas. Assuming that the concentration ratios of volatile components to K₂O are constant in the MORB magmas and their sources (depleted mantle, DM), and taking an average K₂O content in the DM of 72 ppm, the following average contents were estimated for the DM: 158 ppm H₂O, 6.6 ppm Cl, and 8.3 ppm F. Using an S/Dy ratio of 212 for MORB melts and a Dy concentration of 0.531 ppm in the DM, the concentration of S in the DM was estimated as 113 ppm. Our value for the average content of Cl is much higher than estimates obtained by other authors. This discrepancy could be due either to the assimilation of crustal (and hydrospheric) Cl by MORB magmas or to the deep mantle recycling of Cl. The latter mechanism is supported by the statistically significant positive correlation of Cl with K₂O, H₂O, and F. Such a correlation is not consistent with the hypothesis of basaltic magma contamination by seawater-derived chloride brines. Similar to other surface processes, the assimilation of crustal material operates within the existing global correlations and disturbs them. Based on the average integrated degree of mantle melting and the average degree of MORB magma differentiation (0.05), the average contents of potassium and volatile components in N-MORB and E-MORB mantle sources were estimated as 39 and 126 ppm K₂O, 103 and 197 ppm H₂O, 4.0 and 10.7 ppm Cl, and 3.9 and 9.1 ppm F, respectively. It is not likely that normal MORB magmas can be derived from depleted mantle that experienced a previous partial melting event (for instance, during the extraction of the primordial continental crust in the Early Precambrian), which was referred to as the ultradepleted mantle. Ordinary (not ultradepleted) MORB magmas can be derived either by the melting of a zone enriched DM (for instance, progressively enriched in incompatible components with depth), which is hardly possible, or by the continuous addition (mixing) of an enriched component to the ultradepleted mantle at the expense of sediments and crustal materials involved in deep recycling.     

Geochemical Evidence for a Rift-Related Origin of Bimodal Volcanism at Meseta Rio San Juan,North-Central Mexican Volcanic Belt

This study reports new geochemical and Sr and Nd isotope data for 11 samples of hynormative late Miocene (～6.5 Ma) basalt, basaltic andesite, and rhyolitic volcanic rocks from Meseta Rio San Juan, located in the states of Hidalgo and Queretaro, Mexico, in the north-central part of the Mexican Volcanic Belt (MVB). The in situ growth-corrected initial isotopic ratios of these rocks are as follows: ⁸⁷Sr/⁸⁶Sr 0.703400-0.709431 and ¹⁴³Nd/¹⁴⁴Nd 0.512524-0.512835. For comparison, the isotopic ratios of basaltic rocks from this area show very narrow ranges as follows: ⁸⁷Sr/⁸⁶Sr 0.703400-0.703540 and ¹⁴³Nd/¹⁴⁴Nd 0.512794-0.512835. The available geological, geochemical, and isotopic evidence does not support the generation of the basic and intermediate magmas by direct (slab melting), nor by indirect (fluid transport to the mantle) participation of the subducted Cocos plate. The basaltic magmas instead could have been generated by partial melting of the upper mantle. The evolved basaltic andesite magmas could have originated from such basaltic magmas through assimilation coupled with fractional crystallization. Rhyolitic magmas might represent partial melting of different parts of the underlying heterogeneous crust. Their formation and eruption probably was facilitated by extensional tectonics and upwelling of the underlying mantle. The different petrogenetic processes proposed here for basaltic and basaltic andesite magmas on one hand and rhyolitic magmas on the other might explain the bimodal nature of Meseta Rio San Juan volcanism. Finally, predictions by the author about the behavior of Sr and Nd isotopic compositions for subduction-related magmas is confirmed by published data for the Central American Volcanic Arc (CAVA).     

花岗岩混合问题:与玄武岩对比的启示——关于花岗岩研究的思考之一

最近,花岗岩混合成了花岗岩研究的热点,国内外许多学者探讨了花岗岩混合问题,并尝试用不同端元组分不同比例的混合来解释花岗岩的地球化学变化。本文从花岗岩与玄武岩的对比出发,探讨了花岗岩混合的可能性和局限性。作者认为,花岗岩混合的现象是普遍存在的,但是次要的和局部的。岩浆混合的能力或能干性(competence of mixing)主要取决于岩浆的黏性和温度,而黏性又与硅氧四面体有关。相对于玄武岩,花岗岩的SiO_2含量高,温度低,因此,花岗质岩浆的混合能干性很低。玄武质岩浆的混合是mixing(以化学混合为主),而花岗质岩浆的混合通常只是mingling(以机械混合为主),只有在少数情况下才能达到mixing的程度,例如,埃达克岩与地幔混合形成的高镁安山岩或高镁埃达克岩。许多人认为,花岗岩中的暗色微粒包体是花岗质岩浆混合作用最显著、最直接证据。研究表明,花岗岩中的暗色微粒包体大多是闪长质成分的,其初始成分大多是玄武质的。因此,暗色微粒包体不是花岗质岩浆混合作用最显著、最直接证据,而是玄武质岩浆混合能力强过花岗质岩浆的证据。与玄武质岩浆的起源比较,花岗质岩浆从一开始熔融就是不均一的,这源于源区的不均一及熔融过程的复杂性。花岗质岩浆原始均一性的假定是不可能的。花岗岩成分的变化以及在哈克图解中成分点的"连续谱系",主要是由源区不均一性引起的,混合和分异可能有一定的作用,但毕竟是次要的。花岗质岩浆从源区生成、迁移、直至在地表喷出或在浅部定位的全过程,是一个不断均一化和不均一化的过程。但是,由于花岗质岩浆的黏性大,上述过程及岩浆演化的程度和规模都受到限制,也限制了岩浆混合的程度和规模。许多人仅从花岗岩地球化学成分的变化来研究花岗岩的成因,而很少考虑花岗岩物理性质对岩浆演化的制约。对比玄武岩与花岗岩,我们认为,地球化学方法在花岗岩中应用的范围和程度可能远远不及玄武岩,我们应当重新考虑花岗岩的地球化学应用问题。     

Ar/Ar age and geochemistry of the post-collisional Miocene Yamadağ volcanics in the Arapkir area (Malatya Province), eastern Anatolia, Turkey

The Neogene Yamadağ volcanics occupy a vast area between Sivas and Malatya in eastern Anatolia, Turkey. These volcanic rocks are characterized by pyroclastics comprising agglomerates, tuffs and some small outcrops of basaltic–andesitic–dacitic rocks, overlain upward by basaltic and dacitic rocks, and finally by basaltic lava flows in the Arapkir area, northern Malatya Province. The basaltic lava flows in the Arapkir area yield a ⁴⁰Ar/³⁹Ar age of 15.8 ± 0.2 Ma, whereas the dacitic lava flows give ⁴⁰Ar/³⁹Ar ages ranging from 17.6 through 14.7 ± 0.1 to 12.2 ± 0.2 Ma, corresponding to the Middle Miocene. These volcanic rocks have subalkaline basaltic, basaltic andesitic; alkaline basaltic trachyandesitic and dacitic chemical compositions. Some special textures, such as spongy-cellular, sieve and embayed textures; oscillatory zoning and glass inclusions in plagioclase phenocrysts; ghost amphiboles and fresh biotite flakes are attributable to disequilibrium crystallization related to magma mixing between coeval magmas. The main solidification processes consist of fractional crystallization and magma mixing which were operative during the soldification of these volcanic rocks. The dacitic rocks are enriched in LILE, LREE and Th, U type HFSE relative to the basaltic rocks. The basaltic rocks also show some marked differences in terms of trace-element and REE geochemistry; namely, the alkaline basaltic trachyandesites have pronounced higher HFSE, MREE and HREE contents relative to the subalkaline basalts. Trace and REE geochemical data reveal the existence of three distinct magma sources – one subalkaline basaltic trachyandesitic, one alkaline basaltic and one dacitic – in the genesis of the Yamadağ volcanics in the Arapkir region. The subalkaline basaltic and alkaline basaltic trachyandesitic magmas were derived from an E-MORB type enriched mantle source with a relatively high- and low-degree partial melting, respectively. The magmatic melt of dacitic rocks seem to be derived from an OIB-type enriched lithospheric mantle with a low proportion of partial melting. The enriched lithospheric mantle source reflect the metasomatism induced by earlier subduction-derived fluids. All these coeval magmas were generated in a post-collisional extensional geodynamic setting in Eastern Anatolia, Turkey.     

中国东部新生代碱性玄武岩中的流体组成及其碳,氧同位素地球化学特征

利用热分解质谱法测定了中国东部新生代碱性玄武岩中流体挥发分的组成,并对不同温度段释放出的ＣＯ２气体测定了Ｃ,Ｏ同位素值,流体组成和ＣＯ２的Ｃ,Ｏ同位素值表明中国东部上地幔源区的不均一性,与其中所含幔源岩捕体相比,碱性玄武岩浆发育在相对氧化的环境中,并有外来流体组分的加入。     

Geochemical differences between subduction- and collision-related copper-bearing porphyries and implications for metallogenesis

Porphyry Cu (–Mo–Au) deposits occur not only in continental margin–arc settings (subduction-related porphyry Cu deposits, such as those along the eastern Pacific Rim (EPRIM)), but also in continent–continent collisional orogenic belts (collision-related porphyry Cu deposits, such as those in southern Tibet). These Cu-mineralized porphyries, which develop in contrasting tectonic settings, are characterized by some different trace element (e.g., Th, and Y) concentrations and their ratios (e.g., Sr/Y, and La/Yb), suggesting that their source magmas probably developed by different processes. Subduction-related porphyry Cu mineralization on the EPRIM is associated with intermediate to felsic calc-alkaline magmas derived from primitive basaltic magmas that pooled beneath the lower crust and underwent melting, assimilation, storage, and homogenization (MASH), whereas K-enriched collision-related porphyry Cu mineralization was associated with underplating of subduction-modified basaltic materials beneath the lower crust (with subsequent transformation into amphibolites and eclogite amphibolites), and resulted from partial melting of the newly formed thickened lower crust. These different processes led to the collision-related porphyry Cu deposits associated with adakitic magmas enriched by the addition of melts, and the subduction-related porphyry Cu deposits associated with magmas comprising all compositions between normal arc rocks and adakitic rocks, all of which were associated with fluid-dominated enrichment process.In subduction-related Cu porphyry magmas, the oxidation state (fO₂), the concentrations of chalcophile metals, and other volatiles (e.g., S and Cl), and the abundance of water were directly controlled by the composition of the primary arc basaltic magma. In contrast, the high Cu concentrations and fO₂ values of collision-related Cu porphyry magmas were indirectly derived from subduction modified magmas, and the large amount of water and other volatiles in these magmas were controlled in part by partial melting of amphibolite derived from arc basalts that were underplated beneath the lower crust, and in part by the contribution from the rising potassic and ultrapotassic magmas. Both subduction- and collision-related porphyries are enriched in potassium, and were associated with crustal thickening. Their high K₂O contents were primarily as a result of the inheritance of enriched mantle components and/or mixing with contemporaneous ultrapotassic magmas.     

滇西澜沧老厂地区玄武岩岩石成因与构造意义

对滇西澜沧老厂地区玄武岩进行了系统的主微量元素和Nd-Pb同位素地球化学研究,结果表明该玄武岩为典型的洋岛玄武岩(OIB)。Nd-Pb同位素研究表明,玄武岩浆含富集地幔组分。老厂地区玄武岩浆活动可能与地幔热柱有关,玄武岩可能为地幔热柱(软流圈)熔融产生的岩浆与富集的岩石圈地幔岩浆混合的产物。     

A petrological and geochemical study on time-series samples from Klyuchevskoy volcano,Kamchatka arc

To understand the generation and evolution of mafic magmas from Klyuchevskoy volcano in the Kamchatka arc, which is one of the most active arc volcanoes on Earth, a petrological and geochemical study was carried out on time-series samples from the volcano. The eruptive products show significant variations in their whole-rock compositions (52.0–55.5 wt.% SiO₂), and they have been divided into high-Mg basalts and high-Al andesites. In the high-Mg basalts, lower-K and higher-K primitive samples (>9 wt.% MgO) are present, and their petrological features indicate that they may represent primary or near-primary magmas. Slab-derived fluids that induced generation of the lower-K basaltic magmas were less enriched in melt component than those associated with the higher-K basaltic magmas, and the fluids are likely to have been released from the subducting slab at shallower levels for the lower-K basaltic magmas than for higher-K basaltic magmas. Analyses using multicomponent thermodynamics indicates that the lower-K primary magma was generated by ~13% melting of a source mantle with ~0.7 wt.% H₂O at 1245–1260?°C and ~1.9 GPa. During most of the evolution of the volcano, the lower-K basaltic magmas were dominant; the higher-K primitive magma first appeared in AD 1932. In AD 1937–1938, both the lower-K and higher-K primitive magmas erupted, which implies that the two types of primary magmas were present simultaneously and independently beneath the volcano. The higher-K basaltic magmas evolved progressively into high-Al andesite magmas in a magma chamber in the middle crust from AD 1932 to ~AD 1960. Since then, relatively primitive magma has been injected continuously into the magma chamber, which has resulted in the systematic increase of the MgO contents of erupted materials with ages from ~AD 1960 to present.