湖南瑶岗仙花岗岩体中包体的地质地球化学特征与岩浆演化

湖南瑶岗仙钨矿床与成矿有关的碱长花岗岩岩株中发育多种类型包体,包括花岗岩、石英闪长斑岩、黑色包体及云英岩析离体等。这些包体的地质地球化学性质不同,来源和演化路径不同,记载着瑶岗仙花岗岩成因和岩浆分异演化的历史。对这些包体岩石学、地球化学的研究,结合岩体本身和区域燕山早期花岗岩基的对比研究,明确了花岗岩包体(Ⅰb)来自深部岩浆房中早期结晶的花岗岩,性质与区域花岗岩相近;石英闪长斑岩和黑色包体为前寒武纪变质岩在重熔时的残留;云英岩析离体是由花岗岩Ⅰ的岩浆晚期进一步分异形成的浆液过渡态流体结晶沉淀而成;产于石英斑岩中的细粒黑云母花岗岩包体(Ⅲb)捕获自岩浆房中分异的补体或补体上升时初步分异形成的花岗岩。形成瑶岗仙岩体的花岗岩高度富含挥发分,致使其中的包体强烈同化混染,并富含萤石、云母、电气石等以及硫化物矿物。瑶岗仙岩体是区域花岗岩基所代表的岩浆房高度分异的岩浆上侵的产物,石英斑岩岩浆直接来自于岩浆房结晶分异残留岩浆,而非瑶岗仙岩体的分异产物。建立了瑶岗仙地区燕山早期岩浆演化序列:岩浆房主体(二长花岗岩)→细粒黑云母花岗岩(补体)→碱长花岗岩岩株→浆液过渡态流体成矿→石英斑岩脉侵入。     

九华山花岗岩岩浆分异特征及岩石成因

利用九华山花岗岩体明显的Ｒｂ、Ｂａ、Ｓｒ变化特征、强烈亏损的中稀土元素特征以及微量元素比值蛛网图和典型的岩石化学变异特征论证了九华山花岗质岩浆的结晶分异作用,探讨了岩浆结晶分异过程对黑云母成分及锶同位素数值的影响,从而指出了岩浆分异作用可能改变Ｉ型花岗岩类的黑云母成分标型以及锶同位素初始值的原有特征。依据九华山花岗岩体相对偏高的氧化度和相对偏低的铝指数,指出九华山岩体属于Ｉ型花岗岩成因类型,九华山－青阳复式花岗岩基可以看作相似成因类型的不同时间侵位的两个岩体的复合。     

岩浆演化对邯邢式铁矿成矿的制约：来自角闪石化学成分的证据

通过对比冀南邯邢地区矿山岩体和固镇岩体中角闪石的成分差异和形成的物理化学条件差异,讨论岩浆演化对邯邢式铁矿形成的制约。电子探针分析结果显示,强成矿的矿山岩体中角闪石主要为阳起石和镁角闪石,弱成矿岩体固镇岩体中角闪石主要为镁绿钙闪石、镁角闪石和阳起石,前者角闪石成分相对贫Fe、富Mg、Mn以及F和Cl等挥发分。角闪石矿物温压计计算结果显示：矿山岩体中的角闪石主要为岩浆侵位到浅部以后结晶,形成的温度和压力较低,氧逸度较高,未经历明显的结晶分异作用;固镇岩体中角闪石经历了深部岩浆房的结晶分异过程,而后侵位到浅部,大多形成于深部岩浆房,形成温度高、压力大。两者中角闪石成分特征与结晶时物理化学条件的明显差异表明,含有高挥发分F、Cl的岩浆有利于邯邢式铁矿的形成,角闪石在岩浆房深部的结晶分异过程导致硅酸盐体系中铁被过多和过早的消耗,不利于矽卡岩型铁矿的形成。     

北祁连西段黑下佬同碰撞花岗岩地质特征

甘肃省北祁连西段黑下佬二长花岗岩是加里东造山期同碰撞期产物,是以岩墙扩张机制形成的被动就位岩体,为下地壳部分熔融形成的花岗岩岩浆经分异结晶作用形成的I型花岗岩。按其副矿物组合特征,相当于磁铁矿系列,具有轻稀土富集的右倾式稀土元素配分形式,岩石的δ18OSMOW值与I型花岗岩的一般特征相符,岩石的微量元素蛛网图特征与同碰撞期花岗岩相似。     

南岭高分异花岗岩成岩与成矿

南岭是我国花岗岩研究程度最高的地区。特别是由于这一地区花岗岩与钨、锡、铌、钽、锆、铪、铜、钼、铅、锌、银、铋、锑、铀、锂、铍、稀土等金属成矿作用关系密切而受到国内外学术界关注。一般认为,南岭花岗岩及相关的成矿作用与花岗岩浆的高度结晶分异作用有关,但高分异作用发生的原因却并不明确。本文通过详细梳理南岭中生代燕山早期花岗岩的特征提出,这些花岗岩的结晶分异作用表现为岩浆房内晶粥体和残留岩浆的长期不断分凝。区内大面积的粗粒似斑状花岗岩为岩浆房早期结晶的堆晶体(主体),而晚期细粒花岗岩则为残留的高硅熔体(补体)。岩浆房发生充分结晶分异作用受控于两个因素:其一是岩浆房自身在演化过程中不断受到来自深部热的补给,使岩浆房内富含金属元素的残留熔体不断发生抽离,并向上运移。花岗岩体顶端的伟晶岩壳是保证抽离的熔体在近封闭环境下不断发生分异的另一个重要因素。这些特征使得南岭花岗岩的分异机制明显有别于喜马拉雅淡色花岗岩,后者以沿大型拆离断层就位并发生分异结晶为主要机制,两者可分别归类为热驱动分异和构造驱动分异类型,构成高分异花岗岩发生的两大重要机制。未来应结合锂资源的国家重大战略需求,对南岭地区高分异花岗岩,特...     

江西会昌锡矿花岗质喷出——侵入岩建造的岩石特点及其成因

本文通过对会昌岩背火山岩、花岗岩的地质学、岩石学、地球化学特征研究，认为火山岩与花岗岩是同源岩浆结晶分异的产物。花岗岩是由于地幔或下地壳富碱稀薄岩浆上侵，引起上地壳物质同熔，形成中酸性岩浆，经在深部岩浆房充分分异演化，形成酸性岩浆上侵结晶形成的产物。     

高加索Eldjurti花岗岩体的生成环境及岩浆演化特征

Ｅｌｄｊｕｒｔｉ岩体是俄罗斯内高加索地区阿尔卑斯造山活动晚期形成的花岗岩体。笔者研究了岩体中部由钻孔构成深达５０００ｍ的垂直剖面中岩石的岩石化学特征及岩体的生成环境和岩浆演化特征，结果表明Ｅｌｄｊｕｒｔｉ花岗岩体分异成两个岩石化学特征不同的单元，相对偏在性，岩浆分异程度较左的浅部和偏酸性，岩浆分异程度较高的深部。浆结晶分异作用使熔体中Ａｌ，Ｍｇ，Ｆｅ，Ｃａ，Ｎａ不断被消耗，Ｓｉ，Ｋ相对富集于残余熔     

安徽青阳—九华山复式岩体的成因及成矿潜力——来自锆石Hf同位素和微量元素的证据

青阳—九华山复式岩体是安徽南部地区出露面积最大、最具代表性的复式岩体,该复式岩体的岩浆源区、演化过程和成矿联系等问题仍需要进一步查明。在前期对青阳—九华山复式岩体的地质、地球化学特征研究基础上,本文进一步开展了锆石微量元素与Hf同位素分析与研究。结果显示,青阳—九华山复式岩体4个阶段从早到晚（花岗闪长岩二长花岗岩正长花岗岩细粒花岗斑岩）,晚期(第三、第四阶段)比早期(第一、第二阶段)岩浆岩的锆石εHf（t）值呈显著增高趋势,岩浆形成温度升高（705.3℃ 715.9℃ 827.1℃ 805.5℃）,氧逸度降低（93.8 149.170.1 69.9）。进一步分析认为,青阳—九华山复式岩体源于同一具有壳幔混源的岩浆源区,随着时间的演化,岩浆房中幔源组分比例逐渐增高,幔源物质的加入,不仅提高了晚期岩浆形成温度,一定程度改变了源区组成。青阳—九华山复式岩体4个阶段花岗岩均经历了榍石、角闪石、金红石、斜长石等矿物的分离结晶,晚期（第三、第四阶段）花岗岩相比早期（第一、第二阶段）花岗岩具有更高的分异程度。青阳—九华山复式岩体中第一、第二阶段花岗岩具有较好的W—多金属矿床成矿潜力。     

赣中地区晚中生代高分异A型花岗岩的厘定及其成因研究

强烈的分离结晶作用会显著改变A型花岗岩的主要地球化学指标,模糊A型花岗岩与I、S型花岗岩之间的地球化学界限,如何准确判别成为一个难题,江西大乌山岩体提供了一个较为理想的研究实例。大乌山岩体位于华夏板块中部、南岭以北的赣中地区,由中粒黑云母二长花岗岩和细粒含白云母黑云母碱长花岗岩组成,锆石U-Pb定年结果显示,前者结晶年龄为156 Ma,后者为155～157 Ma。岩体具有低P_2O_5(0.05%～0.16%)、高SiO_2(70.8%～74.9%)、高Rb/Sr(平均9.05)和Rb/Ba比值(平均2.38)的特征,弱过铝到强过铝质;Rb-Ba-Sr和Th/Nd-Th等元素含量关系特征显示高分异花岗岩的特点;较高的Ga/Al比值(2.89～3.48)和初始锆石饱和温度(839℃)以及填隙状黑云母所反映的贫水岩浆特征,均与A型花岗岩特性一致。高度的岩浆分异作用过程中,由于锆石、榍石等富锆矿物发生强烈分离结晶作用,结果使该岩体的(10000×Ga/Al)-(Zr+Nb+Ce+Y)以及Zr-SiO_2两元相关演化趋势显著不同于分异的I、S型花岗岩;此外,该岩体的Y/Nb比值大于1.2。综合以上特征,可以判定大乌山岩体为高分异的A_2型花岗岩。因此,在岩石学、矿物学和地球化学分析基础上,利用高分异的花岗岩在(10000×Ga/Al)-(Zr+Nb+Ce+Y)以及Zr-SiO_2二元图解上所表现出的不同演化趋势是判别高分异花岗岩的成因类型比较有效的方法。该岩体具有较低的ε_(Nd)(t)(-9.23～-14.6)和ε_(Hf)(t)(-10.2～-6.5)值,两阶段Nd模式年龄为1.7～2.0 Ga,结合区域变质岩的资料,推断该岩体起源于类似于周潭群包含正-副变质岩的复合源区,在经历了印支期S型花岗质岩浆的抽离之后,在燕山早期拉张构造环境下,残留的较难熔的类似于闪长质的物质在上涌地幔物质加热的背景下进一步发生部分熔融而形成。     

桂东北地区几个加里东期花岗岩体的地球化学特征及其构造环境判别

通过对该区花岗岩的常量元素、稀土元素及微量元素成分分析对比,利用岩石化学特征并结合岩体产出地质条件,对花岗岩形成的构造环境进行了综合判别.提出桂东北花岗岩具有相同的成因和来源,属同一岩浆结晶分异演化而来.结晶分异作用为花岗岩的主要成岩方式.越城岭、苗儿山和海洋山岩体主要形成于同碰撞的挤压构造环境下,而大宁岩体总体构造环境为处于碰撞前向同碰撞转换的挤压构造环境.     

桂东北里松花岗岩中暗色包体的岩浆混合成因

在桂东北姑婆山地区的里松花岗岩中,暗色包体广泛分布,包体的形貌、结构构造和矿物学特征表明,它们是岩浆快速冷凝结晶产物;主元素和微量元素组成说明它们属钾玄岩系列,其源岩具OIB型微量元素特征;包体与寄主花岗岩中锆石U-Pb年龄的相同性,排除了来源于深部固体岩石熔融残留体或浅部围岩捕虏体的可能性,而两种岩石化学成分、岩石结构暗色包体和寄主花岗岩在岩石结构和全岩Sr-Nd同位素组成方面的明显差别性,又排除了同源包体或析离体、堆积体的可能性。里松花岗岩在很多地质-地球化学特征上都介于里松暗色包体和姑婆山主体花岗岩之间,里松暗色包体的总体特征显示了岩浆混合成因,是里松暗色包体岩浆与姑婆山主体花岗岩岩浆发生混合时不完全混合的残留物。     

华县西沟地区花岗岩体地球化学及成矿潜力

陕西华县西沟地区花岗岩体接触带发育钼多金属矿化,矿化与花岗岩关系密切,主要受剪切带控制.岩体的岩石地球化学研究并与金堆城钾长花岗斑岩比较,二者同是燕山期岩浆活动的产物;金堆城岩体具有同碰撞造山期地壳部分熔融作用产物特征,而西沟岩体为造山晚期岩浆分离结晶作用产物,综合成矿条件分析,认为西沟地区具有钼多金属成矿的潜力.     

Field evidence,mineral chemical and geochemical constraints on mafic-felsic magma interactions in a vertically zoned magma chamber from the Chotanagpur Granite Gneiss Complex of Eastern India

The Nimchak granite pluton (NGP) of Chotanagpur Granite Gneiss Complex (CGGC), Eastern India, provides ample evidence of magma interaction in a plutonic regime for the first time in this part of the Indian shield. A number of outcrop level magmatic structures reported from many mafic-felsic mixing and mingling zones worldwide, such as synplutonic dykes, mafic magmatic enclaves and hybrid rocks extensively occur in our study domain. From field observations it appears that the Nimchak pluton was a vertically zoned magma chamber that was intruded by a number of mafic dykes during the whole crystallization history of the magma chamber leading to magma mixing and mingling scenario. The lower part of the pluton is occupied by coarse-grained granodiorite (64.84–66.61?wt.% SiO₂), while the upper part is occupied by fine-grained granite (69.80–70.57?wt.% SiO₂). Field relationships along with textural and geochemical signatures of the pluton suggest that it is a well-exposed felsic magma chamber that was zoned due to fractional crystallization. The intruding mafic magma interacted differently with the upper and lower granitoids. The lower granodiorite is characterized by mafic feeder dykes and larger mafic magmatic enclaves, whereas the enclaves occurring in the upper granite are comparatively smaller and the feeder dykes could not be traced here, except two late-stage mafic dykes. The mafic enclaves occurring in the upper granite show higher degrees of hybridization with respect to those occurring in the lower granite. Furthermore, enclaves are widely distributed in the upper granite, whereas enclaves in the lower granite occur adjacent to the main feeder dykes.Geochemical signatures confirm that the intermediate rocks occurring in the Nimchak pluton are mixing products formed due to the mixing of mafic and felsic magmas. A number of important physical properties of magmas like temperature, viscosity, glass transition temperature and fragility have been used in magma mixing models to evaluate the process of magma mixing. A geodynamic model of pluton construction and evolution is presented that shows episodic replenishments of mafic magma into the crystallizing felsic magma chamber from below. Data are consistent with a model whereby mafic magma ponded at the crust-mantle boundary and melted the overlying crust to form felsic (granitic) magma. The mafic magma episodically rose, injected and interacted with an overlying felsic magma chamber that was undergoing fractional crystallization forming hybrid intermediate rocks. The intrusion of mafic magma continued after complete solidification of the magma chamber as indicated by the presence of two late-stage mafic dykes.     

杭州河上地区新元古代火山岩与侵入岩的岩浆同源性

杭州河上地区是浙西北上元古界上墅组火山岩发育的典型地区,同时还发育新元古代辉绿岩和碱长花岗岩板状复合浅成侵入体。火山岩与侵入岩在空间上密切共生,形成时间相近,皆为晋宁晚期构造岩浆活动的产物。火山喷发并伴随的岩浆侵入经历了两个阶段,每个阶段的火山岩与侵入岩在岩石类型、岩石化学和地球化学方面具有相似性或一致性,稀土元素分布型式基本一致,说明每个阶段的火山岩与侵入岩来源于同一岩浆源,均是同源岩浆活动的产物。第一阶段上墅组基性火山岩与次坞辉绿岩体起源于亏损程度较低的地幔,或来源于亏损地幔的岩浆受到陆壳物质的混染;第二阶段上墅组酸性火山岩与道林山碱长花岗岩体可能起源于地壳中既含有基性地壳组分和又含有酸性地壳组分的源区的部分熔融。     

Petrogenetic modelling of in situ fractional crystallization in the zoned Loch Doon pluton,Scotland

The late Caledonian Loch Doon granitic intrusion ranges in composition from hypersthene diorite at the margin, through quartz diorite, granodiorite and granite to cordierite microgranite at its core. Petrogenetic modelling of trace element variations and least squares analysis of major elements indicate that two distinct magmas are involved, each magma controlled by crystallization of plag-opx-cpx-bio. Late stage rocks related to the second magma include the cordierite microgranites and aplites, which are interpreted as the final residue which crystallized rapidly after a build up and loss of volatiles.Analyses of whole rocks and minerals for REE's and other elements of moderate-high ionic potential indicate that these elements are strongly controlled by minor phase crystallization; apatite, zircon, sphene and allanite are dominant at intermediate compositions but other accessory minerals such as monazite and xenotime may also become important at acid compositions.It is probable that within each magma the mechanisms of crystal settling and filter pressing operated, the former being initially dominant, and the latter becoming more important with increasing degree of fractional crystallization.     

新疆磁海铁矿区镁铁质岩及正长岩锆石U-Pb年代学、岩石地球化学特征:对成岩、成矿作用的制约

对新疆磁海铁矿区镁铁-超镁铁质岩与铁成矿关系、正长岩与镁铁质岩关系的解剖,是认识磁海矿区成岩、成矿过程及构造背景的关键。本文利用SIMS锆石U-Pb测年法,获得磁海辉绿岩、辉长辉绿岩、磁南辉长岩、磁海北角闪石英正长岩的206Pb/238U-207Pb/235U谐和年龄分别为275.1±2.2Ma、281.9±3.2Ma、273.0±1.9Ma和273.0±1.8Ma,这与北山乃至北疆地区主要含铜镍-钒钛磁铁矿的镁铁-超镁铁质岩年龄一致。岩石地球化学特征研究显示,从辉石岩到辉长岩,再到辉绿岩,经历了Ti逐渐富集、Mg#和m/f值先增加后降低的过程,角闪石英正长岩具有A型花岗岩特征,与辉长岩、辉绿岩在成因上存在互补关系。综合年代学和地球化学特征,磁南辉石岩、辉长岩、磁海辉绿岩、辉长辉绿岩以及磁海北边的角闪石英正长岩为同源岩浆演化的产物,岩浆演化过程中受地壳混染作用微弱,在岩浆演化的早期,磁铁矿的结晶分离主导着岩浆成分的改变,当岩浆演化到辉长岩阶段,岩浆开始以结晶分异作用为主;磁铁矿的分离结晶时间早于钛铁矿,岩浆型的金属硫化物为磁铁矿和钛铁矿结晶过渡阶段的产物。磁海镁铁-超镁铁质岩石在成岩及成矿作用上可能与在时间和空间上相邻近的塔里木早二叠世大火成岩省有密切关系。     

内蒙古多伦中酸性侵入岩岩石地球化学特征及构造环境分析

内蒙古多伦县北部分布四个中酸性岩体,其岩石类型为:二长花岗岩、石英正长岩、石英正长斑岩和石英二长斑岩,出露面积0.5~12.4km~2不等,产状为岩株。同位素测龄成果显示二长花岗岩形成年龄为143.8±1.2 Ma,属晚侏罗世晚期(J_3);石英二长斑岩形成年龄为138.4±0.6Ma,属早白垩世早期(K_1)。岩石系列为高钾、钙碱性系列。据岩石地球化学特征推断:研究区内的四个岩体具同源特征,是岩浆同源演变的产物,岩浆来源为中下地壳。结合岩石Q-Ab-Or-H_2O相图,岩浆结晶温度接近750~800℃。二长花岗岩形成于大陆碰撞地球动力学环境即陆内造山构造环境;石英正长岩、石英正长斑岩、石英二长斑岩形成于造山后期构造环境。研究区在晚侏罗世晚期陆内碰撞造山运动已经结束而转入造山后期构造环境,至早白垩世早期大规模双峰式火山岩的喷发标志着研究区全面进入陆内造山后的裂谷阶段或者陆内伸展运动阶段。     

Intrusion of basaltic magma into a crystallizing granitic magma chamber: The Cordillera del Paine pluton in southern Chile

The Cordillera del Paine pluton in the southernmost Andes of Chile represents a deeply dissected magma chamber where mafic magma intruded into crystallizing granitic magma. Throughout much of the 10x15 km pluton, there is a sharp and continuous boundary at a remarkably constant elevation of 1,100 m that separates granitic rocks (Cordillera del Paine or CP granite: 69–77% SiO₂) which make up the upper levels of the pluton from mafic and comingled rocks (Paine Mafic Complex or PMC: 45–60% SiO₂) which dominate the lower exposures of the pluton. Chilled, crenulate, disrupted contacts of mafic rock against granite demonstrate that partly crystallized granite was intruded by mafic magma which solidified prior to complete crystallization of the granitic magma. The boundary at 1,100 m was a large and stable density contrast between the denser, hotter mafic magma and cooler granitic magma. The granitic magma was more solidified near the margins of the chamber when mafic intrusion occurred, and the PMC is less disrupted by granites there. Near the pluton margins, the PMC grades upward irregularly from cumulate gabbros to monzodiorites. Mafic magma differentiated largely by fractional crystallization as indicated by the presence of cumulate rocks and by the low levels of compatible elements in most PMC rocks. The compositional gap between the PMC and CP granite indicates that mixing (blending) of granitic magma into the mafic magma was less important, although it is apparent from mineral assemblages in mafic rocks. Granitic magma may have incorporated small amounts of mafic liquid that had evolved to >60% SiO₂ by crystallization. Mixing was inhibited by the extent of crystallization of the granite, and by the thermal contrast and the stable density contrast between the magmas. PMC gabbros display disequilibrium mineral assemblages including early formed zoned olivine (with orthopyroxene coronas), clinopyroxene, calcic plagioclase and paragasite and later-formed amphibole, sodic plagioclase, mica and quartz. The early formed gabbroic minerals (and their coronas) are very similar to phenocrysts in late basaltic dikes that cut the upper levels of the CP granite. The inferred parental magmas of both dikes and gabbros were very similar to subalkaline basalts of the Patagonian Plateau that erupted at about the same time, 35 km to the east. Mafic and silicic magmas at Cordillera del Paine are consanguineous, as demonstrated by alkalinity and trace-element ratios. However, the contemporaneity of mafic and silicic magmas precludes a parent-daughter relationship. The granitic magma most likely was derived by differentiation of mafic magmas that were similar to those that later intruded it. Or, the granitic magma may have been contaminated by mafic magmas similar to the PMC magmas before its shallow emplacement. Mixing would be favored at deeper levels when the cooling rate was lower and the granitic magma was less solidified.     

西天山托云盆地及周边中新生代岩浆活动的岩石学、地球化学与年代学研究

天山西南部白垩纪-老第三纪发育的托云盆地及其周边出露的岩浆岩是一套完整的碱性岩浆岩系列，包含了苦橄质玄武岩、玄武岩、碧玄岩、碱玄岩（橄榄玄武岩、黑云母辉长二长岩、辉长辉绿岩、辉石橄榄岩）和响岩等多种岩石类型。野外工作显示有火山喷出岩和侵入岩两种不同的产状。年代学结果指示岩浆岩形成于120-50Ma间，为晚白垩世-老第三纪盆地形成演化阶段岩浆活动的产物。分离结晶作用是岩浆演化和岩浆系列形成最主要的因素，托云岩浆岩大致经历了结晶分异过程的两个阶段：早期苦橄质岩浆中橄榄石、尖晶石的结晶分离，表现为MgO和微量元素Cr含量随SiO2含量增加大幅度的降低；晚期主要是单斜辉石、斜长石和钛铁矿等矿物的结晶分异，以CaO、FeO、TiO2等随SiO2含量增加大幅度的降低为特点。苦橄质岩石的出现指示了地幔较高温熔融事件的存在，进而为托云盆地地幔柱的存在提供了有力的证据。无论如何，碱性岩浆的活动表明托云盆地形成的大地构造背景是大陆主动裂谷环境，对应的深部背景为区域性的地幔柱构造。首次发现的响岩是结晶分异作用的最终产物。响岩较极端地指示了岩浆结晶分离过程对岩浆演化的巨大影响。托云岩浆岩的同位素特征指示其源区是一个接近于PREMA地幔，但微量元素特征显示其受地壳流体交代改造的特点。岩浆岩的Nd同位素TDM集中在250～600Ma之间，反映了一个古生代时期形成的新生岩石圈地幔，与新疆北部地区的晚古生代新生岩石圈地幔的事实相符。     

东昆仑东段可日正长花岗岩年龄和岩石成因对东昆仑中三叠世构造演化的制约

可日岩体位于东昆仑造山带东段东昆北构造带,岩性为含暗色微粒包体正长花岗岩。LA-ICP-MS锆石U-Pb同位素定年结果显示寄主岩和暗色微粒包体的结晶年龄分别为231.58±0.49Ma和232.6±2.3Ma。可日正长花岗岩主体为弱过铝质中钾钙碱性I型花岗岩,具有较高的SiO_2含量(72.06%~74.49%)和Na_2O/K_2O(1.00~1.35)、Nb/Ta(15.4~27.9)比值,较低的值(14~31)和Rb/Ba(0.10~0.46)比值,富集大离子亲石元素(LILE),亏损高场强元素(HFSE)。岩体为巴颜喀拉地块同东昆仑地块碰撞后,板片断离持续作用产生的镁铁质熔体底侵中下地壳使其部分熔融的结果。暗色微粒包体同寄主岩具有相近的结晶年龄、较细粒度、含有寄主岩捕获晶、针状磷灰石,显示包体是镁铁质岩浆注入寄主岩快速冷却的产物。由于寄主岩分离结晶,残留熔体与包体的浓度梯度差导致元素扩散,使两者具有物质交换。东昆仑东段晚古生代-早中生代幔源岩浆对花岗质岩浆的影响是一个持续的过程,从俯冲阶段早期流体交代地幔熔融,到俯冲阶段后期板片断离,然后同碰撞阶段板片断离的持续影响,再到后碰撞阶段加厚地壳的拆沉作用,由于地球动力学体制不同,导致幔源岩浆影响的大小和特征不同。可日岩体年龄及岩石成因显示东昆仑地区在232Ma左右处于同碰撞阶段。