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1.
汪洋 《大地构造与成矿学》2014,(3)
薛家石梁-黑山寨岩浆杂岩体出露于北京市昌平区东部,由上庄辉长岩、薛家石梁闪长岩、黑山寨石英二长岩、湖门二长岩和黑熊山花岗岩组成。结合薛家石梁-黑山寨杂岩体的地质产状、各类岩性的空间分布和接触关系以及侵位深度的估算结果,我们认为该杂岩体是一个被剥露出来的掀斜岩浆房。根据岩石学特征和地球化学分析结果,可将杂岩体的岩石归为5大类:(1)堆晶成因的含钒钛磁铁矿辉长岩;(2)低Ti辉长岩;(3)高Ti闪长岩;(4)高Sr低Y中酸性岩(低Ti闪长岩、二长岩、石英二长岩)和(5)黑熊山铁质花岗岩。其岩浆活动分为3批次:第1批次的原始幔源岩浆经AFC过程演化形成该杂岩体所包含的堆晶辉长岩、低Ti辉长岩、低Ti闪长岩、石英二长岩和二长岩;在岩浆房未固结时第2批次的高Ti闪长岩浆注入其中;然后是第3批次的壳源铁质花岗岩浆注入岩浆房上部。岩浆固结后该岩浆房经历了大角度掀斜,是云蒙山变质核杂岩下盘在拆离运动过程中发生背形穹弯变形的结果。该杂岩体所含的高Ti闪长岩的地球化学和Sr-Nd-Pb同位素特征指示当时存在亏损放射性Pb同位素的岩石圈地幔,不支持岩石圈拆沉的动力学模式。薛家石梁-黑山寨杂岩体是燕山造山带挤压变形导致的地壳增厚和增温所引起的重力崩塌过程的岩浆事件响应。 相似文献
2.
东天山尾亚复式岩株热变质晕特征 总被引:1,自引:1,他引:0
尾亚椭圆形复式岩株位于兰新铁路尾亚车站一带,距哈密市约140 km。在构造上位于卡瓦布拉克微地块中部几个大构造线交切处的构造软弱部位。它是由尾亚超单元和环形山超单元组成的典型环状杂岩体(称尾亚超单元组合)。经对其地质特征研究,前者由深源碱性的碱性辉长岩-石英二长岩-石英正长岩-碱长花岗岩-斑状钾长花岗岩5个单元组成;后者由壳幔混合源的石英闪长岩-花岗间长岩-二长花岗岩-钾长花岗岩4个单元组成,它们间为超动式接触关系,反映了岩株是不同时代、不同岩浆的演化序列。 尾亚复式岩株使围岩地层有显著的避让机械… 相似文献
3.
青海南山沟后岩浆杂岩体锆石U-Pb年代学、岩石成因及其地质意义 总被引:1,自引:0,他引:1
青海南山构造带是衔接宗务隆构造带、南祁连构造带和西秦岭造山带的重要结合带。沟后岩浆杂岩体位于青海南山构造带东段,主要由辉长岩、辉长闪长岩、石英闪长岩、花岗闪长岩组成。本文对沟后岩浆杂岩体进行了详细的岩石学、岩石地球化学和LA-ICP-MS锆石U-Pb同位素年代学研究。结果表明,辉长岩、辉长闪长岩、石英闪长岩、花岗闪长岩及暗色微粒包体的结晶年龄分别为248.8±2.6 Ma、243.2±2.1 Ma、243.1±0.9 Ma、244.0±2.1 Ma和249±3 Ma。辉长岩富铁、镁,贫碱;辉长闪长岩高铝、富钙和钠,二者均为钙碱性岩类。石英闪长岩和花岗闪长岩为准铝-弱过铝质高钾钙碱性岩,暗色微粒包体属钙碱性-碱性岩系列。不同岩石类型均表现为富集大离子亲石元素(Cs、Rb、K)和Pb,亏损高场强元素(Nb、Ta、Ti)和P、Ba负异常;稀土元素配分曲线均具有轻重稀土分异的右倾特征,具弱-中等负Eu异常。岩相学和岩石地球化学特征表明沟后岩浆杂岩体具壳幔岩浆混合特征,暗示其可能形成于由俯冲流体交代地幔楔部分熔融的幔源岩浆底侵作用下的构造环境。辉长岩为幔源岩浆经分离结晶的产物,辉长闪长岩为幔源岩浆经分异演化并混染少量壳源岩浆的产物;中基性岩浆与壳源中酸性岩浆发生混合并经历一定的分异演化过程形成了石英闪长岩和花岗闪长岩。结合区域地质资料分析认为,沟后岩浆杂岩体可能代表了研究区早三叠世晚期-中三叠世早期宗务隆洋向南消减作用相关的构造岩浆事件。 相似文献
4.
太行山南段平顺杂岩体成因:岩石学、年代学和地球化学证据 总被引:3,自引:0,他引:3
太行山南段平顺杂岩体主要由橄榄角闪辉长岩,角闪辉长-闪长岩和闪长岩组成,锆石SHRIMP U-Pb测年显示,橄榄角闪辉长岩体和闪长岩体年龄分别为123.4±1.7 Ma和125.3±2.3 Ma,说明岩体形成于早白垩世。平顺杂岩体SiO2含量介于42.82%~63.54%之间,以高Mg#,富Na,高Sr、Cr、Ni,以及富集LILE、LREE,亏损HFSE、HREE为特点,并具有相对低的87Sr/86Sr初始比值和明显偏低的εNd(125 Ma)值,表明岩浆具有壳幔双重属性。结合辉长岩中地幔包体已有的研究成果,认为辉长岩是由富硅流体交代的亏损地幔橄榄岩经低程度部分熔融形成;高Mg闪长岩起源于下地壳部分熔融,并与一定规模的幔源岩浆发生混合;角闪辉长-闪长岩形成于辉长质岩浆与高Mg闪长质岩浆的混合作用。 相似文献
5.
塔什库尔干碱性杂岩体形成时代及其地质意义 总被引:11,自引:0,他引:11
帕米尔构造结是青藏高原变形最强烈的地区之一,区内新生代岩浆侵入活动发育,既有壳源岩浆侵位,也有幔源岩浆广泛分布。根据岩石学和地球化学研究,侵入岩可分为幔源碱性正长岩和壳源花岗岩2个系列。幔源碱性正长岩总体上由暗色正长岩、浅色正长岩和碱性花岗岩组成,其成因为岩浆不不混溶作用。壳源花岗岩类成分单一,具有低共熔岩浆属性,其成因可能与幔源岩浆对地壳加热有关。利用碱性正长岩的钾长石进行^40Ar-^39Ar法获得3个分别为大约23Ma、13Ma和8Ma坪年龄数据,结合岩体地质特征,认为它们分别代表了碱性正长岩和花岗岩的侵位时间以及后期构造热事件。研究结果表明,岩浆活动是帕米尔构造结形成和帕米尔强烈变形的主要因素之一。 相似文献
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对桂东南马山杂岩体中的辉长岩进行了锆石原位LA-ICP-MS分析,获得了157.8±2.4Ma的206Pb/238U的加权平均年龄,表明该岩体形成于燕山早期的晚侏罗世。两件样品具有极低的SiO2,指示其为堆晶成因,无Nb、Ta亏损表明它们形成时没有受到明显地壳物质混染,因此其+4.46和4.24的d(158Ma)值反映了岩浆来自中度亏损的地幔源区,是对幔源物质亏损程度的最大估计;中基性岩具有类似于OIB的微量元素特征,不同程度的弱Nb、Ta亏损以及Sr、Nd同位素的变化,指示了幔源岩浆受到了不同程度的地壳物质的混染;相对于华南大多数同期或中生代花岗岩,马山杂岩体中花岗岩具有较小的d值和年轻的T2DM年龄,指示岩体形成时幔源物质的加入。因此,桂东南地区在燕山早期为拉张环境,马山杂岩体为板内拉张环境下中等亏损程度的地幔源区和下地壳物质部分熔融作用导致的岩浆作用产物。 相似文献
7.
小兴安岭东南晚奥陶世鹤林侵入杂岩体成因探讨 总被引:1,自引:0,他引:1
小兴安岭东南晚奥陶世鹤林侵入杂岩体岩性变化较大,由角闪辉长岩—(石英)闪长岩—英云闪长岩—二长花岗岩组成,不同岩石类型在野外宏观上呈相互侵入、包裹和渐变的接触关系;在(石英)闪长岩、英云闪长岩和二长花岗岩中均发育微细粒闪长质包体,包体多具明显塑性流变特点的浑圆外形和典型岩浆结构、针状磷灰石及捕获的寄主岩钾长石、石英斑晶,为MME型岩浆混合成因包体;杂岩体相对富集LILE(Ba、Sr、Rb)、HFS(U、Th、Zr、Ce)元素等,显示出壳源特点,而较高的εNd(t)值(-2.38~-3.77)显示以幔源为主的特点。研究表明杂岩体具明显的壳幔岩浆混合成因的岩相学、岩石化学和地球化学特征,形成于基性岩浆底侵作用下的陆缘弧型活动大陆边缘构造环境。 相似文献
8.
闽西南晚中生代四方岩体同位素年代学、地球化学及其构造意义 总被引:21,自引:8,他引:21
闽西南地区四方岩体主要由花岗闪长岩和花岗闪长斑岩组成 ,花岗闪长岩单颗粒锆石 U-Pb年龄为 10 7.8±1.2 Ma,角闪石 Ar-Ar年龄为 10 4.8± 0 .8Ma,形成于早白垩世。岩体是在伸展拉张构造环境下以快速冷却 (50~ 60℃ / Ma)侵位的 ,岩石相对富 Na2 O,A / CNK<1,具壳 -幔混合源 I型花岗岩特征。岩石富 K、Rb、Th、U、L REE,贫 Ti、Nb、Ta、Sr,具火山弧/活动大陆边缘钙碱性岩系的特征。 (87Sr/ 86Sr) i为 0 .70 63 5~ 0 .70 898,εNd(t)为 -5.2 4~ -3 .69,TDM为 1.3 3~ 1.2 1Ga。岩石主要由幔源岩浆与中下地壳物质部分熔融形成的花岗质岩浆的混合形成的。与闽东沿海地区相比 ,晚中生代时闽西南地区总体处于与华南软流圈地幔上涌有关的伸展拉张构造环境 ,但由玄武岩浆底侵作用引发的壳幔作用并不强烈。该时期中酸性岩浆作用与成矿关系十分密切 相似文献
9.
新疆乌伦古富碱侵入岩成因探讨 总被引:51,自引:3,他引:51
对沿乌伦古深断裂分布的钠闪石花岗岩、钾长花岗岩、闪长岩、碱性正长岩等富碱侵入体进行了较系统的岩石化学、微量元素、稀土元素地球化学及O、Pb、Sr、Nd同位素组成研究,确认它们为一类幔源重熔分异型富碱侵入岩类。在分析其物质来源、形成构造环境和成岩条件等特征基础上,用部分熔融、多阶段分离结晶和分离结晶-地壳混染等模型探讨了其成岩机理。 相似文献
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本文选取冈底斯带东段加查县东北部丝波绒曲复式岩体为对象,对其进行了岩相学、地质年代学、岩石地球化学以及Sr-Nd-Hf同位素组成的综合研究,据此探讨了该复式岩体的成因及其对构造演化的启示。研究结果表明,该复式岩体由早侏罗世辉长岩-花岗岩杂岩(188~185Ma)和始新世花岗质岩石(~47Ma)构成,两期花岗质岩石中普遍发育塑变形态的镁铁质包体。早侏罗世杂岩由角闪辉长岩和英云闪长岩组成,角闪辉长岩中的主要铁镁矿物为角闪石,它们为一套钙碱性弧岩浆岩组合,具有亏损的Sr-Nd-Hf同位素组成。始新世花岗质岩石主要为二长花岗岩-花岗闪长岩,它们较早侏罗世英云闪长岩更为富碱,属钙碱性-高钾钙碱性I型花岗岩,其同位素组成也较早侏罗世英云闪长岩富集。综合分析表明,该区早侏罗世复合辉长岩-花岗岩的形成受控于新特提斯洋板片北向俯冲的构造背景,角闪辉长岩起源于受俯冲板片脱水交代的上覆地幔楔的部分熔融,共生的英云闪长岩则为同期幔源岩浆底侵诱发初生地壳部分熔融产生的长英质岩浆与幔源岩浆不同程度混合的产物。始新世花岗岩的形成受控于新特提斯洋板片断离的构造背景,是由具"弧"型地球化学特征的初生地壳再造的产物,并有少量印度陆壳富集组分参与成岩。 相似文献
11.
北京燕山地区薛家石梁杂岩体特征、成因、源区性质及岩石圈减薄方式 总被引:14,自引:1,他引:14
薛家石梁杂岩体位于北京北山地区,在平面上呈北西向的椭圆状,主要由辉长岩、二长辉长岩、二长岩、正长岩和花岗岩组成。根据锆石SHRI MP定年结果为132·8~123·3Ma,形成于早白垩世早期。野外地质特征、矿物学特征、岩石学特征及地球化学特征表明,薛家石梁杂岩体中二长岩是二长辉长岩岩浆与正长岩岩浆混合作用的产物,从辉长岩岩浆到二长辉长岩岩浆经历了结晶分异作用。薛家石梁杂岩体中正长岩具高Sr,低Y及Eu正异常特征,推测其可能来源于加厚陆壳的底部。薛家石梁杂岩体中辉长岩中Mg#值为65,w(Nb)/w(U)值为37·8,这些特征暗示其可能为原生岩浆。辉长岩中ε(Nd)值为-6·5,表明其源区岩石不具亏损地幔特征;而辉长岩具富集Pb、Ti、Nb正异常,Hf的负异常,与EMI型富集地幔特征(具Nb、Hf正异常及Pb的负异常)不一致;辉长岩中Rb、Th、Nb、U、La、Ce元素含量比EMI型富集地幔低一个数量级;杂岩体中N(87Sr)/N(86Sr)与N(206Pb)/N(204Pb)值具正相关关系也表明不具交代富集型地幔特征。因此,我们认为辉长岩岩浆源区应为软流圈地幔,而不是富集型地幔(EMI)。辉长岩中ε(Nd)的负值是辉长岩岩浆与太古宙下地壳相互作用的结果。因此,我们认为中国东部岩石圈减薄的主要机制是岩石圈的拆沉作用。 相似文献
12.
西南天山二叠纪中酸性侵入岩的地质学和地球化学:岩石成因和构造背景 总被引:11,自引:3,他引:8
选择3个典型岩体,即位于西南天山东段的拜城县英买来岩体和位于西段阔克萨岭区的川乌鲁岩体、巴雷公岩体(为了对比,也选择了位于塔里木盆地西北缘的麻扎山岩体),进行了岩石学和地球化学研究。结果表明,这些岩体具有不同的特点。英买来岩体为黑云母花岗岩和二云母花岗岩,具有高的SiO2含量,弱过铝,高的Sr同位素初始值(约0.710)和负的εNd(t)值(-4~-6),属于S—A型之间的过渡类型。麻扎山岩体由正长岩组成,属于碱性岩,微量元素标准化图解和其他岩体明显不同的是没有明显的Nb和Ta的负异常。川乌鲁岩体是一个由3个不同期次岩石组成的杂岩体,主体为正长岩-二长岩,地球化学特征显示是由基性岩浆和酸性岩浆不同程度混合形成的。位于同一构造区的巴雷公岩体则与川乌鲁岩体中的花岗斑岩的地球化学特征相似。综合岩石学和地球化学特征推测,南天山东段的英买来岩体是地壳熔融的结果,没有任何地幔物质加入的地球化学信息,西段的阔克萨岭地区酸性岩浆的形成则可能是来自于幔源底侵的基性岩浆导致薄的地壳发生熔融的结果。麻扎山岩体则完全是不同构造背景的产物,有可能与发生在塔里木盆地的二叠纪大规模的岩浆活动有关。因此,二叠纪岩浆活动的性质主要受地壳成分和结构的控制。 相似文献
13.
The Middle Miocene Tsushima granite pluton is composed of leucocratic granites, gray granites and numerous mafic microgranular enclaves (MME). The granites have a metaluminous to slightly peraluminous composition and belong to the calc‐alkaline series, as do many other coeval granites of southwestern Japan, all of which formed in relation to the opening of the Sea of Japan. The Tsushima granites are unique in that they occur in the back‐arc area of the innermost Inner Zone of Southwest Japan, contain numerous miarolitic cavities, and show shallow crystallization (2–6 km deep), based on hornblende geobarometry. The leucocratic granite has higher initial 87Sr/86Sr ratios (0.7065–0.7085) and lower εNd(t) (?7.70 to ?4.35) than the MME of basaltic–dacitic composition (0.7044–0.7061 and ?0.53 to ?5.24), whereas most gray granites have intermediate chemical and Sr–Nd isotopic compositions (0.7061–0.7072 and ?3.75 to ?6.17). Field, petrological, and geochemical data demonstrate that the Tsushima granites formed by the mingling and mixing of mafic and felsic magmas. The Sr–Nd–Pb isotope data strongly suggest that the mafic magma was derived from two mantle components with depleted mantle material and enriched mantle I (EMI) compositions, whereas the felsic magma formed by mixing of upper mantle magma of EMI composition with metabasic rocks in the overlying lower crust. Element data points deviating from the simple mixing line of the two magmas may indicate fractional crystallization of the felsic magma or chemical modification by hydrothermal fluid. The miarolitic cavities and enrichment of alkali elements in the MME suggest rapid cooling of the mingled magma accompanied by elemental transport by hydrothermal fluid. The inferred genesis of this magma–fluid system is as follows: (i) the mafic and felsic magmas were generated in the mantle and lower crust, respectively, by a large heat supply and pressure decrease under back‐arc conditions induced by mantle upwelling and crustal thinning; (ii) they mingled and crystallized rapidly at shallow depths in the upper crust without interaction during the ascent of the magmas from the middle to the upper crust, which (iii) led to fluid generation in the shallow crust. The upper mantle in southwest Japan thus has an EMI‐like composition, which plays an important role in the genesis of igneous rocks there. 相似文献
14.
G. Suresh R. Ananthanarayana R. C. Hanumanthu Subhasish Ghosh A. Anil Kumar K. V. S. Reddy 《Journal of the Geological Society of India》2010,75(4):576-595
Geological studies on saturated to oversaturated and subsolvus aegirine-riebeckite syenite bodies of the Pulikonda alkaline
complex and Dancherla alkaline complex were carried out. The REE distribution of the Dancherla syenite shows a high fractionation
between LREE and HREE. The absence of Eu anomaly suggests source from garnet peridotite. The Pulikonda syenite shows moderate
fractionation between LREE and HREE as reflected by enrichment of HREE and moderate enrichment of LREE. The negative Eu anomaly
indicates role of plagioclase fractionation.Three distinct co-eval primary magmas i.e. mafic syenite-, felsic syenite- and
alkali basalt magmas — all derived from low-degrees of partial melting of mantle differentiates and enriched metasomatised
lower crust played a major role in the genesis and emplacement of the syenites into overlying crust along deep seated regional
scale trans-lithospheric strike-slip faults and shear zones following immediately after late-Archaean calc-alkaline arc magmatism
at different time-space episodes i.e. initially at craton margin and later on into the thickened interior of the Eastern Dharwar
craton. The ductile sheared and folded Pulikonda alkaline complex was evolved dominantly from the magmas derived from partial
melting of lower crust and minor juvenile magmas from mantle. Differentiation and fractionation by liquid immiscibility of
mafic magma and commingling-mixing of intermediate and felsic magmas followed by fractionational crystallisation under extensional
tectonics during waning stages of calc-alkaline arc magmatism nearer to the craton margin were attributed as the main processes
for the genesis of Pulikonda syenite complex. Commingling and limited mixing of independent mantle derived mafic and felsic
syenitic magmas and accompanying fractionation resulting into soda rich and potash rich syenite variants was tentatively deduced
mechanism for the origin of Dancherla, Danduvaripalle, Reddypalle syenites and other bodies belonging to Dancherla alkaline
complex at the craton interior. The Peddavaduguru syenite was formed by differentiation of alkali mafic magma (gabbro to diorite)
and it’s simultaneous mingling with fractionated felsic syenitic magma under incipient rift. Vannedoddi and Yeguvapalli syenites
were derived due to desilicification and accompanying alkali feldspar mestasomatism of younger potash rich granites along
Guntakal-Gooty fault and along Singanamala shear zone respectively. 相似文献
15.
十杭带湘南—桂北段中生代A型花岗岩带成岩成矿特征及成因讨论 总被引:41,自引:0,他引:41
十杭带是华南内陆一条重要的北北东向、具有高εNd (t )值和低t DM值的花岗岩带,该带在湘南—桂北段的花岗质岩体(千里山、骑田岭、西山、金鸡岭、花山和姑婆山等)均形成于151~163 Ma间。但从西南往东北方向,形成时代有逐渐变年轻的趋势。这些岩体在地球化学组成上显示出较为相似的特征,岩石均富碱、高钾,富含Rb,Th,U等大离子亲石元素(LILE)和REE,Nb,Ta,Zr,Hf等高场强元素(HFSE)。在地球化学图解上均落入A型花岗岩区域,因此该花岗岩带应属于一条A型花岗岩带。进一步划分,这些花岗岩应该属于A2亚类。这些花岗岩均具有较低的(87Sr/86Sr)i 值、较高的εNd (t )值和相对低的Nd模式年龄值,但从西南往东北方向,εNd (t )值具有逐渐降低的趋势。在这些花岗质岩体中暗色包体非常发育,岩石学和地球化学,特别是锆石的Hf同位素组成,指示这些花岗质岩石是通过壳-幔岩浆混合作用形成的,幔源岩浆端元来自亏损地幔,可能是软流圈地幔物质的直接参与。该A型花岗岩带可能形成于古太平洋板块俯冲引起的弧后或弧内拉张构造环境,软流圈地幔上涌及诱发的幔源岩浆沿超壳深断裂底侵,导致了强烈的壳幔岩浆混合作用,形成了该花岗岩带。该拉张事件从西南往东北方向进行,拉张强度由强变弱,混入花岗岩中的地幔物质也由多变少。该花岗岩带也是我国
一条重要的W-Sn多金属成矿带。研究表明,这些花岗岩均属于富Sn花岗岩,但Sn在这些花岗岩中的富集机制与传统的结晶分异富集的方式不同。该区锡矿化类型十分丰富,除了存在传统的岩浆热液演化成矿外,还存在新类型的绿泥石化花岗岩锡矿化,丰富了A型花岗岩的成矿理论。 相似文献
16.
粤西阳春中生代钾玄质侵入岩及其构造意义: 总被引:28,自引:0,他引:28
粤西阳春地区马山二长闪长岩强烈富集K、Sr和LREE,(87Sr/86Sr);≈0.7046,εNd(t)≈+1;岗尾-轮水岩体较富集K、Rb、Th和LREE,(87Sr/86Sr):≈0.7063,εNd(t)≈-2;石岩体较富集Sr,K、Rb、Th和LREE相对较低,(87Sr/86Sr);=0.7084~0.7089,εNd(t)≈-6。马山岩体来源于大离子亲石元素(ULE)和LREE富集的交代地幔;岗尾-轮水岩体来自于放射成因Sr、Nd同位素组成略高或交代时间略早的富集交代地幔,并且经历了明显的结晶分异作用;石岩体则很可能是前存下地壳底垫基性岩重熔形成的。从早侏罗世到早白垩世,南岭西部的岩浆成分和源区的规律性变化反映了区域软流圈地幔上涌和岩石圈伸展-拉张-减薄的演化过程。 相似文献
17.
双凤山基性侵入岩体位于松嫩-张广才岭地块南缘,其岩石组成主要为橄榄辉长岩.锆石LA-ICP-MS U-Pb定年显示该岩体形成于279±4 Ma.岩石矿物组成主要为橄榄石、单斜辉石、斜方辉石、高An值(80.1~87.9)斜长石以及以反应边形式存在的角闪石,矿物学特征指示其母岩浆为经历过充分流体交代的富水岩浆.全岩主微量元素组成揭示其源区物质组成为石榴子石二辉橄榄岩,部分熔融程度约20%,岩浆演化过程中经历了斜长石堆晶作用以及斜方辉石的结晶分异作用.全岩Sr-Nd同位素及锆石Hf同位素研究显示其(87Sr/86Sr)i=0.705 2~0.706 1,并具有正的εNd(t)值(0.9~1.3)和εHf(t)值(0~10.2),表明其来源于亏损的地幔源区,并且岩浆上升过程中没有经历明显的地壳混染.微量元素和同位素特征综合反映岩浆源区经历了古亚洲洋俯冲沉积物熔体和流体交代作用的改造,但起主导作用的是流体.其地球化学特征总体显示MORB以及弧型玄武岩过渡的特征,暗示其形成于弧后伸展环境.研究区基性侵入岩地幔源区的不均一性主要受到古亚洲洋多期次俯冲作用析出熔/流体对上覆地幔楔不同程度的改造. 相似文献
18.
《Chemie der Erde / Geochemistry》2021,81(4):125828
Based on the systematic elemental and isotope geochemical study on the Guojialing granite that is closely related to the gold mineralization in the Jiaodong ore-cluster region, further understandings have been made regarding its genetic mechanism, source material and gold mineralization conditions of the Guojialing granites. The (87Sr/86Sr)i values of Guojialing granite range from 0.7106 to 0.7120, and the εNd(t) from −18.1 to −13.2, respectively, which are similar to the initial SrNd isotopic compositions of those Late Jurassic-Early Cretaceous granites widely distributed in the Sulu orogenic belt, indicating similar sources of these intrusions in both Jiaodong and Su-Lu regions. The values of (206Pb/204Pb)i and(207Pb/204Pb)i of Guojialing granite are from 17.158–17.316, 15.453–15.478, respectively, indicating that the source of granites could be originated from mantle mixed with orogenic belt. The zircon Hf isotope of the Guojialing granite is decoupled from the Nd isotope of the whole rock, it has a zircon Hf model age(1979–3202 Ma) older than the full-rock Nd model age (1928 Ma). Compared to the full-rock Nd model age, the zircon Hf model age provides a more reliable age of crust-mantle differentiation and crust formation, suggesting that there is extensive crust deep-melting in the source area before the granitic magma activity, which was accompanied by strong Sm/Nd differentiation. Guojialing granite has similar characteristics to adakite, indicating that garnet is an important residual phase during magma formation. The formation of the Guojialing granite magma may be the partial melting of lithospheric mantle and thickened lower crust under eclogite facies, mixed with significant Neoarchaean crust or even Linglong granites when the magma upwelling. The Guojialing granite has high zircon Ce4+/Ce3+ ratios with the average values of 1151.7 and 811.4 respectively, indicating that the Guojialing granite was formed in a high oxygen fugacity environment, where sulfur is mainly present in the form of SO or SO2, which prevents the immiscibility of sulfides in the magma and avoids the removal of the sulfide metal elements. With crystallization differentiation, high oxygen fugitive magma will become a magma-hydrothermal fluid which is rich in sulfide metal elements, providing favorable material and environmental conditions for gold mineralization, thus favorably formed such giant gold deposit. 相似文献
19.
The East-Ujimqin complex, located north of the Erenhot–Hegenshan fault, North China, is composed of mafic–ultramafic and granitic rocks including peridotite, gabbro, alkali granite, and syenite. We investigated the tectonic setting, age, and anorogenic characteristics of the Xing’an–Mongolian Orogenic Belt (XMOB) through field investigation and microscopic and geochemical analyses of samples from the East-Ujimqin complex and LA-MC-ICP-MS zircon U–Pb dating of gabbro and alkali granite. Petrographic and geochemical studies of the complex indicate that this multiphase plutonic suite developed through a combination of fractional crystallization, assimilation processes, and magma mixing. The mafic–ultramafic rocks are alkaline and have within-plate geochemical characteristics, indicating anorogenic magmatism in an extensional setting and derivation from a mantle source. The mafic–ultramafic magmas triggered partial melting of the crust and generated the granitic rocks. The granitic rocks are alkali and metaluminous and have high Fe/(Fe + Mg) characteristics, all of which are common features of within-plate plutons. Zircon U–Pb geochronological dating of two samples of gabbro and alkali granite yielded ages of 280.8 ± 1.5 and 276.4 ± 0.7 Ma, placing them within the Early Permian. The zircon Hf isotopic data give inhomogeneous εHf(t) values of 8.2–14.7 for gabbroic zircons and extraordinary high εHf(t) values (8.9–12.5) for the alkali granite in magmatic zircons. Thus, we consider the East-Ujimqin mafic–ultramafic and granitic rocks to have been formed in an extensional tectonic setting caused by asthenospheric upwelling and lithospheric thinning. The sources of mafic–ultramafic and granitic rocks could be depleted garnet lherzolite mantle and juvenile continental lower crust, respectively. All the above indicate that an anorogenic magma event may have occurred in part of the XMOB during 280–276 Ma. 相似文献