我国矽卡岩型铜矿床同位素地质特征及其“三位一体”成矿模式

总结了典型折矽卡岩型铜矿床同位素地质地球化学特征，认为我国矽卡岩型铜矿床成矿岩体（＾８７Ｓｒ／＾８６Ｓｒ）ｉ一般在０．７０６￣０．７１０变化，岩体为幔壳混合源型。矿石铅同位素组成均匀、稳定，特别是铀铅，＾２０６Ｐｂ／＾２０４Ｐｂ＝１７．０７５￣１８．１００，＾２０７Ｐｂ／＾２０４Ｐｂ＝１５．３３７￣１５．６３５，比值变化小，而＾２０８Ｐｂ／＾２０４Ｐｂ比值变化稍大，矿石铅源主要来自成矿岩体。矿石δ     

福建省花岗岩类Nd-Sr同位素特征及其意义

本文报道了福建省范围内前人分析数据稀疏或空白区域内的１８个古生代－中生代花岗岩体的Ｎｄ、Ｓｒ同位素组成：εＮｄ（ｔ）＝－３．６～－１６．４,（８７Ｓｒ／８６Ｓｒ）ｉ＝０．７０５５～０．７３１８,ｔＤＭ＝１．２～２．３Ｇａ。结合前人分析数据,区分出三个地域区带：福安－南靖断裂以东的沿海带：εＮｄ（ｔ）＝－１．５～－６．８,（８７Ｓｒ／８６Ｓｒ）ｉ＝０．７０５６～０．７０９９,ｔＤＭ＝１．１～１．４５Ｇａ,弧后伸展构造背景下的幔－壳岩浆混合是该带花岗岩的主要成岩方式;福安－南靖断裂以西的内陆区域：εＮｄ（ｔ）＝－４．０～－１６．４,（８７Ｓｒ／８６Ｓｒ）ｉ＝０．７０６４～０．７４１０,ｔＤＭ＝１．３～２．３,其中加里东－印支期花岗岩主要由与麻源群相当之地壳物质部分熔融形成,而燕山期花岗岩,一部分由与麻源群相当或较年轻的地壳物质部分熔融产生,也有一部分可能由壳－幔岩浆混合形成;福建省南部的纬向带：εＮｄ（ｔ）＝－３．６～－７．５,（８７Ｓｒ／８６Ｓｒ）ｉ＝０．７０５５～０．７０９９,ｔＤＭ＝１．２～１．５５,同位素特征与沿海带相似,但该带构造拉张发育时间较沿海带略早     

西天山琼阿乌孜超基性岩体的稀土元素和Sr,Nd同位素研究

对西天山琼阿乌孜超基性岩体和围岩片麻岩作了Ｓｍ、Ｎｄ、Ｒｂ、Ｓｒ同位素和稀土元素的研究，获得岩体的形成年龄为３１４±１９Ｍａ，∑ＲＥＥ约为４．０～７．６μｇ／ｇ。其主体岩石是由来源于未亏损地幔较高程度熔融而产生的岩浆在结晶分异作用中形成。其岩体的边缘［εＮｄ＝－５，（８７Ｓｒ／８６Ｓｒ）＝０．７０５５，∑ＲＥＥ＝１１１．５６μｇ／ｇ］同化了围岩［εＮｄ＝－１６．７，（８７Ｓｒ／８６Ｓｒ）ｉ＝０．７５３７，∑ＲＥＥ＝１９６μｇ／ｇ］，并同时发生结晶作用，经历了ＡＦＣ过程，形成了特有的琼阿鸟孜超基性岩侵入体。     

陕南铁船山岩体的地球化学特征、成因及其形成的构造环境

扬子克拉通北缘的铁船山岩体形成于新元古代，其岩石类型为霓石－钠铁门石花岗岩，岩石富碱质、Ｓｔ、Ｆｅ、ＲＥＥ和高场强元素，而贫Ａｌ、Ｃａ、Ｍｇ、Ｓｒ、Ｂａ、Ｃｏ、Ｎｉ等组分，δＥｕ＝０．２０，Ａ／ＫＮＣ＝０．８５，Ｋ２Ｏ＋Ｎａ２Ｏ／Ａｌ２Ｏ３＝１．０９，Ａ·Ｒ＝９．２８，岩石属典型的Ａ型花岗岩，Ｎｄ、Ｓｒ和Ｏ同位素示踪反映其成岩物质来自于壳幔混合源区。根据区域地质背景的综合分析，岩体形成于活动陆缘的张裂构造环境，属活动板块边缘拉张型花岗岩。     

武当地块基性岩墙群及耀岭河群基性火山岩的Sr,Nd,Pb,O同位素研究

武当地块基性岩墙群与耀岭河群基性火山岩的Ｓｒ、Ｎｄ、Ｐｂ同位素特征反映它们具相同的混合地幔源区。前者的（＾８７Ｓｒ／＾８６Ｓｒ）ｉ＝０．６９０５￣０．７０６１,εＮｄ（ｔ）＝－１．９￣５．０,Δ＾２０８Ｐｂ／＾２０４Ｐｂ＝３５．４９￣１９０．２６,Δ＾２０７Ｐｂ／＾２０４Ｐｂ＝４￣８５,Ｔｈ／Ｔａ低,Ｌａ／Ｙｂ变化大;后者的（＾８７Ｓｒ／＾８６Ｓｒ）ｉ＝０．６４８７￣０．７０７５,εＮｄ（ｔ）＝０     

广东阳春盆地花岗岩类同位素,微量元素地球化学研究

对阳春盆地３个花岗岩类岩体进行了年龄测定,岗尾岩体和锡山岩体的黑云母Ｋ－Ａｒ稀释法年龄平均值分别为１５６×１０＾６和７６×１０＾６ａ,石录岩体花岗闪长岩中黑云母,钾长石和斜长石等单矿物＾４０Ａｒ／＾３９Ａｒ坪年龄平均值为１００×１０＾６ａ,马山岩体,岗尾央体和石录岩体的锶同位素初始比值分别为０．７０４０,０．７０６４和０．７０８９,它们均属于壳幔混合型花岗岩类,根据微量元素判别,锡山岩体花岗岩是壳     

祁连山金佛寺岩体的岩石学和同位素年代学研究

金佛寺岩体位于北祁连山区山前断裂南侧，属加里东晚期侵入体。由金佛寺花岗闪长岩－石英二长岩、大草滩二长花岗岩及干巴口二云母花岗岩３个侵入阶段的岩体组成。前两阶段岩体的全岩Ｒｂ－Ｓｒ等时线年龄分别为４１９．８７±０．４Ｍａ和４０３．７±０．０８Ｍａ。表明其侵位时代为志留纪中晚期。岩体定位以后经历了３次抬升和两次沉降。     

郭家岭花闪长岩岩体中闪长质包体的成因研究

郭家岭花岗闪长岩是胶东金矿区的重要岩体，Ｒｂ－Ｓｒ全岩等时线年龄为２００．６Ｍａ，岩体中常见一种闪长质包体，这些包体具有淬火结构，变余斑状结构及索列特扩散分带，表明它们是由来自地幔的高温玄武质岩快速冷凝结晶形成的。     

郭家岭型花岗岩地球化学特征与金矿化的关系

根据郭家岭花岗岩与成矿后岩脉的锆石ＳＨＲＩＭＰＵ－Ｐｂ年龄，金矿化被限定在１２６Ｍａ～１２０Ｍａ之间，结合岩体与金矿化密切的空间关系和岩石地球化学上的亲缘关系，认为招掖地区金矿化主要与郭家岭花岗岩有关，岩体高Ｎａ和Ｂａ，Ｓｒ是太古宙绿色岩区与金矿化有关花岗岩的一个明显的地球化学标志。     

广州萝岗花岗岩类的地质地球化学特征

形成于三叠纪的萝岗花岗岩类岩石由石英闪长岩、花岗闪长岩、二长花岗岩和花岗岩组成,岩石化学和微量元素特征表明其属“Ⅰ”型花岗岩类;但δ＾１８Ｏ（‰）值为＋９．７１￣＋１０．９,ＩＳｒ为０．７１１１,又属高δ＾１８Ｏ花岗岩类和中等锶花岗岩范围。Ｎｄ同位素示踪研究表明,其成岩物质极可能源自古老的华夏古陆基底;ＳｉＯ２－Ｋ２Ｏ图解和副矿物组合特征说明,萝岗花岗岩类属深源岩浆侵入形成。结合区域研究资料初步认     

Geochemical studies of Sr-Nd-Pb-Hf isotopes on the Guojialing granite suite: Implications to region Au mineralization in the Jiaodong ore-cluster region

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.     

栖霞牙山花岗岩及其暗色包体地球化学特征及成因研究

栖霞牙山花岗岩体形成于中生代早白垩世（118 Ma）,其岩石类型以花岗岩和花岗闪长岩为主,岩体中发育大量的暗色闪长质微粒包体。通过对牙山花岗岩及其暗色包体地球化学特征研究表明,包体围岩w（SiO₂）=65.5%~68.82%,铝饱和度（A/CNK）为0.89~1.03<1.1,为准铝质钙碱性Ⅰ型花岗岩;暗色包体具有较低w（SiO₂）值（54.82%~60.89%）、高w（TFe₂O₃）值（6.11%~8.15%）、高w（MgO）值（3.57%~5.19%）的特征。稀土元素配分模式图显示二者皆为轻稀土富集的右倾型曲线,微量元素蛛网图中二者均表现为富集Ba、K等大离子亲石元素,亏损Ta、Nb、Ti等高场强元素,具有大陆地壳的特征。暗色包体与寄主岩石的Sr同位素初始比值（⁸⁷Sr/⁸⁶Sr）_i分别为0.709 29~0.709 58和0.709 21~0.709 71,应为同源岩浆的产物。两阶段Nd模式年龄（T_2DM）分为2 291 Ma-2 391 Ma和2 208 Ma-2 353 Ma,表明可能是古元古界陆壳物质部分熔融的产物。Pb同位素特征显示牙山岩体的原始岩浆以下地壳为主,w（Nb）/w（Ta）值介于下地壳与原始地幔之间,表明可能受到幔源物质的影响,包体中大量磷灰石呈针状结晶状态,进一步暗示存在岩浆混合作用。综上并结合区域构造背景认为,牙山岩体为早白垩世中晚期起源于火山弧环境的壳源特征花岗岩,形成过程中存在幔源物质的加入,它的形成与太平洋板块的俯冲作用密切相关。     

The genesis of Variscan (Hercynian) plutonic rocks: Inferences from Sr,Pb, and O studies on the Maladeta igneous complex,central Pyrenees (Spain)

The Maladeta plutonic complex formed during the latest stages of the Variscan orogeny. It was emplaced into the Paleozoic sedimentary sequence of the Pyrenees. The eastern part, investigated in the present study, consists of an early intrusion of cumulate gabbronorites followed in order of emplacement by the main biotite-hornblende granodiorite, which was itself intruded by two small stocks of two-mica cordierite granite. An ⁸⁷Rb-⁸⁷Sr isochron dates the granodiorite at 277±7 m.y. with an initial (⁸⁷Sr/⁸⁶Sr)_o ratio of 0.7117±3. Gabbroic rocks have lower strontium initial ratios, down to 0.7092, while those of granite range from that of the granodiorite up to about 0.715. The three rock types have distinctive ¹⁸O values: 8.7 to 9.6 for the gabbronorites, 9.4 to 10.4 for the granodiorites and 10.3 to 11.8 for the granites. Lead isotopic compositions of rocks and feldspars are all radiogenic. Feldspars give consistent Pb model ages around 280 m.y., with and values of about 9.7 and 4.05, respectively. No pristine, mantle-derived magma was found among the investigated samples and the rocks cannot be related to one another by any simple mechanism of fractional crystallization. Some type of mixing process involving two end members seems to be required: a high-¹⁸O, high-⁸⁷Sr material that is clearly of crustal origin, and a lower-¹⁸O, lower-⁸⁷Sr end member derived from the mantle. Examination of various mixing models does not support magma mixing nor assimilation of crustal rocks by a mafic magma. The most acceptable model involves melting at different levels of a vertically-zoned source in the continental crust; this source was formed by mixing between mantle-derived magmas and crustal metasediments. This material was apparently thickened, tectonically downwarped and partially melted. None of the Maladeta magma-types appear to have been derived at a consuming plate boundary.Contribution Number 3280, Division of Geological and Planetary Sciences, California Institute of Technology, Pasadena, CA 91125, USA     

Pb, Sr and Nd isotope study of two co-existing magmas in the Nízke Tatry Mountains, Western Carpathians (Slovakia)

Summary Two co-existing plutonic rocks (diorite and granodiorite) were studied from an intrusion of Variscan age in the Raztocna Valley – Nízke Tatry Mountains, Western Carpathians. Geochemical analyses of major and trace elements constrain a volcanic arc as emplacement environment and give the first hints of a mixture of two magmatic end-members: the so-called Prasivá granodiorite and the Raztocna diorite. The ⁸⁷Sr/⁸⁶Sr₍₀₎ ratios vary between 0.7075 and 0.7118, the ε Nd₍₀₎ values range from −1.4 to −5.0. Common Pb isotopes reveal a dominant crustal source with minor influences from a mantle and a lower crustal source. Modelling based on Sr and Nd isotope data and using three component mixing calculations indicates that mixing of 2/3 of upper mantle material with 1/3 upper crustal material can produce the isotopic composition of the Raztocna diorite. Very minor amounts of lower crust were incorporated in the diorite. For the Prasivá granodiorite, the mixing ratio of upper mantle and upper crust is similar, but a lower crustal reservoir contributed about 5–10% of the source material.     

Genesis and Mixing/Mingling of Mafic and Felsic Magmas of Back-Arc Granite: Miocene Tsushima Pluton, Southwest Japan

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 ε_Nd(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.     

广西花山花岗岩的岩石学和地球化学特征及成岩物质来源的探讨

本文研究了花山花岗岩的岩石学、地球化学和同位素地质学特征,确定了花山岩体是一个由三期独立的、不同时代、不同成因和不同物质来源的花岗质岩浆岩所组成的复式岩体。第一期印支期牛庙石英二长岩和同安石英二长岩,属以幔源物质为主的壳幔混合来源,由上地幔分异岩浆上侵并同化混染了地壳物质而形成;第二期燕山早期花山主体花岗岩亦属壳幔混合来源,但其壳幔物质比值有所增高。上地幔沿东西向区域性深断裂的上拱和地壳物质(包括沉积组分和火成组分)受热重熔,是该期花岗岩的可能成因;第三期燕山晚期细粒花岗岩小岩体是由以沉积组分为主的地壳物质经部分熔融、重熔或深熔而成。     

研究花岗岩类成因类型和幔壳成分比的同位素方法探讨

Sm-Nd法及其参数εNd（O）、εNd（T）、TCHUR^Nd、εDM^Nd及x,是测定花岗岩形成年龄及研究花岗岩成因类型、模式年龄及地幔物质百分比的重要手段,但因其测试费用高等原因,难以广泛使用。作者提出了Rb-Sm法的相应参数εSr（O）、εSr（T）、TUR^Sr、εDM^Sr及μ做为补充,在没有Sm-Nd同位素资料的情况下,Rb-Sr同位素参数基本上可以代替Sm-Nd同位素参数。经对比,求花岗岩中幔源物质百分比时,Rb-Sr法计算值与Sm-Nd法计算值相比,误差一般不超过10％。此外,作者还提出了计算花岗岩山幔源物质百分比的简化式,使该计算更为简便易行。     

The age of young intrusions of Tsana Complex (Greater Caucasus) and isotope-geochemical evidence for their origin from hybrid magmas

This paper presents isotope-geochronological and petrological study of granitoids of the potentially ore-bearing (Au–As–Sb–Sn–Mo) Early Pliocene Tsana Complex, which are confined to the Main Caucasus fault zone (upthrow fault) in the central part of the Greater Caucasus Range. The Tsurungal and Karobi groups of magmatic bodies are distinguished based on spatial criterion. The Tsurungal group includes three small granite—granodiorite massifs (Tsurungal, Chorokhi, and Toteldash) and numerous acid and intermediate dikes in the upper reaches of the Tskhenistsqali River (Kvemo Svaneti, Georgia). The Karobi group comprises three subvolcanic rhyodacite bodies located in the upper reaches of the Chashuri River (Zemo Racha, Georgia) and numerous N–S-trending trachyandesite dikes near the axial zone of the Main Caucasus Range. The K-Ar and Rb-Sr isotope dating shows that the granitoid massifs and dike bodies of the Tsana Complex were formed in two different-age pulses of the Pliocene magmatism: phase I at 4.80 ± 0.15 and phase II at 4.15 ± 0.10 Ma. All hypabyssal rocks of the Karobi group, unlike those of the Tsurungal Group, were formed during the first pulse. Petrographic studies in combination with geochemical data indicate that most of the granitoids of the Tsana Complex are hybrid rocks (I-type post-collisional granites) and were derived through mixing of deep-seated mantle magmas with acid melts obtained by the upper crustal anatectic melting in the Main Caucasus fault zone. The granitoids of the Tsurungal Group define basic to acid evolution (diorite–granodiorite–granite–two-mica granite) possibly caused by both crystallization differentiation and increasing role of crustal contamination in the petrogenesis of the parental magmas of these rocks. This conclusion is also confirmed by the differences in the Sr isotope composition between granitoids of the early (⁸⁷Sr/⁸⁶Sr = 0.7053) and late (⁸⁷Sr/⁸⁶Sr = 0.7071) phases of the Tsana Complex. Main trends in spatiotemporal migration of magmatic activity in the central part of the Greater Caucasus in the Pliocene–Quaternary time were established using obtained and earlier published isotope-geochronological data.     

Age,origin and evolution of the anorogenic complex of Evisa (Corsica): A K-Li-Rb-Sr study

The anorogenic complex of Evisa (Corsica) is made up of riebeckite hypersolvus granite and of albite-riebeckite-aegirine granite. Ten samples from the southern part of the complex provided Rb-Sr whole-rock isochrons for each facies. The ages of the two granites are indistinguishable at 246±7m.yr. corresponding to the Upper Permian. ⁸⁷Sr/⁸⁶Sr initial ratio (0.7034±0.0011) is in the mantle range of values and precludes any important crustal contamination. Li and Rb contents are controlled by the peralkaline fluid phase, reflected by deuteric changes. These alterations are weak in the hypersolvus facies but are obvious in the albite facies: replacement of preexisting perthite by albite, late precipitations of aegirine and fluorite, associated weak mineralization. The low value of ⁸⁷Sr/⁸⁶Sr initial ratio and the similarity of this ratio for both facies indicate that the fluid phase interacted with the crystallized rocks soon after the emplacement of the complex and provoked autometamorphic reactions without important external supplies.     

The mixing of Mesozoic crust-mantle magma is the key to the source of large amounts of gold deposits in the Jiaobei uplift,ChinaSCIEI北大核心CSCD

胶东地区金矿巨量金质来源一直是学界争论的焦点,很难找到有说服力的直接证据。在没有其它更有效的直接证明巨量金质来源的情况下,本文通过胶北隆起主要地质体新鲜岩石大量微量元素地球化学数据的变化规律,间接得出中生代壳幔岩浆的混合反应是巨量金质来源的关键,即郭家岭和伟德山两期壳幔岩浆的混合反应和演化可能是巨量金质来源的主要形成机制,同时更是热量供给源,而玲珑花岗岩可能是少量金质的提供者和主要赋矿地质体。胶东地区金矿主要成矿时间(130～105Ma)与郭家岭(130～125Ma)和伟德山(126～108Ma)两期花岗岩浆演化结晶时间完全吻合,说明其关系密切,岩浆混合反应和冷凝期,岩浆热液上升运移沉淀成矿。该区中生代地质体对早前寒武纪的地球化学环境有一定的继承性,中生代地壳混合了大量地幔物质,Au丰度偏高,平均为1.31×10^-9,为地球化学高背景场。