海南岛二叠纪—三叠纪构造演化：源自岩浆岩和变质岩同位素年代学和地球化学的约束

本文对海南岛广泛出露的中-酸性花岗质岩体和中—高级变质岩开展了系统的岩石学、年代学、地球化学及Lu-Hf同位素研究,识别出270～259 Ma和242 Ma两期岩浆事件和251～248 Ma变质-深熔事件。270～259 Ma岩浆岩包括花岗(石英)闪长岩和含石榴子石花岗岩。花岗(石英)闪长岩为准铝质I型花岗岩,锆石ε_Hf(t)值变化较大,Mg^#和CaO/Na₂O比值较高,Rb/Sr比值较低,起源于玄武质下地壳,并存在少量幔源岩浆的混入;含石榴子石花岗岩为典型的强过铝质S型花岗岩,锆石ε_Hf(t)值为负,CaO/Na₂O比值较高,源岩主要为壳源贫黏土的碎屑岩。它们均富集LREEs(轻稀土元素)和LILEs(大离子亲石元素),明显亏损HFSEs(高场强元素),显示出与洋壳俯冲相关的岛弧岩浆岩的地球化学特征,形成于大陆弧背景下。251～248 Ma变质-深熔事件与区域上广泛分布的壳源S型花岗岩和韧性剪切变形同期,推测为一期弧-陆碰撞造山事件。242 Ma花岗岩为A₂     

Insights into the evolution of the Thomson Orogen from geochronology,geochemistry, and zircon isotopic studies of magmatic rocks

Abstract

Zircon U–Pb ages, εHf(t), and δ¹⁸O isotopic data together with geochemistry and limited Sm–Nd results from magmatic rocks sampled in deep-basement drill cores from undercover parts of the Thomson Orogen provide strong temporal links with outcropping regions of the orogen and important clues to its evolution and relationship with the Lachlan Orogen. SHRIMP U–Pb zircon ages show that magmatism of Early Ordovician age is widespread across the central, undercover regions of the Thomson Orogen and occurred in a narrow time-window between 480 and 470?Ma. These rocks have evolved εHf(t)_zrn (?12.18 to ?6.26) and εNd (?11.3 to ?7.1), and supracrustal δ¹⁸O_zrn (7.01–8.50‰), which is in stark contrast to Early Ordovician magmatic rocks in the Lachlan Orogen that are isotopically juvenile. Two samples have late Silurian ages (425–420?Ma), and four have Devonian ages (408–382?Ma). The late Silurian rocks have evolved εHf(t)_zrn (?6.42 to ?4.62) and supracrustal δ¹⁸O_zrn (9.26–10.29‰) values, while the younger Devonian rocks show a shift toward more juvenile εHf(t)_zrn, a trend that is also seen in rocks of this age in the Lachlan Orogen. Interestingly, two early Late Devonian samples have juvenile εHf(t)_zrn (0.01–1.92) but supracrustal δ¹⁸O_zrn (7.45–8.77‰) indicating rapid recycling of juvenile material. Two distinct Hf–O isotopic mixing trends are observed for magmatic rocks of the Thomson Orogen. One trend appears to have incorporated a more evolved supracrustal component and is defined by samples from the northern two-thirds of the Thomson Orogen, while the other trend is generally less evolved and from samples in the southern third of the Thomson Orogen and matches the isotopic character of rocks from the Lachlan Orogen. The spatial association of the Early Ordovician magmatism with the more evolved metasedimentary signature suggests that at least the northern part of the Thomson Orogen is underlain by older pre-Delamerian metasedimentary rocks.     

Palaeomagnetic data of late Cretaceous rocks from Sumba,Indonesia; the rotation of the Sumba continental fragment and its relation with eastern Sundaland

Sumba island forms part of a continental fragment, located near the transition of the Sunda Arc to the Banda Arc. It lies within the forearc region, between the active volcanic arc to the north and the Java Trench to the south. Palaeomagnetic studies of Cretaceous (late Albian-early Campanian) Lasipu sediments revealed a mean characteristic remanence (ChRM) direction with D = 42.5°, I = –23.0° and _{_95} = 6.1°, indicating a palaeolatitude of 12° S. This ChRM is, most likely, a secondary magnetization, possibly caused by the intrusion of the 65-Ma-old Tanadaro granodiorite. This granodiorite gave a mean ChRM direction with D = 44.7°, I = –16.3°, and ₉₅ = 12.2°, pointing to a palaeolatitude of 8.3° S. Eastern Sundaland with Borneo, west and south Sulawesi, and Sumba formed one continental unit in the late Mesozoic, most likely attached to the southeast Asian mainland. Borneo and west and south Sulawesi underwent large counterclockwise (CCW) rotations since the Jurassic with 45° during the Cretaceous, and 45° during the Palaeogene. The Sumba microcontinent, most likely, became detached from eastern Sundaland soon after deposition of the Lasipu sediments. Palaeomagnetic data show that Sumba underwent subsequent clockwise (CW) rotations of up to 96°: 53° between 82 and 65 Ma, and 38° between 65 and 37 Ma. Since the late Eocene, only small rotations occurred. The data indicate that eastern Sundaland, including Sumba, remained close to the equator since the Jurassic. CW rotations occurred in Sundaland both in the north (Indochina) and in the west (Sibumasu) as a consequence of the India – Eurasia collision. The same sense of rotation is seen further east in Sulawesis East Arm and the Philippine Sea plate. Eastern Sundaland (Borneo and west Sulawesi) with CCW rotations is being trapped between these CW rotating plates.     

Geochemistry and geochronology of the Proterozoic magmatic rocks of the Ulkan trough: New data

A model of the formation of the Ulkan trough was specified on the basis of new geochemical and geochronological data. The volcanics of the Ulkan Group exhibit geochemical features typical of the rocks of two modern geodynamic settings: suprasubduction and within-plate ones. The combination of the components derived from the different-depth sources in the magmatic chambers explains the formation of the volcanics with mixed geochemical signatures. The age of the granitoids of three phases of the Ulkan Massif is determined within the range of 1730–1925 Ga. The granites of the first and third phases have positive ɛNd(T) of + 3.5 and + 0.7, respectively. The granites of the first phase of the Ulkan Complex were likely derived from the Paleoproterozoic juvenile crust with an age of 1.84–1.95 Ga. The effusive rocks of the Ulkan Group were presumably formed in a geodynamic setting of a Cordilleran-type transform continental margin. Judging from the model T_Nd(DM) age, these geodynamic conditions operated >1.84 Ga ago.     

Zircon U–Pb geochronology and Hf isotope geochemistry of magmatic and metamorphic rocks from the Hida Belt,southwest Japan

Zircon U–Pb and Hf isotope data integrated in this study for magmatic and metamorphic rocks from the Hida Belt,southwest Japan,lead to a new understanding of the evolution of the Cordilleran arc system along the ancestral margins of present-day Northeast Asia.Ion microprobe data for magmatic zircon domains from eight mafic to intermediate orthogneisses in the Tateyama and Tsunogawa areas yielded weighted mean ~(206)Pb/~(238)U ages spanning the entire Permian period(302–254 Ma).Under cathodoluminescence,primary magmatic growth zones in the zircon crystals were observed to be partially or completely replaced by inward-penetrating,irregularly curved featureless or weakly zoned secondary domains that mostly yielded U–Pb ages of 250–240 Ma and relatively high Th/U ratios( 0.2).These secondary domains are considered to have been formed by solid-state recrystallization during thermal overprints associated with intrusions of Hida granitoids.Available whole-rock geochemical and Sr–Nd isotope data as well as zircon age spectra corroborate that the Hida Belt comprises the Paleozoic–Mesozoic Cordilleran arc system built upon the margin of the North China Craton,together with the Yeongnam Massif in southern Korea.The arc magmatism along this system was commenced in the Carboniferous and culminated in the Permian–Triassic transition period.Highly positive εHf(t) values( +12) of late Carboniferous to early Permian detrital zircons in the Hida paragneisses indicate that there was significant input from the depleted asthenospheric mantle and/or its crustal derivatives in the early stage of arc magmatism.On the other hand,near-chondritic εHf(t) values(+5 to-2) of magmatic zircons from late Permian Hida orthogneisses suggest a lithospheric mantle origin.Hf isotopic differences between magmatic zircon cores and the secondary rims observed in some orthogneiss samples clearly indicate that the zircons were chemically open to fluids or melts during thermal overprints.Resumed highly positive zircon εHf(t) values(+9) shared by Early Jurassic granitoids in the Hida Belt and Yeongnam Massif may reflect reworking of the Paleozoic arc crust.     

大别山北麓的奥陶纪岩浆弧：侵入岩年代学和地球化学证据

采用颗粒级锆石U-Pb和角闪石的~(40)Ar-~(39)Ar定年方法,测得大别山北坡马畈闪长质杂岩体中石英闪长岩的结晶锆石年龄分别为(463.5±3.4)和(458.6±6.7)Ma,角闪石~(40)Ar-~(39)Ar坪年龄为(462.7±1.4)Ma。从镁铁质包体到闪长岩和花岗岩类,ε_(Nd)(t)介于4.3～1.8之间,且随着Mg~#值的减小和SiO_2及Nb含量增高,岩石的ε_(Nd)(t)值降低,结合低Nb/Zr比值和中等-高的Ba/Th比值等特点,认为有关岩石的形成与幔源岩浆受板片流体影响并发生地壳AFC(同化混染与分离结晶同时出现)作用有关,但它们亏损Nb等高场强元素的特征,并不是地壳物质影响所致,而反映了地幔岩浆源区的特点,表明岩浆形成于与俯冲有关的环境。这一研究进一步证明,在大别山北麓的北淮阳地区,曾经发育了奥陶纪岩浆弧,向西与北秦岭岩浆弧相接。从大别山北麓的马畈杂岩体到昆仑山的布青山英云闪长岩体,中央造山带内与俯冲有关的侵入岩侵位年龄有向西变新的趋势,可能意味着原特提斯秦岭洋在向华北地块南缘活动大陆边缘俯冲过程中,是从东向西逐渐关闭的。     

西藏班戈地区侵入岩年代学和地球化学: 对班公湖-怒江洋盆演化时限的制约

详细的野外地质调查、室内锆石U-Pb年代学和岩石地球化学研究显示,班戈地区侵入岩可以分为4期:早白垩世早期石英闪长岩和英云闪长岩(138Ma±),早白垩世中期花岗闪长岩(132~128Ma),早白垩世中晚期二云二长花岗岩(130~114Ma),晚白垩世二长花岗岩(80Ma±),从北到南各期次侵入岩具有成岩年龄逐渐变新,形成环境由岛弧环境→同碰撞造山环境→后碰撞环境演变。这一成果为确定班公湖-怒江洋盆的俯冲极性及演化时限提供了新的资料。班戈地区班公湖-怒江洋盆在中侏罗世之前已开始向南俯冲消减,这种俯冲消减活动一直持续至早白垩世中期最终闭合(130~125Ma),拉萨地体与羌塘地体开始发生碰撞作用,这种碰撞作用大约持续了20~30Myr,在晚白垩世早期进入后碰撞阶段(100~80Ma)。     

内蒙古甲乌拉铅锌银矿区岩浆岩年代学、地球化学特征及其对成矿的约束

内蒙古满洲里地区的甲乌拉铅锌银矿区的成岩、成矿事件及其相互关系目前仍有很大争议。文中对矿区内与成矿密切相关的石英斑岩、闪长玢岩开展详细研究。锆石SHRIMP U Pb年代学研究表明：矿区致矿侵入体之一石英斑岩形成于(129±4.8) Ma,成矿晚(或后)期的闪长玢岩形成于约(124±2.5) Ma;认为铅锌银等成矿作用应发生于(129±4.8)~(124±2.5) Ma,为早白垩世末期。岩石地球化学特征显示石英斑岩具有高硅、高钾、贫钙等特征,TAS图上属于亚碱性系列,硅铁镁图上属于钙碱系列,硅钾图上属于高钾钙碱系列。轻重稀土分馏明显,具有明显的负铕异常。相对富集大离子亲石元素(LILE),而亏损高场强元素(HFSE),且具有低Sr、高Y等特征。闪长玢岩同样展现出高钾、高铝、贫钙特征,TAS图上属于亚碱性系列,硅铁镁图上属于拉斑系列;轻、重稀土分馏明显,具明显负铕异常,但稀土总量较高;相对富集大离子亲石元素(LILE),亏损高场强元素(HFSE),同具有低Sr、高Y等特征。这些研究结果表明：石英斑岩具有火山弧的特征,主要来源于壳源的熔融;闪长玢岩具有活动大陆边缘弧的特征,主要来源于地幔的熔融,但经历了壳源的混染上述岩浆与甲乌拉的铅锌银矿;推测应为蒙古-鄂霍次克洋由俯冲向陆陆转换阶段产物。     

狮泉河- 纳木错特提斯洋盆的俯冲极性：岛弧岩浆岩年代学和岩石地球化学证据

阿翁错- 盐湖复式岩体位于狮泉河- 纳木错蛇绿混杂岩带北缘，为狮泉河- 纳木错特提斯洋俯冲消减、碰撞造山过程中岩浆响应的重要组成部分，其研究对认识狮泉河- 纳木错特提斯洋盆的演化具有重要意义。本文以阿翁错- 盐湖复式岩体为研究对象，开展了系统的地质学、地球化学和锆石U- Pb年代学研究，总结了复式岩体的时空分布规律，探讨了复式岩体的成因类型、源区特征和构造背景。复式岩体主要由石英闪长（玢）岩、二长闪长岩、花岗闪长岩、黑云母正长花岗岩、（黑云母）二长花岗岩等组成，为一套岛弧岩浆岩组合，成岩年龄集中在120~104 Ma，属于早白垩世末期，空间分布上具从南到北，由早到晚的趋势。岩石地球化学特征显示从石英闪长岩到二长花岗岩具有由钙碱性系列岩石向钾玄岩系列演化的趋势，主体属于准铝质—弱过铝质I型花岗岩，轻稀土元素分馏程度较高，而重稀土近于平坦，具有弱的负铕异常；富集Rb、K等大离子亲石元素，Ta、Zr、Hf等高场强元素和轻稀土元素，相对亏损Nb、P、Ti等高场强元素和重稀土元素，具有岛弧岩浆岩的特征。基于本次研究结果，结合区域构造背景认为，阿翁错- 盐湖复式岩体形成于狮泉河- 纳木错特提斯洋盆北向俯冲的背景，来自俯冲板片的流体上升，引起上覆地幔楔物质发生部分熔融，形成幔源岩浆，在密度差的作用下幔源岩浆向上运移，底侵至新生下地壳，致其发生部分熔融，并与之发生混合作用，形成了阿翁错- 盐湖复式岩体的母源岩浆，早白垩世末期（104.8±1.4 Ma）狮泉河- 纳木错特提斯洋壳仍持续向北俯冲，下白垩统竟柱山组磨拉石建造的沉积才意味着洋盆彻底关闭。     

滇西剑川始新世富碱岩浆岩锆石U-Pb年代学与Sr-Nd-Hf同位素地球化学及其对岩石成因的制约

滇西剑川富碱岩浆岩位于青藏高原东南缘的三江南段,是金沙江-红河富碱岩浆岩带的重要组成部分。剑川富碱岩浆岩包括花岗岩和正长岩两类岩石,前者主要有花岗斑岩和石英二长斑岩,后者主要是正长斑岩和粗面岩。本文对剑川富碱岩浆岩进行了主微量元素、锆石U-Pb年代学和Sr-Nd-Hf同位素特征研究。锆石U-Pb测年结果显示,剑川花岗岩结晶年龄为35. 1～36. 1Ma,正长岩结晶年龄为35. 7～35. 8Ma,均形成于始新世。花岗斑岩和石英二长斑岩的SiO_2含量为67. 92%～69. 93%,K_2O/Na_2O比值介于0. 86～1. 22,具有高钾钙碱性特征;正长斑岩和粗面岩的SiO_2含量为53. 94%～63. 51%,K_2O/Na_2O比值介于1. 30～2. 68,属于钾玄质岩石系列。两类岩石都富集轻稀土元素(LREE)和大离子亲石元素(LILE),相对亏损高场强元素(HFSE)。其中,花岗斑岩和石英二长斑岩有着较高的Sr、Sr/Y、La/Yb值和低的Y、Yb含量,具有埃达克质岩浆属性。结合Sr-Nd-Hf同位素研究认为,滇西剑川地区花岗岩起源于增厚的镁铁质新生下地壳部分熔融,正长岩是由交代富集的岩石圈地幔熔融产生的基性岩浆演化而来的产物。滇西剑川新生代富碱岩浆活动是对印度与欧亚板块晚碰撞阶段,岩石圈地幔发生对流减薄和软流圈物质上涌过程的响应。     

Paleomagnetism and geochronology of volcanogenic-sedimentary rocks of Henrietta Island (De Long Archipelago,Arctic Ocean)

The paper presents results of geochronological and paleomagnetic studies of the volcanogenicsedimentary sequence of Henrietta Island in the East Siberian Sea. Our ⁴⁰Ar/³⁹Ar investigations confirm existing ideas that the bottom part of the section formed in the Ediacaran (~565 Ma) and that the basalts in the top of the section formed before the middle Cambrian (~520 Ma). Calculated paleomagnetic data confirm that during the rocks formation the territory of present-day Henrietta Island was located close to the 20° latitude, which lets us adjust some information published earlier on the age and natural remanent magnetization of the dolerite dikes of the nearby Jeannette Island. The new data also let us propose that a regional tectonothermal event, probably caused by accretion-related processes, took place at the beginning of the Ordovician.     

印尼某铁矿区岩浆岩与磁铁矿成因关系

通过对印尼某铁矿区岩浆岩与磁铁矿关系的研究,认为该区主花岗岩体是成矿物质的主要来源;接触交代型是矿区主要成矿类型;正长细晶岩是主花岗岩体成岩后期残余岩浆充分结晶分异的产物;正长细晶岩与花岗岩之间及其内部赋存的磁铁矿在成因上属接触交代型磁铁矿经后期残余气液充填交代叠加所形成.     

K—Ar Geochronology and Evolution of Cenozoic Volcanic Rocks in Eastrn China

Cenozoic volcanic rocks widespread in eastern China constitute an important part of the circum-Pacific volcanic belt.This paper presents more than 150K-Ar dates and a great deal of petrochemical analysis data from the Cenozoic volcanic rocks distributed in Tengchong,China‘s southeast coast,Shandong,Hebei,Nei Monggol and Northeast China.An integrated study shows that ubiquitous but uneven volcanic activities prevailed from the Eogene to the Holocene,characterized as being multi-eqisodic and multicycled.For example,in the Paleocene(67-58Ma),Eocene(57-37.5Ma),Miocene(22-18,16-19Ma),Pliocene(8-3Ma),and Early Pleistocene-Middle Pleistocene(1.2-0.5Ma) there were upsurges of volcanism,while in the Oligocene there was a repose period.In space,the older Eogene volcanic rocks are distributed within the region or in the central part of the NE-NNE-striking fault depression,while the younger Neogene and Quaternary volcanic rocks are distributed in the eastern and western parts.Petrologically,they belong essentially to tholeiite-series and alkali-series basalts,with alkalinity in the rocks increasing from old to youg.The above regularities are controlled by both global plate movement and regional inherent tectonic pattern.     

Petrology,geochemistry and U–Pb geochronology of magmatic rocks from the high-sulfidation epithermal Au–Cu Chelopech deposit,Srednogorie zone,Bulgaria

The Chelopech deposit is one of the largest European gold deposits and is located 60 km east of Sofia, within the northern part of the Panagyurishte mineral district. It lies within the Banat–Srednegorie metallogenic belt, which extends from Romania through Serbia to Bulgaria. The magmatic rocks define a typical calc-alkaline suite. The magmatic rocks surrounding the Chelopech deposit have been affected by propylitic, quartz–sericite, and advanced argillic alteration, but the igneous textures have been preserved. Alteration processes have resulted in leaching of Na₂O, CaO, P₂O₅, and Sr and enrichment in K₂O and Rb. Trace element variation diagrams are typical of subduction-related volcanism, with negative anomalies in high field strength elements (HFSE) and light element, lithophile elements. HFSE and rare earth elements were relatively immobile during the hydrothermal alteration related to ore formation. Based on immobile element classification diagrams, the magmatic rocks are andesitic to dacitic in compositions. Single zircon grains, from three different magmatic rocks spanning the time of the Chelopech magmatism, were dated by high-precision U–Pb geochronology. Zircons of an altered andesitic body, which has been thrust over the deposit, yield a concordant ²⁰⁶Pb/²³⁸U age of 92.21 ± 0.21 Ma. This age is interpreted as the crystallization age and the maximum age for magmatism at Chelopech. Zircon analyses of a dacitic dome-like body, which crops out to the north of the Chelopech deposit, give a mean ²⁰⁶Pb/²³⁸U age of 91.95 ± 0.28 Ma. Zircons of the andesitic hypabyssal body hosting the high-sulfidation mineralization and overprinted by hydrothermal alteration give a concordant ²⁰⁶Pb/²³⁸U age of 91.45 ± 0.15 Ma. This age is interpreted as the intrusion age of the andesite and as the maximum age of the Chelopech epithermal high-sulfidation deposit. ¹⁷⁶Hf/¹⁷⁷Hf isotope ratios of zircons from the Chelopech magmatic rocks, together with published data on the Chelopech area and the about 92-Ma-old Elatsite porphyry–Cu deposit, suggest two different magma sources in the Chelopech–Elatsite magmatic area. Magmatic rocks associated with the Elatsite porphyry–Cu deposit and the dacitic dome-like body north of Chelopech are characterized by zircons with ɛHf_T90 values of ∼5, which suggest an important input of mantle-derived magma. Some zircons display lower ɛHf_T90 values, as low as −6, and correlate with increasing ²⁰⁶Pb/²³⁸U ages up to about 350 Ma, suggesting assimilation of basement rocks during magmatism. In contrast, zircon grains in andesitic rocks from Chelopech are characterized by homogeneous ¹⁷⁶Hf/¹⁷⁷Hf isotope ratios with ɛHf_T90 values of ∼1 and suggest a homogeneous mixed crust–mantle magma source. We conclude that the Elatsite porphyry–Cu and the Chelopech high-sulfidation epithermal deposits were formed within a very short time span and could be partly contemporaneous. However, they are related to two distinct upper crustal magmatic reservoirs, and they cannot be considered as a genetically paired porphyry–Cu and high-sulfidation epithermal related to a single magmatic–hydrothermal system centered on the same intrusion.     

新疆阿舍勒盆地泥盆纪火成岩与构造-岩浆演化

阿舍勒泥盆纪火山盆地是阿尔泰西南缘重要的矿集区,产出我国著名的火山成因块状硫化物型(VMS)矿床——阿舍勒铜矿.其内部发育的火山岩和侵入岩地球化学特征记录了阿舍勒盆地的构造岩浆演化和成岩、成矿作用过程,但其形成构造背景和成岩成矿机制一直存在争论.本文报道了阿舍勒矿集区萨尔朔克铜金多金属矿区深部英云闪长岩的LA-MC-I...     

Age and evolution of scheelite-hosting rocks in the Felbertal deposit (Eastern Alps): U-Pb geochronology of zircon and titanite

U-Pb isotope analyses of zircon and titanite extracted from different rocks of the Felbertal scheelite deposit yield the following information: (1) An age of 593±22 Ma (2) is obtained for zircon crystallization in the scheelite-bearing matrix of an eruption breccia in the western ore field. (2) Discordant zircons from an elongated, up to 8 m thick scheelite-rich quartzite body in the eastern ore field give an upper intercept age of 544±5 Ma. This quartzite contains a laminated, fine-grained scheelite mineralization. (3) Zircons from a small granitoid intrusion of the western ore field reveal an age of 336±16 Ma, and concordant titanites document an age of 282±2 Ma for Variscan amphibolite facies metamorphism. Both events, granitoid intrusion and later metamorphism caused ore re-mobilization, including the formation of yellowish fluorescent (molybdo-) scheelite porphyroblasts. (4) For a narrow lamprop-1hyric dike in the western ore field, a concordant titanite age of 283±7 Ma is obtained. This age is identical with the titanites from the amphibolite facies metamorphic intrusion. Tiny scheelite grains were tapped by the dike from pre-existing scheelite mineralizations in the truncated host rocks. (5) Alpine metamorphism at 31±4 Ma did not exceed lowermost amphibolite facies conditions, and it caused scheelite re-mobilization on a minor scale only, producing bluish fluorescent porphyroblasts in quartz veinlets and veins, as well as bluish fluorescent scheelite rims around older scheelite grains. Moreover, crosscutting Alpine fissure fillings show bluish fluorescent, inclusion-free scheelite. (6) The preservation of Variscan titanites, the absence of Alpine titanite growth, and the large degree of Variscan scheelite re-mobilization demonstrate that amphibolite facies metamorphism in the Felbertal area has a Variscan age. This result clearly documents Variscan tectono-metamorphism to be the dominant event, instead of the hitherto surmised Alpine metamorphism. This multi-stage evolution of the Felbertal ore bodies corroborates the view that tungsten deposits are conditioned by several succeeding thermal events, leading to a series of stages that ultimately produce high-grade scheelite concentrations. These high-grade ores predominately occur along shear zones of different age, accompanied by the formation of large volumes of low-grade scheelite mineralizations along host rock foliations and quartz veinlets and veins.     

冀东孤山子基性-超基性岩体锆石U-Pb年代学、岩石地球化学特征

对孤山子基性-超基性岩体的岩相学、锆石U-Pb年代学和全岩地球化学等方面研究,确定了该岩体的形成时代、岩石成因及其形成的构造环境。该杂岩体主要由辉石岩和角闪辉石岩组成,元素地球化学上,贫SiO_2(34.28%~49.22%)、K_2ONa_2O、富MgO(4.54%~13.26%)特征,属碱性系列岩石。岩石稀土元素球粒陨石标准化配分模式为轻稀土富集型,(La/Yb)_N=8.14~36.19,Eu异常不明显,稀土元素原始地幔标准化分布模式相似,为上地幔富集地幔熔融。岩石富集大离子亲石元素(如Rb、Ba、K)和LREE(如La和Ce),明显亏损高场强元素(Nb、Ta、Ti)和HREE。样品Nb/U、Ce/Pb和La/Sm比值显示岩体经历了有限的地壳混染。锆石的LA-ICP-MS U-Pb年代学研究表明,岩石锆石U-Pb年龄分为3类:一类锆石U-Pb年龄为(1 392±10)Ma,应为孤山子超基性侵入体侵位过程中捕获的碎屑锆石;第二类锆石U-Pb年龄为(274.5±2.1)Ma,为岩浆侵位时形成的锆石;第三类锆石U-Pb年龄为(53.02±1.1)Ma,为热液锆石。研究认为,岩体的岩浆源区主要为亏损地幔,可能受晚古生代古亚洲洋俯冲洋壳的脱出流体迭加作用和地壳物质的混染。结合区域构造演化,认为岩体形成于古亚洲洋闭合后挤压向伸展转换的构造背景。     

新疆克拉玛依百口泉蛇绿混杂岩中辉长岩岩石学和地球化学研究

克拉玛依蛇绿混杂岩带百口泉剖面由尖晶石蛇纹岩、辉长岩、玄武岩和硅质岩组成。岩相学研究表明,百口泉辉长岩分为堆晶岩(具堆晶结构)和辉长岩(具辉长结构)两类,且均经历了低-中级变质改造。微量元素地球化学显示其岩浆起源于亏损地幔,强烈的Sr异常和Eu异常表明强烈的斜长石堆晶过程。根据其稀土配分模式推测其源区为尖晶石相的地幔橄榄岩。结合野外地质关系和地球化学特征,白碱滩尖晶石二辉橄榄岩能够代表其源区成分,利用微量元素模拟其岩浆演化过程显示:尖晶石二辉橄榄岩发生2.5%部分熔融所形成的熔体,通过10%～20%分离结晶可以形成堆晶辉长岩,经过80%～90%分离结晶则可以形成具辉长结构的辉长岩。因此,蛇绿混杂岩中零星分布的堆晶岩和辉长岩团块是同源岩浆演化的产物。对分离结晶过程中Nb元素地球化学行为的研究表明,岩浆的结晶分异能够导致辉长岩明显亏损Nb。