内蒙古中部构造混杂带晚古生代-早中生代变质基性岩的地球化学特征及其大地构造意义

内蒙古中部构造混杂带中的变质基性岩可分为南、北两带:南带位于乌兰沟-图林凯地区,被划分至温都尔庙群下部的桑达来因组,主要为一套变质玄武岩和辉长岩、辉绿岩,局部含有超基性岩和碳酸岩透镜体,其中变质基性火山岩以绿片岩相变质为主,局部保留枕状构造或发育蓝片岩,已有的锆石U-Pb年代学数据表明南带变质基性火山岩形成于晚古生代到早中生代;北带位于芒和特-二道井-红格尔一线,主要呈岩块状保存在由绢云绿泥石英片岩、硅质岩、含铁石英岩和少量的大理岩组成的基质中,岩石类型包括蓝片岩、冻蓝闪石片岩、阳起片岩、绿帘角闪片岩等。地球化学研究显示南、北两带的变质基性岩相对低Al(Al2O3=10.66%~14.97%)、低Ti(TiO2=1.27%~1.96%)、高Na(Na2O=1.02%~4.20%)、贫K(K2O=0.02%~0.71%),具有拉斑玄武岩到碱性玄武岩系列的过渡特征,高的Na2O/K2O比值(6.89~454)暗示这些基性岩在变质作用前发生了细碧角斑岩化。不活动元素Zr与其他高场强元素(HSFE;Th、Nb、Hf、Ti)和稀土元素(REE)显示良好的线性关系,表明在变质过程中,高场强元素和稀土元素基本保持稳定,可以反映原岩的性质。根据稀土、微量元素配分型式和相关比值可以将内蒙中部构造混杂带中的变质基性岩分为两类:一类稀土含量相对较低(∑REE=46.00×10-6~78.08×10-6)、轻重稀土分异不明显((La/Yb)N=0.50~1.04),无明显Eu负异常,Hf/Ta=6.82~15.18,具有正常的大洋中脊玄武岩(NMORB)特征;另一类稀土含量相对较高(∑REE=58.66×10-6~151.3×10-6)、轻重稀土分异明显((La/Yb)N=2.28~4.68),无明显Eu负异常,Hf/Ta=2.06~4.70,与富集型洋中脊玄武岩(E-MORB)相似。部分变质基性岩样品轻微富集大离子亲石元素Rb和Ba,可能暗示原岩在就位过程中遭受了微弱的陆壳混染。以上地球化学特征表明这些变质基性岩的原岩可能形成于一个扩张规模有限的陆内洋盆环境。已有的古生物地理学研究表明古亚洲洋闭合后,到晚古生代早期,内蒙古中部地区成为佳-蒙地块的一部分。石炭纪期间整个内蒙古中部发育稳定的浅海相沉积,局部为造山后隆起环境,发育加里东I型花岗岩和花岗闪长岩。从晚石炭世-早二叠世起,内蒙中部开始处于伸展环境:二连浩特到东乌珠穆沁旗一带发育大量的碱性岩;华北克拉通北缘发育很多高钾钙碱性-碱性的花岗岩;内蒙中部地区广泛发育二叠纪大石寨组双峰式火山岩。到中二叠世开始裂解形成若干近东西向分布的海盆,发育哲斯组、林西组浅海相、泻湖相沉积。持续的伸展形成了有限洋盆,发育以温都尔庙群为代表的含铁硅质岩以及晚古生代-早中生代基性岩。由于早中三叠世华北板块与扬子板块全面碰撞和陆内造山过程的影响,有限洋盆最终在早中生代之后发生被动闭合,形成南、北构造混杂带,并导致该基性岩乃至整个内蒙中部的晚古生代沉积发生广泛绿片岩相变质作用,而局部蓝片岩的形成可能与有限洋盆的俯冲作用有关。     

东昆仑那陵格勒河南上三叠统鄂拉山组火山岩地球化学特征及构造环境

东昆仑那陵格勒河南地区发育上三叠统鄂拉山组(T_3e)火山岩,岩石类型主要以英安质玻屑晶屑凝灰岩和英安质熔结凝灰岩为主,具有高碱、高钾、高铝的特征;岩石的二氧化硅含量w(SiO_2)=69.12%~74.52%,全碱含量w(Na_2O+K_2O)=6.42%~7.33%,里特曼指数σ=1.39~2.01,岩石的铝过饱和指数ASI介于1.02~1.17之间,属典型的过铝质高钾钙碱性系列。岩石的稀土元素w(LREE)/w(HREE)=11.02~15.99,δEu=0.54~0.67,铕具中等亏损,属轻稀土富集型;微量元素K、Rb、Ba和Th较强的富集,Sr、Ti、Sc、Cr明显亏损,具有后碰撞下地壳重熔产物的特征。在鄂拉山组玄武质晶屑凝灰熔岩中获U-Pb同位素年龄值为231 Ma±1 Ma,形成时代为晚三叠世。通过综合分析认为,鄂拉山组火山岩可能形成于以侧向挤压为主的陆—陆后碰撞过程中加厚地壳物质部分熔融的产物,属于印支期后碰撞火山盆地岩石建造。     

http://www.sciencedirect.com/science/article/pii/S1674987112000072

The Abor volcanics outcroping in the core of the Siang window in the Eastern Himalaya comprise voluminous mafic volcanics (47％-56％ w(SiO2)),with subordinate felsic volcanics (67％-75％ w(SiO2)).The felsi...     

安徽大别山腹地中生代火山岩的发现及其地质意义

近期作者等在大别山腹地开展１∶５万区调过程时,于中深变质岩中发现一套中生代火山岩系;主要岩石类型为石英安山质晶屑凝灰熔岩、火山角砾岩及凝灰岩。通过详细观察、追索,其中查明火山岩系的空间分布及其与围岩的接触关系。对认识大别山的构造演化及热隆—顶蚀作用、超高压变质带的形成、折返机制等提供新的依据。     

Palaeomagnetism of the Permian Volcanic Rocks of Moissey (French Jura): Implications For the Palaeofield and Tectonic Evolution

Rocks from the Massif de la Serre in the French Jura (latitude: 47.3°N longitude: 5.6°E) belonging to an ignimbritic assemblage dominated by vitrophyric rhyolites, and whose age of formation is probably Permian (Autunian to Saxonian) have been studied by applying thermal and alternating field demagnetization. the characteristic magnetization has a mean direction derived from 89 samples of D= 170°, I = - 16°, k = 26.2°, α₉₅= 3° and a corresponding north palaeopole at 41°N, 172°E, A ₉₅= 5°. the pole, which is very close to the Permian European poles, can thus be considered as a new contribution. Some samples are found to carry a unique normal polarity magnetization, others carry both normal and reverse polarities. It therefore seems that, similar to Permian series in the USSR, these west European rocks have registered a normal event in the Kiaman interval. From a structural point of view, we may conclude that during the Alpine tectonic phases the Massif de la Serre has not been subjected to substantial rotation.     

新命名地层单位──三塘湖组

经首次全国地层多重划分对比研究，在东准噶尔地层小区建议使用新命名地层单位──三塘湖组，用以代表一套以陆相中酸性火山熔岩及火山碎屑岩为主的火山岩系（局部有基性火山岩）．时限大致为早二叠世．文中介绍了三塘湖组的定义、划分沿革。层型剖面及分布变化。     

华北板块南缘熊耳群火山岩研究的若干问题

本文基于大量的区域地质学，岩石学和地球化学资料，陈述熊耳群的一些重要资料，阐明作用者对一些争议问题的看法，同时指出今后值得注意的一些研究内容。研究表明，熊耳群火山岩以橄榄玄粗岩，安粗岩和粗面英安岩，流纹岩为主，其次为高钾玄武安山岩，高钾安山岩，高钾英安岩；火山岩系列主要为橄榄玄粗岩系，其次为高钾钙碱性岩系；熊耳群是扩张应力背景的产物，但火山岩的地球化学特征表明，能耳期或熊耳期以前的陆下岩石圈地幔历     

Subsurface structure of the volcanic centre of the České Středohoří Mountains, North Bohemia, determined by geophysical surveys

Former geophysical surveys performed in the region of the volcanic centre of the České Stř edohoří Mts. in North Bohemia (the Ohře Rift zone) showed that anomalous volcanic bodies and features can be effectively identified within sedimentary environment. For this reason we carried out new geophysical measurements in the area of the main mafic intrusion of essexitic character. The target was the exact location and geometry of the intrusion and its relation to other components of the volcanic centre. We used gravity, magnetic, shallow seismic and electromagnetic techniques. The new gravity and magnetic data were tied to the old databases so that we could investigate the area as a whole complex. Electromagnetic measurements were applied in the area of the expected extent of the intrusion, and the seismic measurements in the central part of the intrusion. Based on all the data, mainly on gravity modelling, we delineated not only the surface and subsurface extent of the intrusion, but we also defined the hidden relief of the intrusion. It was found that the intrusion is formed by a single body that has a few protrusions, and not by a set of separate individual intrusions, as indicated by surface outcrops. However, the body of the intrusion is affected by a major fault that caused lithological differences on both sides (essexite/monzodiorite). In detail we show the depth of the debris cover and the thickness of the weathered zone in the central part of the essexite body. We also derived indications of tectonic elements in the area of the intrusion in the main structural/tectonic direction in the region. The results will be utilized to establish a 3D geological model of the whole volcanic centre. This investigation may serve as an example of non-seismic geophysical exploration applied to the study of volcanic centres surrounded by sedimentary rocks.     

Upper Cretaceous Magmatic Series and Associated Mineralisation in the Carpathian – Balkan Orogen

Abstract: The Alpine Orogen contains in South East Europe, from the Carpathians to the Balkans–Srednogorie, an Upper Cretaceous, ore bearing igneous belt: a narrow elongated body which runs discontinously from the Apuseni Mountains in the North, to the western part of the South Carpathians (Banat) in Romania, and further South to the Carpathians of East Serbia and still further East to Srednogorie (Bulgaria). This results in a belt of 750 km/30–70 km, bending from N-S in Romania and Serbia, to E-W in Bulgaria. Using the well established century-old terminology of this region, we describe it in this paper as the Banatitic Magmatic and Metallogenetic Belt (BMMB). Plate tectonics models of the Alpine evolution of South East Europe involve Mesozoic rifting, spreading and thinning of the continental crust or formation of oceanic crust in the Tethian trench system, followed by Cretaceous-Tertiary convergence of Africa with Europe and opening of Eastern Mediterranean and Black Sea troughs. The result of successive stages in the collision process is not only the continental growth of Europe from N to S by the docking of several microplates formerly separated from it by Mesozoic palaeo–oceans, but also the rise of mountain belts by overthickening of the crust, followed by orogenic collapse, lateral extrusion, exhumation of metamorphic core complexes and post-collisional magmatism connected to strike-slip or normal faulting. The BMMB of the Carpathian-Balkan fold belt is rich in ore deposits related to plutons and/or volcano-plutonic complexes. Serbian authors have proposed an Upper Cretaceous Paleorift in Eastern Serbia for the Timok zone and some Bulgarian geologists have furnished geologic, petrological and metallogenetic support for this extensional model along the entire BMMB. The existence and importance of previous westwards directed subductions of Transilvanides (=South Apuseni = Mure? Zone) and Severin-Krajina palaeo–oceans, popular in Roman ian literature, seems to have little relevance to BMMB generation, but the well documented northwards directed subduction of the Vardar-Axios palaeo–ocean during Jurassic and Lower Cretaceous is a good pre-condition for the generation, during the Upper Cretaceous, of banatitic magmas in extensional regime, by mantle delamination due to slab break–off. Four magmatic trends are found: a tholeiitic trend, a calc-alkaline trend, a calc-alkaline high–K to shoshonitic trend and, restricted to East Srednogorie, a peralkaline trend. For acid intrusives, the typology is clearly I-type and magnetite–series, pointing to sources in the deep crust or the mantle; however, some high ⁸⁷Sr/⁸⁶Sr ratios recorded in banatites prove important contamination from the upper crust. The calc-alkaline hydrated magmas, most common for banatitic plutons, can be considered as recording three stages of evolution: more primitive – the monzodioritic, dioritic to granodioritic trend (S Apuseni, S Ba–nat, Timok, C and W Srednogorie); more evolved – the granodioritic-granitic trend (N Apuseni, N Banat, Ridanj–Krepoljin); the alkaline trend (E and W Srednogorie, western part of N Banat). Correlating the composition of the host plutons with the types of mineralisation, several environments can be found in the BMMB, function of timing of fluid separation (porphyry versus non-porphyry environments), depth of emplacement, size of intrusion and geology of intruded rock pile, biotite versus hornblende crystallisation, involving the evolution of K/Na ratio in fluids, i. e. development of potassic and phyllic alteration zones: a) non-porphyry environment with granodioritic to granitic magmas, plutonic level, skarn mineralisation prevails; b) porphyry environment with monzodioritic or dioritic to granodioritic magmas, subvolcanic–hypabyssal–plutonic level; porphyry Cu with skarn halo at hypabyssal-subvolcanic level; c) porphyry environment with monzodioritic or dioritic to granodioritic magmas, volcano-plutonic complexes with porphyry copper plus massive sulfide mineralisation at subvolcanic-volcanic level; d) non-porphyry environment with magmas of alkaline tendency, volcanic level, vein (“mesothermal” and “epithermal”) mineralisation.     

Late proterozoic island arc volcanics from Gebeit,Red Sea Hills,north-east Sudan

The area of Gebeit Mine in the northern Red Sea Hills, Sudan, is built up of voluminous volcanic rocks and minor volcaniclastic and clastic sequences. According to their chemical and modal compositions the Gebeit volcanics can be devided into four groups: (a) cpx-physic basalts with clinopyroxene and plagioclase as the dominant phenocrysts and minor opaques; (b) hbl-physic basalts with hornblende, clinopyroxene, plagioclase and subordinate magnetite including one rare dacite; (c) pl-phyric andesites with plagioclase phenocrysts in a matrix that is rich in magnetite; and (d) aphyric basalts. The compositional variation within the distinct volcanic groups can only partly be explained by fractional crystallization, and more than one magma source reservoir is required.Mineral and whole rock Sm/Nd data for the cpx-physic and hbl-physic basalts yield an isochron age of 832 ± 26 Ma (Nd_T = 6.74 ± 0.19, MSWD = 0.12) which is interpreted as the age of eruption. The Nd_t values for the aphyric basalts and pl-physic andesites range from 6.7 to 8.3, indicating the involvement of different depleted magma sources. The Nd and Sr isotopic data rule out any significant influence of older continental crust in the formation of the Gebeit volcanics and indicate an intraoceanic origin. This implies that the Gebeit terrane is a segment of juvenile crust that originated in a subduction-related environment and supports the arc accretion model for the Arabian-Nubian Shield.