火山-侵入杂岩带的成岩-成矿专属性

成岩成矿关系问题,特别是成矿作用与岩浆活动的专属性问题,一直是矿床学研究中的重要课题。粤东地区热液脉状锡、钨（多金属）矿床产于中生代花岗质火山岩、次火山岩和侵入岩组成的火山侵入杂岩带中,成岩年龄与成矿年龄一致,但矿床地质、矿床矿物流体包裹体和同位素地球化学没有相对标准来区分这些来源于岩浆作用不同阶段、不同产出状态岩浆岩的成矿物质特征,使得人们对于区内矿床成因的认识不一。文中运用稀土元素地球化学方法,着重探讨和对比了矿床矿石、蚀变岩石及与成矿有关的岩浆岩的稀土元素特征和配分型式,并进一步根据在不同压力条件下Ｃｌ－在熔体和热液间的分配系数实验数据和不同压力条件下热液与相应熔体平衡时的稀土元素分配系数实验结果,分别计算了厚婆坳锡矿床和莲花山钨矿床与矿区有关岩浆岩熔体平衡的热液中的稀土元素浓度并制出配分型式,再与矿床矿石及矿石矿物稀土元素配分型式比较,从而确定成矿与侵入阶段的花岗岩岩浆活动关系密切。区内矿床为岩浆热液矿床。研究结果表明,稀土元素作为热液流体来源的示踪剂能有效地确定火山侵入杂岩带的成岩成矿专属性。     

3D model of Svecofennian Accretionary Orogen and Karelia Craton based on geology,reflection seismics,magnetotellurics and density modelling: Geodynamic speculations

A 3D model of deep crustal structure of the Archaean Karelia Craton and late Palaeoproterozoic Svecofennian Accretionary Orogen including the boundary zone is presented. The model is based on the combination of data from geological mapping and reflection seismic studies, along profiles 1-EU, 4B, FIRE-1-2a-2 and FIRE-3-3a, and uses results of magnetotelluric soundings in southern Finland and northern Karelia. A seismogeological model of the crust and crust–mantle boundary is compared with a model of subhorizontal velocity-density layering of the crust. The TTG-type crust of the Palaeoarchaean and Mesoarchaean microcontinents within the Karelia Craton and the Belomorian Province are separated by gently dipping greenstone belts, at least some of which are palaeosutures. The structure of the crust was determined mainly by Palaeoproterozoic tectonism in the intra-continental settings modified by a strong collisional compression at the end of the Palaeoproterozoic. New insights into structure, origin and evolution of the Svecofennian Orogen are provided. The accretionary complex is characterized by inclined tectonic layering: the tectonic sheets, ~15 ​km thick, are composed of volcanic-sedimentary rocks, including electro-conductive graphite-bearing sedimentary rocks, and electro-resistive granitoids, which plunge monotonously and consecutively eastward. Upon reaching the level of the lower crust, the tectonic sheets of the accretionary complex lose their distinct outlines. In the seismic reflection pattern they are replaced by a uniform acoustically translucent medium, where separate sheets can only be traced fragmentarily. The crust–mantle boundary bears a diffuse character: the transition from crust to mantle is recorded by the disappearance of the vaguely drawn boundaries of the tectonic sheets and in the gradual transition of acoustically homogeneous and translucent lower crust into transparent mantle. Under the effect of endogenic heat flow, the accretionary complex underwent high-temperature metamorphism and partial melting. Blurring of the rock contacts, which in the initial state created contrasts of acoustic impedance, was caused by partial melting and mixing of melts. The 3D model is used as a starting point for the evolutionary model of the Svecofennian Accretionary Orogen and for determination of its place in the history of the Palaeoproterozoic Lauro-Russian intracontinental orogeny, which encompassed a predominant part of the territory of Lauroscandia, a palaeocontinent combining North American and East European cratons. The model includes three stages in the evolution of the Lauro-Russian Orogen (~2.5, 2.2–2.1 and 1.95–1.87 ​Ga). The main feature of the Palaeoproterozoic evolution of the accretionary Svecofennian Orogen and Lauroscandia as a whole lay in the causal link with evolution of a superplume, which initiated plate-tectonic events. The Svecofennian–Pre-Labradorian palaeo-ocean originated in the superplume axial zone; the accretionary orogens were formed along both continental margins due to closure of the palaeo-ocean.     

Mafic-ultramafic magma activity and copper-nickel sulfide metallogeny during Paleozoic in the Eastern Kunlun Orogenic Belt,Qinghai Province,China

The Eastern Kunlun Orogenic Belt (EKOB) has a complex geological structure and diverse magmatic activities, which are closely related to the Qaidam Basin and the Tethys tectonic evolution. There are at least 3 stages mafic-ultramafic rocks occurred in the Early Paleozoic in EKOB. The first stage is the Later-Silurian to Early Devonian, represented by the giant Xiarihamu super large magmatic Cu-Ni deposit, containing about 1.18 million metric tons (Mt) of nickel with average grades of 0.65% Ni, and its age of ore-forming pyroxene peridotite is 411 Ma; The second stage is the Early Carboniferous, represented by the large Shitoukengde magmatic Cu-Ni sulfide deposit, and its ore-forming age of the olivine websterite is 334 Ma; The third stage of mafic-ultramafic rocks occurred mainly during the Middle-Late Triassic, represented by Xiaojianshan, Lalinggaoli, and Kaimuqi complexes, and no economical ore bodies have been found in this period. The authors summarized the difference between the ore-bearing and the nonmineralized mafic-ultramafic rocks in the EKOB. The olivine of the ore-bearing complexes contains higher MgO and SiO₂ content but lower FeO and CaO contents, and the clinopyroxene of ore-bearing complexes contains lower FeO and CaO contents. Crustal sulfur contamination is key to the formation of the giant Xiarihamu Ni deposit, and crustal sulfur contamination degree of the giant magmatic Ni deposit is higher than that of large Ni deposit. The above indicators could guide the exploration and evaluation of similar deposits in the EKOB.     

巴西与碱性岩- 碳酸岩杂岩体相关的关键矿产成矿作用与规律

在巴西,与碱性岩- 碳酸岩杂岩体相关成矿作用复杂,产出了世界上唯一的霞石正长岩型斜锆石矿床、全球最大的铌矿床以及巴西最大的铀矿和镍矿集区,资源储量丰富,具有重要的经济价值和战略意义,同时也是关键矿产成矿作用研究的殿堂。本文在前人研究基础之上,整理分析了35处与碱性岩- 碳酸岩相关的关键矿产地质特征。根据成矿作用特征,划分了4个成矿系列:①霞石正长岩碱性杂岩相关的U- Zr- Mo- REE 和萤石成矿系列;②碱性岩- 碳酸岩杂岩(正长岩+辉石岩+霓霞岩+碳酸岩等)相关的Nb- P- Ti- REE和蛭石成矿系列;③阿拉斯加型超基性岩- 碱性杂岩体相关的Ni成矿系列;④交代正长岩相关的U- P成矿系列。根据关键矿产资源时空分布规律,划分了5个成矿带:(Ⅰ)Lancinha- Cubato碱性岩- 碳酸岩相关REE- P- U- Zr- Ni- Mo- 蛭石成矿带;(Ⅱ)Rio de Janeiro- Rondnia碱性岩- 碳酸岩- 金伯利岩相关的Nb- REE- Ti- Zr- P- 金刚石成矿带;(Ⅲ)Ceará- Mato Grossodo Sul 超基性岩- 碱性岩- 碳酸岩相关的Ni- U- P- 蛭石成矿带;(Ⅳ)亚马逊地区碳酸岩相关Nb- REE- Th- Ti- P成矿带;(Ⅴ)巴伊亚地区与变正长岩相关的U成矿带。本文还详细介绍了典型矿床成矿地质特征和成矿条件,为走出去寻找关键矿产资源基地提供了理论支撑。     

湖北庙垭稀土矿床地质特征研究

庙垭稀土矿床位于北大巴山东北缘和武当隆起西部边缘接触处的过渡带中,是一个与正长岩碳酸岩杂岩体有关的特大型铌稀土矿床。以酸性火山岩为主体的武当隆起,其时代属性和构造属性也是该区的重要基础问题,与庙垭稀土矿床的形成有着密切的关系。庙垭杂岩体沿着耀岭河群与下志留统梅子垭组之间的断裂构造脆弱带分布,矿区北西向和北西西向断裂和褶皱均较发育,为碳酸岩岩浆从地幔向地壳浅部侵入提供了便利的通道和定位空间,并对铌、稀土矿的分布起一定的控制作用。杂岩体由北向南由边缘相、过渡相及中心相3个相带组成,表现有碳酸岩化、绢云母化、黑云母化、钠长石化、萤石化等围岩蚀变。结合区域地质背景和矿床地质特征,认为在正长岩之后形成的碳酸岩,与正长质岩浆有着密切关系。认为矿化物质来源应为正长岩浆侵入带来,后经岩浆期后气水热液交代作用,即各种碳酸岩化促使铌、稀土元素富集沉淀。杂岩体形成前后受构造作用控制明显,先期形成的岩石冷缩裂缝和构造破碎为后期气热交代创造了良好条件,矿化多侵位于耀岭河群的糜棱岩中。庙垭稀土矿床就是在火山岩喷发时所产生的正长岩碳酸岩与震旦系-古生界岩石地层逆冲推覆过程中相互耦合形成的。     

特提斯中西段古生代洋陆格局与构造演化

笔者根据国内外研究进展和区域地质对比,将特提斯中西段的古生代构造域划分为Iapetus-Tornquist洋加里东造山带、Rheic洋华力西期造山带、乌拉尔-天山中亚造山带和古特提斯Pontides-高加索-Mashhad造山带,并提出4个初步认识:(1)Rodinia超大陆在新元古代裂解形成的原特提斯大洋在欧洲以Ia...     

Structural architecture and low‐grade metamorphism of the Mikabu‐Northern Chichibu accretionary wedge,SW Japan

To understand tectono‐metamorphic processes within or close to the brittle–ductile transition of quartz‐rich crustal rocks in an accretionary wedge, an integrated field, petrological, geochronological and Raman spectroscopic study was conducted on the Mikabu‐Northern Chichibu belt in SW Japan. Field mapping in central Shikoku reveals that the Northern Chichibu belt is comprised of a pile of four tectono‐stratigraphic units, referred to as A, B, C and D units. The A unit (dominated by pelagic sedimentary rocks) represents the structurally lowest and youngest accretionary complex that forms a composite unit with the Mikabu ophiolitic suite. The B unit (consisting of chert‐clastic rock sequences) overlies the A unit and is overlain by the C and D units (mudstone‐matrix mélange units). Raman spectroscopy of carbonaceous material constrains the peak temperature of each unit to be ~290°C for the A unit, 270–290°C for the B unit, 230–250°C for the C unit and ~220°C for the D unit. Ductile deformation and pervasive metamorphism are limited to rocks in the Mikabu, A and B units. Alkali pyroxene and sodic amphibole occur in metabasite from the Mikabu, A and B units, and the widespread occurrence of prograde veins containing lawsonite+quartz pseudomorphs after laumontite was newly recognized from the C unit. Phase petrological data constrain the peak pressure of each unit to be ~0.65 GPa for the Mikabu‐A unit (aragonite stable), ~0.45–0.6 GPa for the B unit (jadeite+albite stable in the structurally lower part), and ~0.35 GPa for the C unit (prehnite+lawsonite stable). The peak metamorphic pressure increases towards structurally lower and younger accretionary complexes, but the thickness of the preserved strata is insufficient to account for the inferred pressure range. The structural–metamorphic relations imply thickening of the accretionary wedge by underplating was followed by a significant phase of thinning by both ductile and brittle processes.     

Geochemical contrast between the Sanbagawa psammitic schists (Oboke unit) and the Cretaceous Shimanto sandstones in Shikoku, Southwest Japan and its geologic significance

Abstract A systematic geochemical study of sandstones from the Cretaceous Shimanto Supergroup and psammitic schists from the Oboke unit in Shikoku has been carried out in order to clarify the depositional age of the protoliths of the Oboke psammitic schists. The geochemical data, together with chronological and geologic data, led to the following conclusions. (i) It is inferred that Oboke psammitic schists are metamorphically equivalent to sandstones in the Hiwasa Formation of the Shimanto accretionary complex, deposited in a trench area during the Campanian, in eastern Shikoku. (ii) The protolith attained to maximum metamorphic conditions within 20 million years after the deposition. (iii) The accumulation of a large amount of coarse-grained clastic sediments in the trench area induced offscraping and underplating of the sediments in the subduction zone, forming the Hiwasa Formation and Oboke unit, respectively.     

台湾增生楔的构造单元划分及其变形特征

台湾增生楔位于欧亚板块、菲律宾海微板块和南海的结合部位,是现代弧陆碰撞研究的理想场所。通过对南海973航次在该区域的多道地震剖面的解释,对该增生楔进行了构造单元的划分,并分析了变形特征。认为台湾增生楔是由3个部分,即弧陆碰撞产生的增生部分、洋内俯冲产生的增生部分和增生楔后端在恒春海脊和北吕宋海槽之间的构造楔组成,研究区的高屏斜坡、恒春海脊和北吕宋海槽西端变形带分别是3个部分的反映。自中中新世以来,南海洋壳开始沿着马尼拉海沟向菲律宾海微板块俯冲,形成增生楔中洋内俯冲增生部分;与此同时菲律宾海微板块开始向NW方向移动,前缘的吕宋岛弧自6．5Ma B．P以来与亚洲陆缘斜向碰撞,形成增生楔中弧陆碰撞增生部分。碰撞首先发生在台湾岛的北部,由于弧陆强烈的挤压作用,增生楔后端部分向北吕宋海槽倒冲楔人,使得上部的北吕宋海槽的沉积发生隆升变形。滨海的各个地貌单元可以和台湾陆上的地貌单元相联系,它们具有相似的地质特征,但是由于陆上部分增生历史久,不仅抬升为陆,而且地层的年代也更老。     

Structure of the Middle Urals,east of the main Uralian Fault

In the Middle Urals, volcanic-arc and back-arc basin rocks of Ordovician to Devonian age occur in the Tagil Synform. These outboard terranes were thrust westwards in the late Carboniferous onto continental margin associations of late Proterozoic and Palaeozoic age, now exposed in the Central Uralian Uplift. The Main Uralian Fault coincides approximately with the suture separating the outboard terranes from the East European Platform margin. New fieldwork in the hinterland of the Middle Urals in the area east of the Tagil Synform has found structural evidence favouring E-directed thrusting of accreted terranes and eugeoclinal allochthons in the late Palaeozoic. The upper tectonic units are composed of ophiolite mélange and volcano-sedimentary rocks of Ordovician to Devonian age; they are thrust onto high-grade gneisses, some of possible microcontinental affinities, extensively intruded by mid-Palaeozoic granitic plutons. The nappes in the hinterland are refolded by major upright antiforms and synforms that fold the entire tectonostratigraphy. After thrust assembly, all tectonic units east of the Main Uralian Fault were intruded by late Carboniferous to early Permian granites. Reflection seismic profiles (recorded to 8 s TWT), recently reprocessed at Cornell University, image the major fold structures and demonstrate that they are restricted to the upper crust, being underlain by an extensive zone of flat-lying middle crustal reflectivity. At 10–15 km depth the latter appears to truncate all structures, including the late- to post-tectonic granitoids and extensional faults, east of the Main Uralian Fault. Previous studies (potential-field, refraction- and wide-angle-reflection seismics) have identified an anomalously deep crust under the Tagil Synform and have concluded that the root zone of the orogen is located beneath this belt. The new evidence presented here supports this interpretation, with back-thrusting of the oceanic rocks eastwards over Palaeozoic accreted terranes. © 1998 John Wiley & Sons, Ltd.