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1.
Tectono-Metallogenic System in the Altay Orogenic Belt, China 总被引:7,自引:0,他引:7
WANG Jingbin ZHANG Jinhong DING Rufu FANG TonghuiBeijing Institute of Geology for Mineral Resources State Bureau of Nonferrous Metals Industry Andingmenwai Beijing 《《地质学报》英文版》2000,74(3):485-491
The Altay erogenic belt of China is an important metallogenic belt of base metals, rare metals and gold. The main orogenic-metallogenic epoch is the Hercynian (Late Palaeozoic). Hercynian orogeny underwent two tectonic stages: the early volcano-passive continental margin extension (D1-D2) and late subduction-collision (D3-P). There correspondingly developed two different metallogenic systems. One is the stratabound massive sulphide and iron metallogenic system related to volcano-passive continental margin, and the other is the epigenetic gold and granite-associated rare metals system formed by collision. Very few mineralizations were formed during the subduc-tion time. 相似文献
2.
新疆乔夏哈拉铁铜金矿床与国内外IOCG矿床的对比研究 总被引:11,自引:0,他引:11
随着IOCG矿床不断取得巨大的勘探成果,IOCG矿床在国内外都日益受到关注。新疆乔夏哈拉铁铜金矿床在构造环境、元素组合、蚀变特征等方面与国外典型的IOCG矿床有相似之处,乔夏哈拉铁铜金矿床处于大陆边缘拉张环境,具有Fe-Cu-Au(-REE)多元素组合,蚀变以绿帘石矽卡岩化为主,垂直分带不明显;在成矿时代方面又区别于多数产在元古代的IOCG矿床,而是在古生代;乔夏哈拉西矿区切割铁矿层的闪长岩脉角闪石的Ar-Ar坪年龄为378.1±3.6Ma,故铁的成矿年龄应在泥盆纪。本文认为乔夏哈拉铁铜金矿床不仅与IOCG矿床有较多相似之处,与国内内蒙古白云鄂博铁稀土铌矿床、云南迤纳厂铁铜稀土矿床、云南拉拉铜铁金钴钼稀土矿床和云南稀矿山铁铜矿床等也有相似之处,因此,在中国寻找IOCG矿床尤其是大型矿床,是有可能的。 相似文献
3.
阿尔泰山南缘中—酸性斑岩的地球化学特征及其岩石成因探讨 总被引:8,自引:2,他引:6
阿尔泰山南缘中—酸性斑岩侵入于中泥盆统北塔山组火山岩地层中,斑岩体规模较小,主要岩石类型为闪长斑岩、石英闪长斑岩、花岗闪长斑岩、石英二长斑岩等。对哈腊苏、卡拉先格尔、喀腊萨依、托斯巴斯陶和乔夏哈拉等5个与铜矿有关矿区的斑岩研究表明,其地球化学特征既有相似性,又有不同的特点,其中SiO2含量为534%~662%,A/CNK为098~127(大多数小于1),稀土元素表现为轻稀土相对富集、不具Eu异常的特点。微量元素表现为明显的Nb和Ta的负异常。但是Harker图解以及稀土元素配分曲线表明,不同地区的斑岩不存在演化关系。斑岩的Sr和Nd同位素组成基本上与与其共生的玄武岩相同,因此根据实验岩石学以及稀土模拟结果推测,它们可能是岛弧阶段底侵的基性岩石部分熔融形成的,源区相当于下地壳无水的角闪岩相,但含有少量的石榴子石,其中石榴子石和角闪石比例的差别可能是导致不同地区斑岩地球化学特征差别的主要原因。 相似文献
4.
阿尔泰南缘典型块状硫化物矿床成矿环境浅析 总被引:10,自引:2,他引:8
新疆阿尔泰南缘产有较丰富的块状硫化物矿床,主要分为块状硫化物铜(锌)矿、块状硫化物铅锌矿、块状硫化物铜(金)矿等基本类型,其代表分别是阿舍勒铜(锌)矿、可可塔勒铅锌矿、乔夏哈拉铜(金)矿,通过对这些矿床基本成矿特征及其矿环境的分析对比,认为它们形成于相同的成矿大地构造背景及相近的产出环境,但又有各自的富集部位及控矿因素,找矿标志也有差别,属于阿尔泰南缘陆缘裂谷带早-中泥盆世海底火山喷流-沉积环境下形成的同一成矿系列产物。 相似文献
5.
阿尔泰南缘古生代康布铁堡组火山岩系是许多铁矿、铜锌矿以及铅锌矿的赋矿围岩,但该赋矿地层目前还缺乏精确的同位素年代学资料。通过对变安山质凝灰岩和花岗岩LA-ICP-MS锆石U-Pb定年,获得阿尔泰南缘苏普特背斜花岗岩的年龄为412.7±0.78 Ma,安山质凝灰岩的年龄为411.2±3.4 Ma,表明阿尔泰南缘苏普特背斜内泥盆纪早期存在着强烈的火山活动,与区内广泛发育的火山岩属于同一事件的产物,具有相同的动力学背景。为研究阿尔泰南缘古生代构造演化及苏普特背斜异常区提供了重要的理论依据。 相似文献
6.
阿尔泰南缘麦兹泥盆纪火山_沉积盆地成矿特点及其铅锌、铁、金找矿潜力分析 总被引:7,自引:1,他引:7
麦兹盆地位于西伯利亚板块南缘阿尔泰陆缘活动带中,是一个重要的铅、锌、铁矿化集中区,其中著名的有蒙库大型铁矿床、可可塔勒大型铅锌矿床,是阿尔泰南缘多金属成矿带中最重要的成矿盆地之一。盆地内矿床、矿点多为火山喷流热水沉积成因,层控特征明显,具有规模大、形态规则、厚度及有用组分稳定等特点。铁矿成矿与早泥盆世早期细碧角斑质火山作用相伴,而铅锌成矿则与早泥盆世晚期长英质火山喷流沉积作用相伴。通过对麦兹盆地成矿地质特征和典型矿床中矿体分布变化规律的研究,认为北西向同生断裂、火山沉积洼地、火山喷发中心(火山机构)共同控制铅锌矿的产出,矿体还受到后期褶皱、变质作用的改造。根据有利层位、火山岩相、喷流沉积岩、热液蚀变、矿化组合、铁帽、控矿构造和地球化学异常等综合找矿评价标志,分析了可可塔勒矿区深部、什根特、铁热克萨依、H-48号异常的铅锌找矿潜力,并探讨了盆地内铁、金的找矿潜力,指出了进一步找矿的方向与有利地段。 相似文献
7.
8.
新疆晚古生代大陆边缘成矿系统与成矿区带初步探讨 总被引:15,自引:4,他引:15
新疆地处中亚成矿域的中段,古生代大陆边缘增生明显、构造和岩浆活动强烈、矿产资源丰富。古生代大陆边缘成矿作用主要集中在两个时期,即以阿尔泰南缘为主的早中泥盆世和以天山为主的早石炭世。本文在综合研究及与境外对比的基础上,按照北疆地区晚古生代大陆边缘的构造动力学和成矿特征,将研究区大陆边缘成矿系统划分为:活动大陆边缘海相火山岩-盆地流体成矿系统,活动大陆边缘火山岛弧-岩浆活动成矿系统和被动大陆边缘沉积盆地-热水活动成矿系统三类。同时对形成于大陆边缘的成矿区带进行划分,主要包括:阿勒泰南缘晚古生代活动大陆边缘块状硫化物成矿带;阿尔泰南缘-东准噶尔活动大陆边缘卡拉先格尔岛弧斑岩铜金成矿带;东天山晚古生代活动大陆边缘铜钼锌成矿区带;西准噶尔洋内弧斑岩-浅成低温热液铜金成矿区带;西天山(伊犁地块)活动大陆边缘金铜成矿区带;塔里木板块被动大陆边缘沉积型铅锌成矿带。本文认为大陆增生与成矿作用的关系是矿床学和成矿系统研究的重要内容,成矿区带是成矿系统发生成矿作用的响应,而成矿系统是成矿区带形成的本质。 相似文献
9.
新疆乔夏哈拉铁铜金矿的矿床成因及其成矿模式 总被引:7,自引:3,他引:4
新疆阿尔泰乔夏哈拉铁铜金矿床,与火山-沉积型铁矿床和矽卡岩型铁铜金矿床具有相似性.铁的主要来源为火山岩浆源,铜的来源为侵入体岩浆源和部分基性火山岩.铁矿石和铜矿石为两期成矿,属于不同的成矿机制,分别与火山-沉积作用和后期的热液叠加改造作用紧密相关.该矿床的成矿模式可概括为:在大量岩浆喷发、喷溢过程中,铁质在海水中富集并发生沉淀,形成似层状磁铁矿矿体;断裂的活动,致使中基性侵入体侵位,热液中的铜在一定环境中形成硫化物矿石,同时发生广泛的绿帘石矽卡岩化;矽卡岩阶段形成的磁铁矿叠加在原来的磁铁矿之上;断裂的再次活动,导致深部岩浆源含铜金矿液的上升,叠加定位于铁矿层及围岩新生裂隙带之中,形成浸染状和块状硫化物铜金矿石.研究表明,在准噶尔北缘向东南具有进一步找矿的潜力. 相似文献
10.
C.G. Murray 《Ore Geology Reviews》1986,1(2-4)
The northern part of the Tasman Fold Belt System in Queensland comprises three segments, the Thomson, Hodgkinson- Broken River, and New England Fold Belts. The evolution of each fold belt can be traced through pre-cratonic (orogenic), transitional, and cratonic stages. The different timing of these stages within each fold belt indicates differing tectonic histories, although connecting links can be recognised between them from Late Devonian time onward. In general, orogenesis became younger from west to east towards the present continental margin. The most recent folding, confined to the New England Fold Belt, was of Early to mid-Cretaceous age. It is considered that this eastward migration of orogenic activity may reflect progressive continental accretion, although the total amount of accretion since the inception of the Tasman Fold Belt System in Cambrian time is uncertain.The Thomson Fold Belt is largely concealed beneath late Palaeozoic and Mesozoic intracratonic basin sediments. In addition, the age of the more highly deformed and metamorphosed rocks exposed in the northeast is unknown, being either Precambrian or early Palaeozoic. Therefore, the tectonic evolution of this fold belt must remain very speculative. In its early stages (Precambrian or early Palaeozoic), the Thomson Fold Belt was probably a rifted continental margin adjacent to the Early to Middle Proterozoic craton to the west and north. The presence of calc-alkaline volcanics of Late Cambrian Early Ordovician and Early-Middle Devonian age suggests that the fold belt evolved to a convergent Pacific-type continental margin. The tectonic setting of the pre-cratonic (orogenic) stage of the Hodgkinson—Broken River Fold Belt is also uncertain. Most of this fold belt consists of strongly deformed, flysch-type sediments of Silurian-Devonian age. Forearc, back-arc and rifted margin settings have all been proposed for these deposits. The transitional stage of the Hodgkinson—Broken River Fold Belt was characterised by eruption of extensive silicic continental volcanics, mainly ignimbrites, and intrusion of comagmatic granitoids in Late Carboniferous Early Permian time. An Andean-type continental margin model, with calc-alkaline volcanics erupted above a west-dipping subduction zone, has been suggested for this period. The tectonic history of the New England Fold Belt is believed to be relatively well understood. It was the site of extensive and repeated eruption of calc-alkaline volcanics from Late Silurian to Early Cretaceous time. The oldest rocks may have formed in a volcanic island arc. From the Late Devonian, the fold belt was a convergent continental margin above a west-dipping subduction zone. For Late Devonian- Early Carboniferous time, parallel belts representing continental margin volcanic arc, forearc basin, and subduction complex can be recognised.A great variety of mineral deposits, ranging in age from Late Cambrian-Early Ordovician and possibly even Precambrian to Early Cretaceous, is present in the exposed rocks of the Tasman Fold Belt System in Queensland. Volcanogenic massive sulphides and slate belt-type gold-bearing quartz veins are the most important deposits formed in the pre-cratonic (orogenic) stage of all three fold belts. The voicanogenic massive sulphides include classic Kuroko-type orebodies associated with silicic volcanics, such as those at Thalanga (Late Cambrian-Early Ordovician. Thomson Fold Belt) and at Mount Chalmers (Early Permian New England Fold Belt), and Kieslager or Besshi-type deposits related to submarine mafic volcanics, such as Peak Downs (Precambrian or early Palaeozoic, Thomson Fold Belt) and Dianne. OK and Mount Molloy (Silurian—Devonian, Hodgkinson Broken River Fold Belt). The major gold—copper orebody at Mount Morgan (Middle Devonian, New England Fold Belt), is considered to be of volcanic or subvolcanic origin, but is not a typical volcanogenic massive sulphide.The most numerous ore deposits are associated with calc-alkaline volcanics and granitoid intrusives of the transitional tectonic stage of the three fold belts, particularly the Late Carboniferous Early Perman of the Hodgkinson—Broken River Fold Belt and the Late Permian—Middle Triassic of the southeast Queensland part of the New England Fold Belt. In general, these deposits are small but rich. They include tin, tungsten, molybdenum and bismuth in granites and adjacent metasediments, base metals in contact meta somatic skarns, gold in volcanic breccia pipes, gold-bearing quartz veins within granitoid intrusives and in volcanic contact rocks, and low-grade disseminated porphyry-type copper and molybdenum deposits. The porphyry-type deposits occur in distinct belts related to intrusives of different ages: Devonian (Thomson Fold Belt), Late Carboniferous—Early Permian (Hodgkinson—Broken River Fold Belt). Late Permian Middle Triassic (southeast Queensland part of the New England Fold Belt), and Early Cretaceous (northern New England Fold Belt). All are too low grade to be of economic importance at present.Tertiary deep weathering events were responsible for the formation of lateritic nickel deposits on ultramafics and surficial manganese concentrations from disseminated mineralisation in cherts and jaspers. 相似文献
11.
Based on published data and original investigations, it has been shown that the combination of widely known Ag, Fe, and Fe-Mn ore deposits, as well as boron and Pb-Zn world-class deposits, is typical for metallogenic zones in the north and northeast of the Sino-Korean Craton. The ore genesis was spatially inherited and lasted from the Archean to Mesozoic. The Archean metallogenic zones are related to the protocontinental margin terranes of the craton basement and they comprise banded iron ore and Cu-Zn sulfide deposits. The proterozoic-Early Paleozoic metallogenic zones are related to rift basins, where the ore-bearing Archean folded basement is overlain by volcanic and sedimentary complexes. The Proterozoic metallogenic zones host quartz veins and schistosity zone-related Au deposits, banded iron and Cu-Zn ore deposits, large sedimentary-metamorphogenic borate and magnesite deposits, Cu-W deposits in tourmalinites, exhalation-sedimentary Pb-Zn ore deposits, and large polygenic REE-Fe-Nb ore deposits. The Riphean-Cambrian terrigenous-carbonate strata are represented by stratiform Pb-Zn and fluorite deposits. Mesozoic metallogenic zones related to volcano-plutonic complexes of intraplate series coincide with zones where the folded basement is made of Precambrian ore-bearing series. Gold deposits are typical of all the metallogenic zones, but most of them are related to Mesozoic volcano-plutonic complexes. 相似文献
12.
新疆阿尔泰山南缘产于泥盆纪火山-沉积盆地铅锌矿床地质特征--以可可塔勒铅锌矿为例 总被引:9,自引:1,他引:8
可可塔勒矿床位于新疆阿尔泰造山带南缘,产于泥盆纪火山-沉积盆地内铅锌矿(可可塔勒)体呈似层状、透镜状,矿石构造以条纹条带状、块状、斑杂状为主,矿物成分相对简单,矿体直接容矿围岩为火山-沉积岩.矿床属火山-沉积岩容矿的块状硫化物矿床.为介于典型的火山岩容矿的块状硫化物型矿床(VHMS)和典型沉积岩容矿的硫化物矿床(SEDEX型)之间的过渡类型(一种新类型块状硫化物矿床),其矿化特征与伊比利亚型矿床相类似. 相似文献
13.
西天山查岗诺尔地区矿床成矿系列和找矿方向 总被引:10,自引:5,他引:10
西天山查岗诺尔地区是新疆重要的铁铜成矿带,形成于伊犁石炭-二叠纪裂谷。矿床类型有火山喷气沉积型铅锌硫化物矿、火山喷气沉积改造型铁铜、铜锌、铜硫化物矿、火山热液型铜硫化物矿、热液脉型金矿、火山热液型铜银矿。成矿系列划为与伊犁石炭-二叠纪裂谷火山-沉积作用有关的铁、铜、铅、锌、金、银多金属成矿系列,成矿亚系列为与下石炭统海相火山-沉积岩有关的铁、铜、锌、铅、金等层控硫化物矿床成矿亚系列和与下二叠统陆相火山-次火山岩有关的铜银矿成矿亚系列。矿床式有查岗诺尔式、欠哈布代克萨拉式、胜利式、巴勒陶萨拉式、哈尔嘎嘎林恩式、艾肯达坂式等。 相似文献
14.
合理划分成矿区带对矿产资源预测评价和勘查具有指导价值,而正确认识构造单元性质和成矿时期的构造环境是成矿带划分的重要前提。本文从地质建造、地球物理、卫星遥感等多角度全面分析了阿尔金山的内部组成及其边界断裂特征,认为阿尔金山原属于南塔里木地块的组成部分,阿尔金造山带是在古老地块基础上活化以后形成的特殊造山带,其特点明显不同于秦祁昆造山系,阿尔金成矿带应划归塔里木成矿省。阿尔金成矿带可进一步划分为三个次级成矿单元:红柳沟-喀腊大湾(裂谷)成矿亚带主要形成海相火山岩型铅锌矿、火山-沉积变质型铁矿;阿尔金(陆缘地块)成矿亚带主要形成石棉矿和玉石矿;迪木那里克-苏巴里克(裂陷槽)成矿亚带则以沉积变质型铁矿和石棉矿为主。 相似文献
15.
Spatial-temporal Frame,Evolution and Mineralization of the Northern Qilian Metallogenic Province 总被引:1,自引:0,他引:1
Sun Haitian Wu Jieren Li Jinping Institute of Mineral Deposits Chinese Academy of Geological Sciences Beijing Xi''an Institute of Geology Mineral Resources Chinese Academy of Geological Sciences Xi''an Shaanxi Institute of Mineral Deposits Chinese Academy of Geological Sciences Beijing 《《地质学报》英文版》1997,71(2):204-216
Four metallogenic epochs occurred in different tectonic environments during theevolution of the Northern Qilian metallogenic province through the geological time. The Mid-dle Proterozoic metallogenic epoch witnessed the tectonic environment of crustal breakupcaused by mantle diapirism, in which ultramafic-mafic rocks were intruded along beep faultbelts and the superlarge Jinchuan magmatic Cu-Ni sulphide deposit was formed. In theMiddle-Late Proterozoic metallogenic epoch the crust was further broken to form anintracontinental rift, in which the Chenjiamiao style massive Cu-Fe sulphide deposits hosted bybasic volcanic tuff were formed in the lower volcano-sedimentary sequence, while the largesedex type Jingtieshan style Fe-Cu deposits were formed within the upper abyssal carbon-richargillaceous sedimentary sequence. The Early Palaeozoic saw the aulacogen environment, with-in which the Baiyinchang style superlarge massive base and precious metal sulphide depositshosted by quartz keratophyric tuff were formed in the Middle-Late Cambrian rifted island arcand the massive Cu-Zn sulphide deposits and magmatic chromite deposits associated with theophiolite suite were formed in the Early-Middle Ordovician, and the Honggou style massiveCu-Fe sulphide deposits hosted by spilite were formed in the Late Ordovician back-arc basinenvironment. In the Late Palaeozoic-Meso-Cenozoic, the metallogenic province went into anintracontinental orogenic stage characterized by compressive tectonic environment, in whichthere occurred carbonate-quartz vein type and tectono-alteration gold deposits associated withductile-shear structures. 相似文献
16.
The Carpatho-Balkanides and adjacent area: a sector of the Tethyan Eurasian metallogenic belt 总被引:3,自引:1,他引:3
S. Janković 《Mineralium Deposita》1997,32(5):426-433
The Tethyan Eurasian metallogenic belt (TEMB) was formed during Mesozoic and post-Mesozoic times in the area of the former
Tethyan ocean on the southern margin of Eurasia, with the Afro-Arabian and Indian plates to the south. It extends from western
Mediterranean via the Alps and southeastern Europe through the Lesser Caucasus, the Hindu Kush, and the Tibet Plateau to Burma
and SW Indonesia, linking with the West Pacific metallogenic belt. The Carpatho-Balkan region is one of the sectors of the
TEMB, characterized by some specific features. The emplacement of ore deposits is related to a definite time interval, and
to specific tectonic settings such as:
1. Late Permian-Triassic intracontinental rifting along the northern margin of Gondwanaland and/or fragments already separated.
This setting involves volcanogenic and volcano-sedimentary deposits (iron, lead/zinc, manganese, antimony, mercury, barite),
skarn deposits associated with volcano-plutonic complexes of bimodal magmatism, and low temperature carbonate-hosted lead/zinc
deposits.
2. Jurassic intraoceanic rifting – ophiolite complexes: This setting hosts major magmatic (particularly podiform chrome deposits)
and volcano-sedimentary deposits, mainly of the Cyprus type.
3. Subduction-related setting involves porphyry copper deposits, lesser skarn deposits (iron, locally Pb-Zn), massive sulphide
Cu (e.g. Bor) accompanied locally by Pb-Zn of replacement type, epithermal gold deposits, associated with calc-alkaline igneous
complexes of the Early Tertiary-Late Cretaceous, and the Neogene gold/silver and base metals deposits.
4. Post-collision continent-continent setting includes deposits of Pb-Zn, Sb, As, Au-Cu associated with volcano-plutonic complexes
of calc-alkaline affinity.
Several major Alpine metallogenic units are developed in the Carpatho-Balkanides and adjacent area, each characterized by
specific development, mineral associations, and types of ore deposits.
Received: 3 June 1996 / Accepted: 10 January 1997 相似文献
17.
《International Geology Review》2012,54(3):293-299
China has many volcanogenic massive sulfide (VMS) deposits, few of which are familiar to Western geologists. The economic importance of VMS deposits in China has been increasingly recognized, especially after progress has been made on exploration and research in major orogenic belts since the 1980s. VMS deposits of various types with ages ranging from Proterozoic to Mesozoic have been identified within a number of major metallogenic belts. The VMS deposits in northwestern China occur in Hercy-Caledonian orogenic belts (the Altaides [Altay] and Qilian); those in southwestern China appear in the Himalaya-Tethyan orogenic belt as well as at the margin of Yangtze continental plate; and those in eastern China are related to basemental sequences of Proterozoic to early Paleozoic ages. Most of the important VMS deposits in China appear to be associated with paleotectonic settings of convergent plate margins. Only a few deposits presently have been identified as economically important, but if VMS deposits occur in clusters within metallogenic belts, then the potential for discovering more deposits is considerable. 相似文献
18.
In this review, we describe the geological characteristics and metallogenic–tectonic origin of Fe deposits in the Altay orogenic belt within the Xinjiang region of northwestern China. The Fe deposits are found mainly within three regions (ordered from northwest to southeast): the Ashele, Kelan, and Maizi basins. The principal host rocks for the Fe deposits of the Altay orogenic belt are the Early Devonian Kangbutiebao Formation, the Middle to Late Devonian Altay Formation, with minor occurrences of Lower Carboniferous and Early Paleozoic metamorphosed volcano-sedimentary rocks. The principal mineral-forming element groups of the deposits are Fe, Fe–Cu, Fe–Mn, Fe–P, Fe–Pb–Zn, Fe–Au, and Fe–V–Ti. The Fe deposits are associated with distinct formations, such as volcanic rocks, skarn deposits, pegmatites, granite-related hydrothermal vein mineralization, and mafic pluton-related V–Ti-magnetite deposits. The Fe deposits are most commonly associated with volcanic rocks in the upper Kangbutiebao Formation, in the volcano-sedimentary Kelan Basin, and in skarn deposits at several localities, including the lower Kangbutiebao Formation in the volcano-sedimentary Maizi Basin, and the Altay Formation at Jiaerbasidao–Kekebulake region. Homogenization temperatures of fluid inclusions in the prograde, retrograde and sulfide stages of the skarn type deposit are mainly medium- to high-temperature (cluster between 200 and 500 °C), medium-temperature (cluster between 200 and 340 °C) and low- to medium temperature (cluster between 160 and 300 °C), respectively. Ore fluids in the sedimentation period in the volcano-sedimentary type deposit are characterized by low- to medium temperature (with a peak around 190 °C), low to moderate salinity (3.23 to 22.71 wt.% NaCl equiv). Ore fluids in the pegmatite type deposit are characterized by low- to medium temperature (with a peak at 240 °C), low salinity (with a peak around 9 wt.% NaCl equiv). An analysis of the isotopic data for Fe deposits from the Altay orogenic belt indicates that the sulfur was derived from several sources, including volcanic rocks and granite, as well as bacterial reduction of sulfate from seawater. The present results indicate that different deposit types were derived from various sources. The REE geochemistry of rocks and ores from the Fe deposits in the Altay orogenic belt suggests that the ore-forming materials were derived from mafic volcanic rocks. Based on isotopic age data, the timing of the mineralization can be divided into four broad intervals: Early Devonian (410–384 Ma), Middle Devonian (377 Ma), Early Permian (287–274 Ma), and Early Triassic (c. 244 Ma). The ore-forming processes of the Fe deposits are closely related to volcanic activity and the emplacement of intermediate and felsic intrusions. We conclude that Fe deposits within the Altay orogenic belt developed in a range of tectonic settings, including continental arc, post-collisional extensional settings, and intracontinental settings. 相似文献
19.
华北克拉通北缘新太古代清原绿岩带,以产出中国最古老的红透山火山岩型块状硫化物(VMS)铜锌矿床而闻名.但近年同位素年代学研究表明,该绿岩带还发育同期的条带状(BIF)铁矿.对该绿岩带开展BIF铁矿、VMS铜锌矿时空和成因关系及其形成构造背景和海洋环境的研究非常必要.在综述近年笔者及前人获得的清原绿岩带地质剖面观察、典型VMS铜锌矿床和BIF铁矿床地质、锆石U-Pb年代学、主微量元素和Nd-Fe-S同位素地球化学等资料的基础上,总结了清原绿岩带VMS-BIF矿床组合形成的构造背景、成矿物质来源及形成规律.最后建立了新太古代清原绿岩带VMS-BIF弧后盆地系统成矿模式.这对于指导区域找矿预测、了解新太古代陆壳演化和古海洋环境均有重要的科学意义. 相似文献
20.
伊朗扎格罗斯造山带构造演化与成矿 总被引:1,自引:0,他引:1
扎格罗斯造山带是特提斯构造域的重要组成,其内赋存有世界级规模的金属矿产资源。本文综述了扎格罗斯造山带构造格架、物质组成、矿床分布及特征,讨论了该区构造演化与成矿。扎格罗斯造山带由南至北由扎格罗斯褶皱冲断带(ZFTB)、萨南达杰-锡尔詹岩浆变质带(SSZ)、乌尔米耶-达克塔尔火山岩浆带(UDMA)和伊朗中部地块四个构造单元组成。新元古代—早寒武世时,萨南达杰-锡尔詹带和伊朗中部地块位于冈瓦纳大陆北缘,受始特提斯洋盆俯冲影响,边缘发育大陆岩浆弧。晚石炭世—二叠纪萨南达杰-锡尔詹带和伊朗中部地块与冈瓦纳大陆裂解,新特提斯洋盆形成。三叠纪伊朗中部地块与北侧的欧亚大陆汇聚,古特提斯洋盆闭合。侏罗纪—白垩纪新特提斯洋盆向北侧的萨南达杰-锡尔詹带俯冲,形成弧岩浆岩及弧后盆地,其中弧前蛇绿岩中发育铬铁矿床,弧后盆地双峰式火山岩中产有块状硫化物矿床,碳酸盐岩内发育梅迪阿巴德密西西比河谷型超大型铅锌矿床。白垩纪末—新生代初洋壳向萨南达杰-锡尔詹带仰冲,含铬铁矿的蛇绿岩就位。始新世末—渐新世新特提斯洋闭合,南侧的阿拉伯板块与北侧的萨南达杰-锡尔詹带和中伊朗地块所在的欧亚大陆碰撞,在阿拉伯板块前缘形成扎格罗斯褶皱冲断带,在欧亚大陆南缘形成乌尔米耶-达克塔尔火山岩浆带。伴随碰撞,在萨南达杰-锡尔詹带的碳酸盐岩中形成类密西西比河谷型铅锌矿床,中中新世以来扎格罗斯地区进入后碰撞阶段,在乌尔米耶-达克塔尔带内发育了包括萨尔切实梅和松贡超大型矿床在内的众多斑岩型铜矿床。 相似文献