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1.
义敦岛弧是喜马拉雅巨型造山带中的一个复合造山带,它经历了印支期洋壳俯冲造山、燕山湖弧-陆碰撞和喜马拉雅期陆内走滑作用诸演化历史。可能由于洋壳板片俯冲角度不同,义敦晚三叠世古岛弧带(206~237 Ma)南北两段具有不同的发育历史,北段昌台弧以发育孤间裂谷为特色,具张性弧特征,发育扩张环境流体聚敛成矿系统,形成VMS型Zn-Pb-Cu矿床和浅成低温热液型Ag-Au-Hg矿床;南段中甸弧不发育弧后盆地,但广泛发育钙碱性弧火山岩-玢岩-斑岩杂岩系和挤压环境岩浆-流体成矿系统,形成斑岩型-夕卡岩型铜多金属矿床。在三叠纪-侏罗纪之交的弧-陆碰撞作用中,早期大陆板片俯冲形成同碰撞花岗岩带(约200 Ma),晚期造山后伸展作用,形成A型花岗岩带(75~138 Ma),伴随扬子大陆板片俯冲而发生的强烈剪切和推覆,在甘孜-理塘蛇绿混杂带发育挤压剪切环境流体聚敛成矿系统,形成剪切带型金矿。伴随造山后伸展和A型花岗岩侵位,发育伸张环境岩浆-流体聚敛成矿系统,主要形成夕卡岩型锡矿和构造破碎带热浪脉型银多金属矿床。印度-亚洲大陆碰撞在义敦造山带主要表现为陆内走滑作用,并控制碱性花岗岩和花岗斑岩的发育(50~30 Ma),伴随斑岩型金矿的形成。 相似文献
2.
秦岭造山带是中生代华北和扬子大陆碰撞形成的造山带,甘肃阳山超大型金矿是秦岭造山带内储量最大、代表性最强的金矿床,也是中国最大的金矿床之一。本文对阳山金矿地质和地球化学特征的系统总结表明,阳山金矿矿体形成受断裂构造控制;主要赋存在泥盆系三河口群泥质、粉砂质千枚岩内,部分矿体赋存在花岗斑岩内或两侧;主要的金属矿物为黄铁矿和毒砂;流体包裹体和C、H、O、S、Sr、Pb同位素研究显示,成矿流体主要源自变质热液或地层改造热液;成矿物质主要来自泥盆系三河口群和碧口群。阳山金矿矿化作用时间为190Ma左右,滞后花岗斑岩岩浆侵位时间约30Ma,排除了金成矿与晚三叠世的花岗岩浆作用有关的可能。阳山金矿矿床地质特征类似于卡林型金矿,成矿流体则具造山型矿床特征,总体上属造山型向卡林型金矿过渡性质的类卡林型金矿床。由于阳山金矿的矿化时间与西秦岭陆陆碰撞和大规模流体成矿事件相一致,因此阳山金矿是陆陆碰撞体制下流体演化和成矿作用形成的卡林-类卡林型金矿的代表。 相似文献
3.
秦岭造山带以其独特的大地构造位置、复杂的地质演化和丰富的矿产资源而成为地质科学研究的焦点,科学家已经基本清楚了其大地构造格局和地质演化轮廓,共识其在印支期(三叠纪:251~199.6Ma)彻底实现了由海盆向大陆造山带的转变。但是,盆山转变的过程细节、洋盆闭合的时间、三叠纪大地构造属性以及相关的岩浆作用和成矿作用研究薄弱,认识分歧较多。笔者通过综合分析地质、地球物理、地球化学、矿产资源等方面的研究成果,认为三叠纪的秦岭恰似现今地中海,并存着洋陆俯冲和陆陆碰撞,并逐渐由洋陆俯冲转变为陆陆碰撞体制;秦岭古特提斯洋于230~200Ma期间自东向西拉链式缝合,扬子陆块与华北-秦岭联合大陆之间的碰撞造山作用接踵而至;三叠纪的秦岭构造背景并非单一的陆陆碰撞,更非过去认为的造山后或碰撞后。秦岭印支期岩浆作用强烈,形成了埃达克岩、钙碱性花岗岩、高钾钙碱性花岗岩、碱性岩、疑似奥长环斑花岗岩、碳酸岩等多种岩浆岩;它们自勉略缝合带向北显示分带性,依次是:阳山—胭脂坝过铝质S型或改造型花岗岩带、南秦岭高镁埃达克质的钙碱性花岗岩带、北秦岭高钾钙碱性花岗岩带、华北克拉通南缘碱性岩-碳酸岩带;印支期岩浆作用的复杂性、多样性、空间分带性和成分极性等特点无法用陆陆碰撞或碰撞后构造体制来解释,而应是勉略洋板块向北俯冲的结果。秦岭印支期成矿作用长期被忽视,但最近已发现有重要经济价值的印支期矿床类型有碳酸岩脉型、造山型和斑岩型钼矿床,卡林型-类卡林型、造山型和斑岩-爆破角砾岩型金矿床,造山型银多金属矿床,表明在洋陆俯冲向陆陆碰撞转变体制的成矿作用强烈、成矿类型多样,印支期矿床的找矿潜力较大。 相似文献
4.
范家山铜金矿位于西秦岭北成矿亚带,温泉复式花岗岩天水斑岩夕卡岩钼铜金矿带的核心位置。矿床地质特征表明:范家山铜金矿体主要受岩体与围岩接触带以及岩体附近的断裂破碎带的控制,以金铜矿化为主,围岩蚀变为夕卡岩化、角岩化及硅化、绢英岩化等。范家山铜金矿床主矿脉包裹体温度、盐度及H-O同位素研究显示,主成矿流体的盐度(S)为2.0%~11.0%(w(NaCl)eq),均一温度为120~345 ℃,主要集中在150~280 ℃范围,具有中温和中低盐度的特征,为岩浆水和大气降水的混合。成矿花岗斑岩锆石U-Pb年龄为(248.3±1.9) Ma(MSWD=0.67, N=9),表明成矿活动发生在印支早期。结合区域构造背景,范家山铜金矿为印支期早期陆陆碰撞导致地壳加厚背景下的夕卡岩型矿床,深部具有斑岩型成矿的潜力。 相似文献
5.
滇西北红山铜钼矿床辉钼矿Re-Os同位素测年及其成矿意义 总被引:10,自引:7,他引:3
红山铜钼矿床是义敦岛弧南端格咱火山-岩浆弧中已探明规模最大的夕卡岩型铜矿床,近年来在其深部勘探过程中又发现斑岩型铜钼矿体.利用辉钼矿Re-Os同位素测年技术,分别对红山铜钼矿床中5件夕卡岩型矿石和1件斑岩型矿石中辉钼矿进行定年,首次获得红山铜钼矿床高精度成矿年龄.夕卡岩型矿石中辉钼矿Re-Os模式年龄为77.90 ~ 81.05Ma,加权平均值为79.32±0.87Ma,斑岩型矿石中辉钼矿模式年龄为80.71Ma,两者在误差范围内相一致;6件样品辉钼矿等时线年龄为80.0±1.8Ma,代表了红山铜钼矿床的成矿时代.辉钼矿中Re的含量为(4.074±0.035) ×l0-6~(94.21±0.75)×10-6,指示其物质来源以壳源为主,有少量幔源物质混入.红山铜钼矿床与格咱火山-岩浆弧燕山晚期岩浆侵入作用的高峰期及相关斑岩-夕卡岩型多金属矿床的成矿年龄一致,表明它们是弧陆碰撞的后造山伸展背景下同一区域地质事件的产物,该期夕卡岩-斑岩型铜钼多金属具有较大成矿潜力. 相似文献
6.
中国镍矿成矿规律初探 总被引:12,自引:0,他引:12
我国镍矿可分为岩浆型、海相沉积型和风化壳型3种预测类型.矿床形成时代较为连续,最早形成于中—新元古代,最晚形成于新生代,其中中—新元古代和晚古生代是形成矿床的两个高峰期;中—新元古代矿床主要分布在华北地块和扬子地块周缘,晚古生代镍矿主要分布在中亚造山带、峨眉山和塔里木大火成岩省范围内.岩浆型镍矿主要形成于大陆边缘裂解、造山带后碰撞伸展以及地幔柱3种构造背景,根据不同构造背景并结合主要岩浆作用特点,将与幔源基性—超基性岩有关的镍-铜-钴-铂族元素矿床成矿系列类型划分出与大陆裂解边缘幔源基性—超基性岩浆作用有关的镍-铜-钴-铂族元素矿床成矿亚类型、与地幔柱基性—超基性岩浆作用有关的镍-铜-钴-铂族元素矿床成矿亚类型、与造山带俯冲作用下幔源基性—超基性岩有关的镍-铜-钴-铂族元素矿床成矿亚类型、与造山带后碰撞伸展背景下幔源基性—超基性岩有关的镍-铜-钴-铂族元素矿床成矿亚类型等4种亚类型.分别对中—新元古代与大陆边缘裂解有关的镍铜(铂)矿床、寒武纪与黑色页岩有关的海相沉积型镍钼钒矿床、早二叠世与造山带伸展背景有关的镍铜矿床、晚二叠世与大火成岩省有关的镍铜(铂)矿床、新生代与风化壳有关的镍金矿床及其对应的典型矿床特征和成矿模式进行了叙述;认为大陆裂解边缘、地幔柱、造山带后碰撞伸展是我国镍矿形成的有利成矿地质背景,与邻近深大断裂、镁铁—超镁铁岩体、高MgO的原生岩浆(高镁玄武质岩浆)、深部岩浆作用、硫饱和与硫化物熔离共同组成岩浆型镍矿的6个重要地质条件. 相似文献
7.
西秦岭近年来在新区发现新矿床和新类型金矿,矿床的地质特征表明金矿成矿受岩性、构造、岩浆活动的制约,许多金矿的地质、地球化学特征显示成矿与岩浆岩在时间和空间上关系密切;分析认为金矿主成矿时间为印支晚期-燕山早期,与区域大规模的岩浆活动在时间上一致;金矿主要有夕卡岩型、热液脉型和与岩浆活动有关的微细浸染型三种类型。矿石矿物元素组合显示由北而南成矿深度变浅、剥蚀程度较低;根据金、汞、锑矿床点和金、砷、锑、银元素分布特征,认为在北带岩体旁侧应注意寻找夕卡岩型和热液脉型金矿,中、南矿带在已知矿床深部注意寻找热液脉型金矿,有锑、汞矿点的区域注意深部及外围金矿的找矿;通过分析,最后圈定18处下一步重点工作区。 相似文献
8.
在皖赣沿江地区分布着大量中生代侵入岩体及其岩石包体和相关的夕卡岩矿床。本文在综合整理作者研究团队近30年来所获得的区内大部分侵入岩体及其岩石包体和夕卡岩矿床研究资料的基础上,聚焦区域中生代壳幔相互作用与多成因夕卡岩成矿过程分析,为发展壳幔成矿学打下一定基础。基性侵入岩和镁铁质岩石包体的同位素年代学和岩石地球化学资料表明,皖赣沿江地区在中生代发生了碰撞后(145~135 Ma)富铜金和造山后(130~120 Ma)富铁金幔源岩浆底侵作用和相应的壳幔混源岩浆作用。壳幔混源岩浆作用主要包括结晶分异作用、同化混染作用、岩浆混合作用和岩浆熔离作用。夕卡岩矿床地质调研和镜下观察结果显示,两期壳幔混源岩浆侵入晚古生代到早中生代围岩地层后引发了多成因夕卡岩成矿作用,形成了接触交代、层控、岩浆和复合叠加等多成因夕卡岩矿床。接触交代、层控、岩浆和复合叠加夕卡岩矿床分别以热液交代、沉积+热液交代、岩浆结晶+热液交代和沉积+岩浆结晶+热液交代矿物组合和结构构造为特征。在碰撞后酸性-中酸性侵入岩体中产有富Cu和Zn等成矿物质的元古宙变质岩包体,表明碰撞后富铜金的底侵玄武岩浆或其演化岩浆在浅位岩浆房中同化了元古宙变质基底成矿物质(铜锌等)储库导致铜进一步富集,从而形成更富铜的酸性-中酸性岩浆。在碰撞后中基性-基性侵入岩体中产有含大量Cu-Fe硫化物(黄铜矿和磁黄铁矿)和氧化物包裹体的深位和浅位堆积岩,表明碰撞后富铜金的底侵玄武岩浆在深位岩浆房中和其演化岩浆在浅位岩浆房中发生了强烈的结晶分异作用导致铜铁亏损,形成更富金的中基性-基性岩浆。酸性-中酸性侵入岩体中夕卡岩包体和夕卡岩中辉长岩-夕卡岩过渡包体的存在表明,碰撞后富铜金的底侵玄武岩浆在侵位处同化晚古生代含铜铁矿源层的碳酸盐地层导致铜进一步富集,形成更富铜的夕卡岩岩浆。更富铜的酸性-中酸性岩浆、更富金的中基性-基性岩浆和更富铜的夕卡岩岩浆是形成碰撞后时期接触交代和层控夕卡岩铜矿、接触交代夕卡岩金矿和岩浆夕卡岩铜矿的最重要控制因素。在造山后中基性-基性侵入岩体中产有含大量Cu-Fe硫化物(黄铜矿和磁黄铁矿)和氧化物包裹体的堆积岩,表明造山后富铁金的底侵玄武岩浆在深位岩浆房中发生了强烈的结晶分异作用导致铜铁亏损,从而形成更富金的中基性-基性岩浆。造山后富铁金的底侵玄武岩浆在侵位处同化晚古生代含铜铁矿源层的碳酸盐地层、早中生代铁矿源层或者早中生代铁硅矿源层,导致铁、铁和铁硅的进一步富集,分别形成更富铁的夕卡岩岩浆、基性岩浆和中基性岩浆。更富金的中基性-基性岩浆及更富铁的夕卡岩岩浆、基性岩浆和中基性岩浆是形成造山后时期接触交代夕卡岩金矿、岩浆夕卡岩铁矿、矿浆型铁矿和接触交代夕卡岩铁矿的关键控制因素。 相似文献
9.
老挝琅勃拉邦—泰国黎府成矿带位于印支板块西北缘,是中南半岛重要的金铜成矿带之一。该带经历了晚古生代—中生代古特提斯构造-岩浆演化作用,成矿活动复杂,形成了斑岩-矽卡岩型金铜矿床、浅成低温热液型金银矿床以及热液脉型金矿床。然而,热液脉型金矿的成因类型仍存在争议,3类金铜矿床与区域构造演化的关系仍缺乏总结。本文通过对前人典型矿床研究资料的整理,并结合成矿流体来源、演化新证据,将带内热液脉型金矿床的成因类型归为造山型金矿。综合区域构造-岩浆-成矿作用研究资料,总结了成矿带内3类金铜矿床的时空分布规律和成矿特征,建立了与古特提斯洋俯冲-闭合及陆陆碰撞过程相关的区域金铜成矿模式,提出了晚二叠世—早三叠世俯冲期浅成低温热液型金银矿床、早中三叠世闭合期斑岩-矽卡岩型铜金矿床、晚三叠世陆陆碰撞期造山型金矿床的成矿规律。 相似文献
10.
大陆碰撞成矿论 总被引:54,自引:2,他引:52
基于经典的板块构造而建立的成矿理论已日臻完善,完好地解释了增生造山成矿作用及汇聚边缘成矿系统发育机制,但却无法解释碰撞造山成矿作用及大陆碰撞带成矿系统。通过对青藏高原碰撞造山与成矿作用的详细研究,并与中国秦岭和其它碰撞造山带综合对比,本文系统提出了一套全新的大陆碰撞成矿理论,简称"大陆碰撞成矿论",初步阐明了大陆碰撞带成矿系统和大型矿床的成矿动力背景、深部作用过程和形成机制。该理论认为,伴随大陆三段式碰撞过程而发育的主碰撞陆陆汇聚环境、晚碰撞构造转换环境和后碰撞地壳伸展环境,是大陆碰撞带成矿系统和大型矿床的主要成矿构造背景。对应于三段式碰撞而在深部出现的俯冲板片断离、软流圈上涌和岩石圈拆沉过程,是导致大规模成矿作用的异常热能驱动力。伴随三段式碰撞而分别出现的压-张交替或压扭/张扭转换的应力场演变,是驱动成矿系统形成发育的构造应力机制。大陆碰撞产生的不同尺度的高热流、不同起源的富金属流体流、不同级次的走滑-剪切-拆离-推覆构造系统和张性裂隙系统,是形成成矿系统和大型矿床的主导因素。成矿金属在碰撞形成的壳/幔混源高fO2岩浆-热液系统、地壳深熔低fO2岩浆-热液系统、剪切变质-富CO2流体系统以及逆冲推覆构造驱动的区域卤水系统和浅位岩浆房诱发的对流循环流体系统中,伴随成矿金属的积聚与淀积是形成大型矿床的关键机制。"大陆碰撞成矿论"还强调,完整的大陆碰撞过程可以引发三次大规模成矿作用,形成一系列标示性的大型矿床:在主碰撞陆陆汇聚成矿期,大陆碰撞引发地壳加厚与深熔,产生富W-Sn壳源花岗岩,形成花岗岩型Sn-W矿床;大陆俯冲板片断离诱发软流圈上涌,产生富金属的壳/幔混源花岗闪长岩,形成岩浆-热液型或叠合型Pb-Zn-Mo-Fe矿床;大陆碰撞从变质地体排挤出富CO2流体,在剪切带形成造山型Au矿,从造山带排泄出建造流体,在前陆盆地形成MVT型Zn-Pb矿。在晚碰撞构造转换成矿期,大规模走滑断裂系统诱发壳幔过渡带和富集地幔减压熔融,其岩浆在浅部地壳岩浆房出溶成矿流体,分别形成斑岩型Cu(-Mo-Au)矿床和碳酸岩型REE矿床;深切岩石圈的剪切作用与下地壳变质产生含Au富CO2流体,形成造山型Au矿;逆冲推覆构造驱动地壳流体长距离迁移汇聚、走滑拉分导致流体大量排泄和充填,形成Pb-Zn-Cu-Ag矿。在后碰撞地壳伸展成矿期,新生下地壳部分熔融产生富金属、富水、高fO2埃达克质岩浆浅成侵位和流体出溶,产生斑岩型Cu矿;中上地壳部分熔融层(岩浆房)驱动地热流体系统,在地热区发育热泉型Cs-Au矿,在构造拆离带形成热液脉型Pb-Zn-Sb和Sb-Au矿。 相似文献
11.
Geodynamic settings and tectonic model of skarn gold deposits in China: An overview 总被引:47,自引:0,他引:47
Yan-Jing Chen Hua-Yong Chen Khin Zaw Franco Pirajno Zeng-Jie Zhang 《Ore Geology Reviews》2007,31(1-4):139-169
Seventy skarn-type gold deposits, including 1 super-large, 19 large and 24 medium-sized, are known from different geotectonic units of China. They contain a total resource of approximately 1000 t of gold (625 t in South China), and account for 20% of China's gold reserves. These skarn deposits are sited in collisional orogenic belts, fault-controlled magmatic belts and reactivated cratonic margins. All of the Chinese skarn gold provinces were affected by Phanerozoic collisional orogenesis. The timing of the metallogenic events and the spatial–temporal distribution of the Chinese skarn gold deposits indicates that they were formed during ore-forming processes linked to the transition from shortening to extension in the geodynamic evolution of a collision orogen, and not to subduction systems as is commonly advocated for porphyry copper systems around the Pacific Rim. 相似文献
12.
We present a review of major gold mineralization events in China and a summary of metallogenic provinces, deposit types, metallogenic epochs and tectonic settings. Over 200 investigated gold deposits are grouped into 16 Au-metallogenic provinces within five tectonic units such as the Central Asian orogenic belt comprising provinces of Northeast China and Tianshan-Altay; North China Craton comprising the northern margin, Jiaodong, and Xiaoqinling; the Qinling-Qilian-Kunlun orogenic belt consisting of the West Qingling, North Qilian, and East Kunlun; the Tibet and Sanjiang orogenic belts consisting of Lhasa, Garzê-Litang, Ailaoshan, and Daduhe-Jinpingshan; and the South China block comprising Youjiang basin, Jiangnan orogenic belt, Middle and Lower Yangtze River, and SE coast. The gold deposits are classified as orogenic, Jiaodong-, porphyry–skarn, Carlin-like, and epithermal-types, among which the first three types are dominant.The orogenic gold deposits formed in various tectonic settings related to oceanic subduction and subsequent crustal extension in the Qinling-Qilian-Kunlun, Tianshan-Altay, northern margin of North China Craton, and Xiaoqinling, and related to the Eocene–Miocene continental collision in the Tibet and Sanjiang orogenic belts. The tectonic periods such as from slab subduction to block amalgamation, from continental soft to hard collision, from intracontinental compression to shearing or extension, are important for the formation of the orogenic gold deposits. The orogenic gold deposits are the products of metamorphic fluids released during regional metamorphism associated with oceanic subduction or continental collision, or related to magma emplacement and associated hydrothermal activity during lithospheric extension after ocean closure. The Jiaodong-type, clustered around Jiaodong, Xiaoqinling, and the northern margin of the North China Craton, is characterized by the involvement of mantle-derived fluids and a temporal link to the remote subduction of the Pacific oceanic plate concomitant with the episodic destruction of North China Craton. The Carlin-like gold metallogenesis is related to the activity of connate fluid, metamorphic fluid, and meteoric water in different degrees in the Youjiang basin and West Qinling; the former Au province is temporally related to the remote subduction of the Tethyan oceanic plate and the later formed in a syn-collision setting. Porphyry–skarn Au deposits are distributed in the Tianshan-Altay, the Middle and Lower Yangtze River region, and Tibet and Sanjiang orogenic belts in both subduction and continental collision settings. The magma for the porphyry–skarn Au deposits commonly formed by melting of a thickened juvenile crust. The epithermal Au deposits, dominated by the low-sulfidation type, plus a few high-sulfidation ones, were produced during the Carboniferous oceaic plate subduction in Tianshan-Altay, during Early Cretaceous and Quaternary oceanic plate subduction in SEt coast of South China Block, and during the Pliocene continental collision in Tibet. The available data of different isotopic systems, especially fluid D–O isotopes and carbonate C–O systems, reveal that the isotopic compositions are largely overlapping for different genetic types and different for the same genetic type in different Au belts. The isotopic compositions are thus not good indicators of various genetic types of gold deposit, perhaps due to overprinting of post-ore alteration or the complex evolution of the fluids.Although gold metallogeny in China was initiated in Cambrian and lasted until Cenozoic, it is mainly concentrated in four main periods. The first is Carboniferous when the Central Asian orogenic belt formed by welding of micro-continental blocks and arcs in Tianshan-Altay, generating a series of porphyry–epithermal–orogenic deposits. The second period is from Triassic to Early Jurassic when the current tectonic mainframe of China started to take shape. In central and southern China, the North China Craton, South China Block and Simao block were amalgamated after the closure of Paleo-Tethys Ocean in Triassic, forming orogenic and Carlin-like gold deposits. The third period is Early Cretaceous when the subduction of the Pacific oceanic plate to the east and that of Neo-Tethyan oceanic plate to the west were taking place. The subduction in eastern China produced the Jiaodong-type deposits in the North China Craton, the skarn-type deposits in the northern margin (Middle to lower reaches of Yangtze River) and the epithermal-type deposits in the southeastern margin in the South China Block. The subduction in western China produced the Carlin-like gold deposits in the Youjiang basin and orogenic ones in the Garzê-Litang orogenic belt. The Cenozoic is the last major phase, during which southwestern China experienced continental collision, generating orogenic and porphyry–skarn gold deposits in the Tibetan and Sanjiang orogenic belts. Due to the spatial overlap of the second and third periods in a single gold province, the Xiaoqinling, West Qinling, and northern margin of the North China Craton have two or more episodes of gold metallogeny. 相似文献
13.
碰撞造山带与成矿区划 总被引:8,自引:1,他引:8
碰撞造山事件与成矿作用具有强烈的对应耦合关系,而且成矿规模与碰撞的强度呈正相关关系。碰撞造山带的壳幔物质相互作用与成矿作用的强度也呈正相关关系,特别是多期次碰撞造山带,均发生过强烈的壳幔物质相互作用,孕育着丰富的矿产资源。详细地研究了碰撞造山的构造演化过程,划分了相应的成矿构造单元和成矿区带。从碰撞造山的角度提出西天山、西昆仑山、阿尔金-北祁连山、东昆仑山、秦岭-大别山、西南三江、康滇陆缘等造山带为重要的成矿区带。 相似文献
14.
The Tethyside orogen, a direct consequence of the separation of the Gondwanaland and the accretion of Eurasia, is a huge composite orogenic system that was generated during Paleozoic–Mesozoic Tethyan accretionary and Cenozoic continent–continent collisional orogenesis within the Tethyan domain. The Tethyside orogenic system consists of a group of diverse Tethyan blocks, including the Istanbul, Sakarya, Anatolide–Taurides, Central Iran, Afghanistan, Songpan–Ganzi, Eastern Qiangtang, Western Qiangtang, Lhasa, Indochina, Sibumasu, and Western Burma blocks, which were separated from Gondwana, drifted northwards, and accreted to the Eurasian continent by opening and closing of two successive Tethyan oceanic basins (Paleo-Tethyan and Neo-Tethyan), and subsequent continental collision.The Tethyan domain represents a metallogenic amalgamation across diverse geodynamic settings, and is the best endowed of all large orogenic systems, such as those associated with the Cordilleran and Variscan orogenies. The ore deposits within the Tethyan domain include porphyry Cu–Mo–Au, granite-related Sn–W, podiform chromite, sediment-hosted Pb–Zn deposits, volcanogenic massive sulfide (VMS) Cu–Pb–Zn deposits, epithermal and orogenic Au polymetallic deposits, as well as skarn Fe polymetallic deposits. At least two metallogenic supergroups have been identified within the eastern Tethyan metallogenic domain (ETMD): (1) metallogenesis related to the accretionary orogen, including the Zhongdian, Bangonghu, and Pontides porphyry Cu belts, the Pontides, Sanandaj–Sirjan, and Sanjiang VMS belts, the Lasbela–Khuzdar sedimentary exhalative-type (SEDEX) Pb–Zn deposits, and podiform chromite deposits along the Tethyan ophiolite zone; and (2) metallogenesis related to continental collision, including the Gangdese, Yulong, Arasbaran–Kerman and Chagai porphyry Cu belts, the Taurus, Sanandaj–Sirjan, and Sanjiang Mississippi Valley-type (MVT) Pb–Zn belts, the Southeast Asia and Tengchong–Lianghe Sn–W belts or districts, the Himalayan epithermal Sb–Au–Pb–Zn belt, the Piranshahr–Saqez–Sardasht and Ailaoshan orogenic Au belts, and the northwest Iran and northeastern Gangdese skarn Fe polymetallic belts. Mineral deposits that are generated with tectonic evolution of the Tethys form in specific settings, such as accretionary wedges, magmatic arcs, backarcs, and passive continental margins within accretionary orogens, and the foreland basins, foreland thrust zones, collisional sutures, collisional magmatic zones, and collisional deformation zones within collisional orogens.Synthesizing the architecture and tectonic evolution of collisional orogens within the ETMD and comparisons with other collisional orogenic systems have led to the identification of four basic types of collision: orthogonal and asymmetric (e.g., the Tibetan collision), orthogonal and symmetric (Pyrenees), oblique and symmetric (Alpine), and oblique and asymmetric (Zagros). The tectonic evolution of collisional orogens typically includes three major processes: (1) syn-collisional continental convergence, (2) late-collisional tectonic transform, and (3) post-collisional crustal extension, each forming distinct types of ore deposits in specific settings. The resulting synthesis leads us to propose a new conceptual framework for the collision-related metallogenic systems, which may aid in deciphering relationships among ore types in other comparable collisional orogens. Three significant processes, such as breaking-off of subducted Tethyan slab, large-scale strike-slip faulting, shearing and thrusting, and delamination (or broken-off) of lithosphere, developed in syn-, late- and post-collisional periods, repsectively, were proposed to act as major driving forces, resulting in the formation of the collision-related metallogenic systems. Widespread appearance of juvenile crust and intense inteaction between mantle and crust within the Himalayan–Zagros orogens indicate that collisional orogens have great potential for the discovery of large or giant mineral deposits. 相似文献
15.
Types,geological features and geodynamic significances of gold-copper deposits in the Kanggurtag metallogenic belt,eastern Tianshan,NW China 总被引:5,自引:0,他引:5
Occupying the middle of the central Asia Paleozoic accretionary and collisional orogenic belt, the eastern Tianshan area has a great economic potential due to Au-Cu mineralization during syn- and post- orogenic events. In the Kanggurtag Au-Cu metallogenic belt, three major types of gold deposits have been recognized: ductile-shear-zone-hosted gold deposits, magmatic hydrothermal gold deposits, and epithermal gold deposits. Four kinds of copper deposits have also been identified recently: the porphyry-type, the skarn-type, the magmatic type, and volcanic/sedimentary-type. Tectonically, the development of these late Paleozoic gold and copper deposits was closely associated with the subduction and collision of the ancient Tianshan ocean that intervened between the Tarim craton and the Siberian block. In the early to mid-Carboniferous, N-dipping subduction beneath the Dananhu arc generated magmatic intrusions, leading to formation of the porphyry Cu deposits. The magmatic front migrated southward to form the Yamansu arc upon the Kanggurtag accretionary wedge. In the latest Carboniferous to early Permian, during the closure of the ancient Tianshan ocean, large mafic-ultramafic complexes were emplaced, resulting in several magmatic copper-nickel deposits. Gold deposits of the shear-zone-type are controlled by the Kanggurtag ductile shear zone, which is related to collisional orogenesis. The epithermal gold deposits are associated with extensional tectonics and post-tectonic volcanic activity. The tectonic settings, geological features, and temporal and spatial distributions of these different types of gold and copper deposits reflect, to a great extent, the accretionary and collisional tectonics that occurred between the northern margin of the Tarim block and the southern margin of the Siberian block. 相似文献
16.
《International Geology Review》2012,54(11):1006-1007
The considerable gold resource potential in China has been increasingly recognized in recent years, following detailed geological investigation of the major orogenic belts since the 1980s. The major tectonic components of China include the Sino-Korean, Yangtze, Tarim, and Cathaysian Precambrian platforms surrounded by the Altaides, Tianshan-Inner Mongolia, Daxinganling, Alkin, Kunlun, Qilian, Qinling, Himalaya-Tethys, and Nanling orogenic belts. A large number of gold deposits and geochemical anomalies have been discovered in all of these lithotectonic provinces. The most important deposit types are Precambrian lode, Carlin-type, ophiolite-related, porphyry-related, volcanic epithermal, and possible Muruntau-type gold deposits, occurring mainly in seven major metallogenic districts in eastern and southwestern China. Many lithotectonic belts provide favorable locations for the formation of various large gold deposits and are comparable with other productive gold provinces of the world, such as the Canadian Shield and Circum-Pacific magmatic arcs. The geochemical anomalies and many existing gold deposits and metallogenic belts in China require additional detailed study on the basis of modern exploration technologies. 相似文献
17.
中国东北地区主要地质特征和地壳构造格架 总被引:3,自引:2,他引:1
中国东北地区位于亚洲大陆东缘,发育中国乃至地球上最古老的地质记录、多个时代的古洋岩石圈残片和活动陆缘及陆间碰撞岩浆岩带,具有独特的盆山-山脉相间地貌特征,蕴藏着丰富的自然资源。迄今为止,对于该区古生代构造单元如何划分,一直存在截然不同的认识;对于该区中生代以来的构造格架,缺乏系统的论述。本文在简要介绍现今不同山脉和盆地等地理单元地质特征的基础上,基于断裂构造和地貌特征等方面的资料,把该区新生代构造单元划分为大兴安岭、小兴安岭、阴山-燕山和长白山等4个隆起带,海拉尔-锡林浩特、松辽、三江-兴凯湖和下辽河等4个断陷带。基于岩浆活动和沉积盆地分布,结合区域地球动力学背景,提出了该区晚三叠世至中侏罗世、晚侏罗世、早白垩世早期和早白垩世晚期至古新世等不同阶段构造单元划分的初步方案。基于对已有资料的综合研究,对该区古生代构造单元的特征、松辽盆地的基底组成、早古生代和晚古生代华北克拉通北部边界的位置以及古生代洋盆演化及结束时间等重大地质构造问题,进行了初步探讨,提出了阴山-燕山地区在古生代晚期由克拉通转化为陆缘活化造山带;松辽盆地基底具有与周缘造山系相同的地质组成;该区古生代构造单元是陆缘造山带与碰撞造山带的复合而不是地块拼贴;该区在二叠纪晚期遭受了碰撞造山并在华北北缘形成了高耸的近东西走向的碰撞造山带等新认识。根据洋岩石圈残片和古陆缘岩浆岩的分布,把该区古生代构造单元划分为大兴安岭、阴山-燕山、小兴安岭、张广才岭和老爷岭等5个造山系及华北克拉通,简要介绍了不同造山系的地质特征。 相似文献
18.
阿尔金北缘红柳沟-拉配泉一带铜金矿床硫同位素特征及其意义 总被引:3,自引:0,他引:3
通过对阿尔金北缘地区铜金矿床的硫同位素研究, 结合矿床地质特征, 划分了区内矿床的成因类型, 认为主要有3类:似层状海相火山沉积型铜多金属矿床、韧性剪切带型(铜)金矿床、受裂隙控制的脉状岩浆热液型铜多金属矿床。结合区域构造演化特点, 探讨了矿床成因类型与区域构造演化阶段的关系, 认为区域成矿作用可分为3个阶段:第一阶段为早古生代早中期板块构造海底扩张作用时期, 形成以喀腊大湾为代表的海相火山沉积型铜多金属矿床; 第二阶段是早古生代晚期板块构造聚合碰撞作用时期, 形成以大平沟和红柳沟为代表的韧性剪切带型(动力变质热液型)(铜)金矿床; 第三阶段是早古生代末板块构造碰撞后的岩浆活动和偏脆性断裂构造活动时期, 形成以索尔库里北山和拉配泉为代表的受裂隙控制的岩浆热液型铜多金属矿床。从硫同位素特征、矿床成因类型及其与区域构造演化的关系上分析, 该区具有较好的铜金多金属矿床找矿远景。 相似文献
19.
作为全球三大成矿域之一,特提斯成矿域发育众多的世界级成矿带(矿床),例如,旁地德斯、萨汉德-巴兹曼、贾盖、玉龙、冈底斯成矿带等。为了进一步了解特提斯成矿域中新世斑岩铜矿的成因及成矿作用,本文对萨汉德-巴兹曼、贾盖和冈底斯铜矿带典型矿床的地质、地球化学、Sr-Nd-Pb数据进行对比分析,探讨含矿斑岩岩石成因、源区特征和构造环境,归纳其构造演化与其成矿作用过程。地球化学数据显示,这三个铜矿带中新世斑岩体总体显示钙碱性I型花岗岩的特征,具有埃达克岩亲和性。与冈底斯铜矿带相比较,萨汉德-巴兹曼铜矿带和贾盖铜矿带斑岩体显示出弧岩浆岩与埃达克岩过渡的地球化学特征,暗示其岩浆源区MORB质角闪榴辉岩或榴辉岩可能发生的较大程度的部分熔融。Sr-Nd-Pb同位素数据显示,这些含矿斑岩主要来源于受岩浆作用控制的壳幔混合物质,显示DUPAL异常。综合研究分析,认为这些含矿斑岩可能形成于岛弧造山带演化过程中,是洋壳俯冲消减和大陆碰撞过程中增厚下地壳部分熔融的结果。 相似文献
20.
东南亚地区位于全球特提斯成矿域、环太平洋成矿域与印度-澳大利亚成矿域的交汇地带。构造演化独特,先后经历了原-古-中-新特提斯增生造山、印度-欧亚陆陆碰撞造山、太平洋俯冲等多期次构造-岩浆事件,形成了多条火山弧带、蛇绿混杂带以及同碰撞和后碰撞岩浆岩带。本文在总结前人大地构造研究成果基础上,将东南亚地区划分为6个一级构造单元、32个二级构造单元和57个三级构造单元。伴随着原-古-中-新特提斯构造演化、印度-欧亚大陆碰撞、太平洋俯冲等多期次构造域事件,以构造单元划分为基础,将东南亚地区划分为3个一级成矿域,6个二级成矿省,21个三级成矿带,并结合构造演化初步探讨了主要成矿事件。 相似文献