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1.
湖南响涛源锰矿位于湘中桃江成锰盆地。盆地内发育一组NNW向同沉积断裂,形成了一系列断陷槽,控制了沉积岩相的分布,其中黑色页岩、含锰灰岩、碳酸锰矿为成矿最佳的岩性组合。矿石的化学组分多样,Co、Ni、Pb、Mo和Ba等丰度较高,Co/Ni、SiO2/Al2O3、(Fe+Mn)/Ti、Al/(Fe+Mn+Al)、Fe/Ti比值以及Co/Zn-(Cu+Ni+Co)和Fe-Mn-(Cu+Ni+Co)图解揭示锰矿成矿过程中有海底热水的参与;稀土元素配分模式、Ce、Eu异常表示锰矿形成于被动大陆边缘环境,并具有热水沉积特征;碳同位素结果显示出富集碳的轻同位素的特征,反映了响涛源锰矿成矿过程中深部热水沉积及生物作用的特征;氧同位素计算古温度为湘中响涛源锰矿床的低温热水沉积成因提供了有利的佐证。 相似文献
2.
湘中湘潭盆地大塘坡组锰矿是湖南重要的锰矿基地。盆地内发育一组NNE向同沉积断裂,形成了一系列凹陷带(断陷槽),控制了沉积岩相的分布,锰矿主要产于盆地凹陷带的黑色页岩夹碳酸锰矿微相内。矿石中Co、Zn、Pb、Mo和Ba等元素丰度较高,Co/Ni、SiO2/Al2O3、(Fe+Mn)/Ti、Al/(Fe+Mn+Al)比值以及Co/Zn-(Cu+Ni+Co)和Fe-Mn-(Cu+Ni+Co)图解都揭示锰矿成矿过程中有海底热水的参与;稀土元素分布模式、Ce、Eu异常表示锰矿形成于被动大陆边缘环境,并具有热水沉积特征;碳同位素结果显示出富集碳的轻同位素的特征,反映了湘中地区锰矿中碳同位素热水沉积的特征;氧同位素计算古温度为湘中地区锰矿的低温热水沉积成因提供了有利的佐证。 相似文献
3.
贵州二叠系茅口组顶部锰矿沉积特征及矿床成因研究 总被引:4,自引:0,他引:4
通过对遵义、纳雍营盘等地含锰岩系沉积特征及沉积地球化学特征研究,结果表明,锰矿体形态主要以层状、似层状、透镜状、脉状产出,具有角砾状构造、递变层理等,常夹硅质岩和凝灰岩,具有热水喷流沉积构造特征。锰矿层位于玄武岩之下,夹于茅口组灰岩顶部,说明锰矿成矿在玄武岩喷发之前。含锰岩系中的矿物组合有浸染状黄铜矿,黄铁矿,重晶石,天青石,菱锰矿、钙菱锰矿、锰方解石、黄铜矿、蓝铜矿、褐铁矿、绿泥石、石英及其他碳酸盐岩矿物等,这些矿物组合与热水沉积矿物组合类似。对含锰岩系进行微量元素、稀土元素、碳同位素分析测试表明,含锰岩系富集As、Co、Cu、Cr、Mo、Ni、Pb、U和V等元素,Fe/Ti、(Fe+Mn)/Ti及Al/(Al+Fe+Mn)比值,Fe-Mn-(Cu+Co+Ni)×10三角图解等均显示锰矿属于热水沉积成因。锰矿石碳同位素值δ~(13) C介于+4.17‰~-18.53‰,氧同位素δ~(18) O介于-6.98‰~-10.05‰显示,碳同位素组成具有热水沉积特征。含锰岩系稀土配分曲线与峨眉山玄武岩稀土配分曲线类似,表明锰矿成矿物质来源与峨眉地幔热柱密切相关。 相似文献
4.
李家湾锰矿床是黔东松桃地区较为典型的"大塘坡式"锰矿床之一,也是近年来在该地区新发现的一个大型隐伏锰矿床,是杨立掌锰矿体在外围的深部延伸。笔者在野外地质调查的基础上,重点对该矿床的锰矿石及其围岩开展系统的地质和地球化学特征研究,探讨锰矿床的成矿物质来源、成因和成矿环境。该矿床主要的矿石形态有块状、条带状、花斑状3种,主要锰矿物为菱锰矿和钙菱锰矿。锰矿层中MnO、CaO、MgO含量较高,TiO_2、Al_2O_3、K_2O、Na_2O含量较低,含锰岩系富集Rb、Ba、Th、Cs、Zr、Ga等元素;SiO_2/Al_2O_3值显示其物质来源并非正常的陆源,通过Al/(Al+Fe+Mn)、(Fe+Mn)/Ti、Fe/Ti、Y/Ho、Nb/Ta、U/Th值,Fe-Mn-(Cu+Co+Ni)×10图解表明,锰矿具有热水沉积特征;Mn/Fe、Sr/Ba、V/(V+Ni)值揭示锰矿沉积环境为浅海、还原环境。稀土元素总量较高,轻稀土富集,含锰岩系Eu、Ce的异常、La/Ce值、ΣREE和ΣHREE总量反映锰矿沉积过程受热水活动影响,大地构造环境处于被动大陆边缘。由此表明,李家湾锰矿形成于较强的还原环境,锰矿形成是由热水沉积和正常沉积的混合作用形成,属于热水沉积成因。 相似文献
5.
【研究目的】锰矿作为一种金属矿产,应用于国民经济的多个领域。黔阳成锰盆地是中国重要的锰矿基地,其锰矿床类型为赋存于南华系大塘坡组地层中的一套海相碳酸锰矿床,资源储量大,开采历史长,但其成矿模式尚不清楚。【研究方法】本文以锰矿集中分布的湖南靖州地区为例,在野外剖面实测、地球化学数据分析的基础上,通过Co/Zn-(Cu+CO+Ni)图解、Fe-Mn-(Cu+CO+Ni)×10三端元判别图解、(Zr+Ce+Y)×100-(Cu+Ni)×15-(Fe+Mn)/4三角图解以及Al/(Fe+Mn+Al)比值、(Fe+Mn)/Ti比值和Fe/Ti比值等一系列判别指标分析了锰矿中锰元素的来源。利用锰矿石的V/Cr、Th/U、Ce/La以及Ce标志分析了锰矿石沉积时的古环境。【研究结果】黔阳成锰盆地靖州地区锰矿石中锰元素主要来源于海底热液系统,沉积时水体处于贫氧—缺氧环境,前期形成的断裂带为锰元素的运移提供了通道。【结论】黔阳成锰盆地靖州地区锰矿石是冰期由地壳深部经众多断裂带上升到海盆中的锰元素,在间冰期与海水中的CO23-相结合富集而成。 相似文献
6.
扬子陆块北缘的鄂东北地区是湖北省沉积变质型锰矿集中区,发育了广水—黄陂—蕲春SEE-NWW向元古代沉积变质锰矿带,锰矿赋存于新元古界红安岩群中。本文以鹰咀山锰矿床、四方山锰矿床及孙冲锰矿床为例,分析研究其矿物学特征和地球化学特征,以便为总结该区锰矿床成矿环境及成矿物质来源提供帮助。研究表明,锰矿石矿物主要为菱锰矿、软锰矿、硬锰矿、黑锰矿、锰铝榴石等;矿石化学组分多样,Co、Ni、Zn、Sr、Ba、U等元素相对富集。锰矿石的w(Th)/w(U)、w(V)/w(Cr)值反映锰矿形成于弱氧化-还原的沉积环境;w(SiO2)/w(Al2O3)、w(Fe+Mn)/w(Ti)、w(Fe)/w(Ti)、w(Al)/w(Fe+Mn+Al)、w(Y)/w(Ho)、w(La)/w(Ce)特征值,以及w(SiO2)—w(Al2O3)图解、w(Fe)/w(Ti)—w(Al)/w(Fe+Mn+Al)图解,均反映其成矿过程中有热水物质参与。因此,鄂东北地区的沉积变质型锰矿形成于弱氧化-还原性沉积环境,有热水(液)活动参与成矿作用并提供了丰富的物质来源。 相似文献
7.
贵州松桃道坨锰矿含锰岩系地球化学特征
和沉积环境分析 总被引:18,自引:0,他引:18
道坨锰矿床是贵州锰矿整装勘查过程中新发现的全隐伏超大型锰矿床,其含锰岩系赋存于南华系大塘坡组第一段底部黑色页岩中,呈层状、似层状、透镜状产出。对含锰岩系主量及微量元素地球化学特征分析:其V/(V+Ni)、V/(V+Cr)、V/Cr、Ce/La值,及U、V、Ni、Mo等氧化还原敏感元素的富集程度显示其形成于缺氧环境。含锰岩系富集As、Mo、Ag、Sb,及Al/(Al+Fe+Mn)、(Fe+Mn)/Ti、Co/Zn值均显示热水沉积物特征,且在(Cu+Ni+Co)×10—Fe—Mn、Co/Zn—(Cu+Ni+Co)关系图解中,岩矿样品投影点均落在热水沉积区内,反映了热水作用对锰的富集和成矿影响甚重。此外,Al2O3/(Al2O3+Fe2O3)、Al/(Al+Fe)、Al/(A1+Fe+Mn)、(La/Ce)N值及(K2O+NaO2)—SiO2、La/Ce—Al2O3/(Al2O3+Fe2O3)图解指示含锰岩系形成于被动大陆边缘背景。 相似文献
8.
渝东南“大塘坡式”锰矿形成于Marinoan冰期和Sturtian冰期的间冰期,是在扬子地块东南缘“堑- 垒”式陆缘沉积盆地背景上发育的多阶段、多成因沉积型菱锰矿,成锰期明显受大地构造活动、岩浆作用(火山作用)、“黑烟窗”等热事件影响;且与Rodinia超大陆裂解导致的裂谷盆地成矿作用关系密切。冰期转换、裂谷盆地作用及锰成矿作用三者间的耦合关系明显,并呈现显著相关的沉积地球化学特征。对渝东南不同矿区、不同产状的锰矿及其围岩样品进行的相关Mn/Fe、(Fe+Mn)/Ti、Ba/Sr、U/Th、Y/Ho、SiO2/Al2O3、Al/(Al+Fe+Mn)比值分析和Co/Zn- (Co+Ni+Cu)、La/Yb- ΣREE、La/Yb- Ce/La、lgTh- lgU、La- Ce、lgTh- lgU、(Cu+Ni+Co)×10- Fe- Mn等图解分析,均指示成锰物质的深部来源,成矿受热水影响显著;此外,样品富集As、Sb、Sr、Mo、Ag、Ba、Th、U等热水沉积标识元素。锰矿样品稀土总量平均值为159×10-6,明显高于正常海相沉积阶段形成的菱锰矿稀土总量(19×10-6)。锰矿样品V/(V+Ni)、V/Cr、Ce/La、lgCe/Ce*指示锰矿形成于缺氧环境;Mo、U等氧化- 还原敏感元素富集。成锰盆地的氧化 还原条件制约着锰矿的形成,且成矿过程是沉积、成岩、后生不同阶段矿物相转化的综合结果。锰矿成矿可分为三阶段:第一阶段为沉积期分层性海水上部氧化带MnO2沉淀物富集;第二阶段为沉积期周期性短暂的富氧底流将MnO2沉淀物带入盆地底部沉积;第三阶段为准同生 成岩期,MnO2在缺氧环境中的厌氧细菌或硫酸盐细菌作用下还原为Mn2+,同时产生OH-使底层海水或海底沉积物孔隙流体碱度升高,形成原生菱锰矿及(含)锰碳酸盐沉积物,经成岩作用进一步形成菱锰矿。 相似文献
9.
新疆西昆仑奥尔托喀讷什锰矿地质、地球化学及成因 总被引:2,自引:1,他引:1
近年来,西昆仑玛尔坎苏地区富锰矿找矿取得重大突破,新发现奥尔托喀纳什等大型锰矿床。该矿床层位稳定,厚度较大,Mn平均品位达35%以上,为中国最富的碳酸锰矿床,属于典型的海相沉积型锰矿床。锰矿体主要赋存于晚石炭世喀拉阿特河组地层中,该组岩性为一套浅海碳酸盐岩台地相沉积建造组合,可划分为台内浅滩、潮坪、开阔台地、局限台地等4个相类型。成矿分为三个期次,第一期为沉积成岩成矿期,矿石矿物由菱锰矿、锰方解石、硼锰矿组成;第二期为热液改造期,形成锰镁绿泥石、红锰矿、硫锰矿、锰方解石(脉)、重结晶菱锰矿、蔷薇辉石及滑石、石膏等;第三期为表生氧化期,发育少量软锰矿、水锰矿、硬锰矿等。锰矿石具有较低的Fe/Mn比值、V/(V+Ni)比值和强烈的Ce正异常,表明Mn是在氧化环境下,以氧化物或氢氧化物的形式沉积富集。含锰岩系顶、底板岩石中含较多成熟度较差的中酸性火山岩岩屑,以及具有较低Al/(Al+Fe+Mn)、Y/Ho、Co/Ni比值的锰矿石,说明其成矿物质来源于海底热水活动。奥尔托喀纳什锰矿具有"内源外生"的特点,锰矿石及菱锰矿具有负的δ~(13)C值(-23.3‰~-13.2‰),表明锰矿经历了先成锰氧化物或氢氧化物、再被还原转化成菱锰矿的过程。此外,有机质所导致的更为强烈的还原作用是本矿床富锰矿形成的重要机制。后期构造叠加致使矿体发生变形,矿体形态受褶皱控制。矿石受到强烈改造,形成锰镁绿泥石、红锰矿、蔷薇辉石等,晚期经历氧化淋滤作用形成软锰矿、水锰矿等。 相似文献
10.
Ga是一种典型的稀有分散元素,主要产于铝土矿、闪锌矿及煤矿之中。最近,在广西东平地区下三叠统北泗组碳酸锰矿床中发现Ga高异常含量,w(Ga)介于5.16×10~(-6)~82.80×10~(-6)之间,平均为33.76×10~(-6),达到了Ga工业品位标准;锰矿层和围岩中w(Ga)平均分别为46.40×10~(-6)、19.31×10~(-6),高于国内外已报道的大部分锰矿床。文中根据北泗组碳酸锰矿床地球化学特征,揭示了该锰矿床为热水沉积;同时,结合现代大洋铁锰沉积有关Ga的最新报道,提出北泗组碳酸锰矿床中Ga的赋存与含锰矿物密切相关,其来源与海底热液活动有关。最后,文中还利用Mn/Fe-Ga、Co-Ga关系图判别了古代铁锰沉积的成因类型。 相似文献
11.
贵州水城二叠系茅口组含锰岩系地质地球化学特征与锰矿成因分析 总被引:7,自引:1,他引:6
贵州水城二叠系茅口组内发现新锰矿。通过对含锰岩系的地质地球化学研究,其富集Zn,Ni,As,Sb,Sr,Ba,Ga,Ag,V,U元素;锰含量较高层位,Th/U比值小于1,锰含量较低层位,Th/U比值往往高达4~5。Co/Ni比值小于1。含锰岩石的(Fe+Mn)/Ti均大于47,高于20,特别是含锰高的岩石,其(Fe+Mn)/Ti值在300以上。含锰岩石的Al/(Al+Fe+Mn)均远远低于0.35,一般为小于0.02。稀土配分模式与峨眉山玄武岩相似,∑REE较高,LREE/HREE值偏低等特征。根据锰岩系地球化学和区域构造特征分析,水城二叠系茅口组含锰岩系属于热水喷流沉积的产物。 相似文献
12.
Koichiro Fujinaga Tatsuo Nozaki Takazumi Nishiuchi Kiyoko Kuwahara Asuhiro Kato 《Resource Geology》2006,56(4):399-414
Abstract. Major and trace element contents are reported for Permian manganese ore and associated greenstone from the Ananai manganese deposit in the Northern Chichibu Belt, central Shikoku, Japan. The manganese deposit occurs between greenstone and red chert, or among red chert beds. Chemical compositions of manganese ore are characterized by enrichments in Mn, Ca, P, Co, Ni, Zn, Sr and Ba, and negative Ce and positive Eu anomalies relative to post-Archean average Australian Shale (PAAS). Geochemical features of the manganese ore are similar to those of modern submarine hydrother-mal manganese deposits from volcanic arc or hotspot setting. In addition, geochemical characteristics of the greenstone closely associated with the Ananai manganese deposit are analogous to those of with-in plate alkaline basalt (WPA). Consequently, the Ananai manganese deposit was most likely formed by hydrothermal activity related to hotspot volcanism in the Panthalassa Ocean during the Middle Permian. This is the first report documenting the terrestrially-exposed manganese deposit that was a submarine precipitate at hotspot. 相似文献
13.
广西东平-足荣大型锰矿床位于桂西南锰矿带上,是广西重要的锰矿富集区。其含矿地层为三叠系北泗组,是一套以硅-泥-灰为主浅海台盆相含锰碳酸盐岩沉积,含锰矿物主要为钙菱锰矿、锰方解石和锰白云石。本文对矿区锰矿层顶部的沉凝灰岩及含锰岩系开展了详细的岩石学、岩石地球化学和锆石U-Pb年代学研究,进而对锰矿成矿时代、成因、沉积环境、沉凝灰岩源区和大地构造背景进行了探讨。锆石SHRIMP U-Pb定年结果显示,3件沉凝灰岩样品的锆石呈自形-半自形板柱状,发育良好的岩浆锆石振荡环带结构。~(206) Pb/~(238)U年龄加权平均值分别为250.8±2.1Ma(MSWD=0.98)、250.6±2.2Ma(MSWD=0.49)和243.6±2.3Ma(MSWD=0.44)。进一步限定了"东平"式锰矿的成矿时代为早-中三叠世(不晚于241~246Ma的范围内)。沉凝灰岩的构造环境判别图解及微量、稀土元素特征显示其岩浆可能形成于与俯冲消减作用相关的碰撞-弧相关或活动大陆边缘相关背景,推测东平-足荣锰矿的形成可能受到广西凭祥-东兴火山作用的影响。含锰岩系的U、V和Mo元素含量及U/Th、V/Cr、V/(V+Ni)、Ni/Co 比值显示东平-足荣锰矿形成于氧化-次氧化的沉积环境。logU-logTh、Fe/Ti-Al/(Al+Fe+Mn)图解及微量元素Ba含量、Ba/Sr值均指示成矿作用受到热水作用的影响。综合矿床地质研究,东平-足荣锰矿形成于弧后盆地拉张构造背景中,锰成矿受同期火山及海底热液作用影响,水体沉积环境为氧化-次氧化条件。 相似文献
14.
J. Ostwald 《Mineralium Deposita》1992,27(4):326-335
The Mary Valley manganese deposits exhibit mineralogy and textures characteristic of at least four parageneses. The deposits consist mainly of isolated occurrences of braunite, together with a number of lower and higher valency manganese oxides, and manganese silicates, in bedded radiolarian cherts and jaspers of Permian age. The parageneses are: (a) Braunite — quartz (primary), (b) Braunite — hausmannite — spessartine — tephroite — quartz (metamorphic). (c) Hydrated manganese silicates — barite — braunite — hausmannite (hydrothermal veins), (d) Tetravalent manganese oxides (pyrolusite, cryptomelane, manjiroite, nsutite) (supergene). The primary mineralisation is interpreted as the result of the geochemical separation of Mn from Fe in a submarine exhalative system, and the precipitation of Mn as oxide within bedded radiolarian oozes and submarine lavas. During diagenesis this hydrothermal manganese oxide reacted with silica to produce primary braunite. The later geological of evolution of this volcanogenicsedimentary deposit involved metamorphism, hydrothermal veining by remobilised manganese, and supergene enrichment. 相似文献
15.
建德铜矿床的海底喷流沉积成因 总被引:2,自引:0,他引:2
建德铜矿床是浙江西部多金属成矿带中一个引人瞩目的重要矿床。它产于中石炭统底部伴有火山岩、硅质岩和碧玉岩的白云岩中。整合块状矿体之下有一筒状矿化蚀变带。其成分以Cu>Zn>Pb为特征。根据矿床地质、地球化学特征以及近年来研究所获得资料,认为该矿床属海底喷流沉积成因 相似文献
16.
The Sjögruvan deposit is one of the Långban-type Fe-Mn oxide deposits hosted by marble interbeds within Svecofennian metavolcanic rocks in the Bergslagen region, central Sweden. Mineralogical and geochemical studies have been carried out to clarify the premetamorphic origin of this type of deposit, which is set apart from most other Mn mineralizations by a significant enrichment in Ba, As, Sb, Pb, W and Be contained by various oxyminerals. The principal ore types at Sjögruvan are (1) hematite+quartz-magnetite, (2) hausmannite+calcite+tephroite and (3) braunite+celsian+phlogopite. The Mn ores are compositionally akin to modern Mn deposits formed by submarine hydrothermal processes (with a high Mn/Fe ratio and low contents of Co, Ni, Th, U and REE) and likely owe their existence to similar mechanisms of formation. Pb isotope data indicate that the metal source and timing of deposition is similar to the major stratabound base-metal and iron deposits in Bergslagen. All the key elements have been leached from the local felsic volcanic units and were deposited on the sea floor; the excellent Mn-Fe separation occurred in an Eh-pH gradient that essentially corresponded to the mixing zone of hydrothermal solutions and seawater. The braunite ore is chemically distinct from the hausmannite ore, with a high concentration of refractory elements (Al, Ti, Zr) and a positive Ce anomaly, which indicate a detrital/hydrogenetic contribution to its protolith. Carbon isotope ('13C) values around 0 (relative PDB) suggest that carbonates in the deposit formed directly from seawater. 相似文献
17.
西秦岭寒武系硅岩建造喷流沉积作用与矿质聚集 总被引:3,自引:0,他引:3
硅岩建造是西秦岭拉尔玛-邛莫层控金矿床的含矿岩系。含矿层状硅岩呈块状、条带状、层纹状、多孔状和同生角砾状等,单层厚度一般为30m-200m。主要成分SiO2平均含量高达95.30%,其余为FeO、Fe2O3和有机炭等。硅质的Al/(Al+Fe+Mn)比值低于0.35(平均0.153)。硅岩中微量元素十分丰富,不仅含具基性、超基性特征的元素群(如Cu、Cr、Pt、Pd、Os等),而且含具酸性特征的元素群(如W、Mo、U等).硅岩中稀土以总量低(32.9×10^-4~100×10^-4)、δCe亏损为特征.经北美页岩标准化后.稀土含量随原于序数的增大而增大.硅岩的δ180值为l7.60‰ ~23.24‰,其形成温度约为7O℃~l18℃.硅岩的δ30Si值主要在+O.4%~+O.8%之间,硅岩的上述特点均显示其与喷流沉积作用有美.喷流沉积作用不仅形成了特殊的硅岩建造,而且也使金等元素在硅岩建造中发生了明显的聚集。 相似文献
18.
A. I. Brusnitsyn 《Geochemistry International》2013,51(8):623-645
The Parnok ferromanganese deposit is confined to the black shales of the western slope of the Polar Urals. The deposit area is made up of weakly metamorphosed terrigenous-carbonate rocks formed in a marine basin at a passive continental margin. Ore-bearing sequence is composed of coaliferous clayey-siliceous-calcareous shales comprising beds and lenses of pelitomorphic limestones, and iron and manganese ores. The iron ores practically completely consist of micrograined massive magnetite. The manganese ores are represented by lenticular-bedded rocks consisting of hausmannite, rhodochrosite, and diverse manganese silicates. With respect to relations between indicator elements (Fe, Mn, Al, Ti), the shales are ascribed to pelagic sediments with normal concentrations of Fe and Mn, the limestones correspond to metalliferous sediments, ferruginous sediments are ore-bearing sediments, while manganese rocks occupy an intermediate position. It was found that the concentrations of trace elements typical of submarine hydrothermal solutions (As, Ge, Ni, Pb, Sb, Zn, etc.) in both the ore types are in excess of those in lithogenic component. At the same time, the indicator elements of terrigenous material (Al, Ti, Hf, Nb, Th, Zr, and others) in the ores are several times lower than those in the host shales (background sediments). REE distribution patterns in iron ores show the positive Eu anomaly, while those in manganese ores, the positive Ce anomaly. In general, the chemical composition of the ores indicates their formation in the hydrothermal discharge zone. The peculiar feature of the studied object is the manifestation of hydrothermal vents in sedimentary basin without evident signs of volcanic activity. Hydrothermal solutions were formed in terrigenous-carbonate sequence mainly at the expense of buried sedimentation waters. The hydrothermal system was likely activated by rejuvenation of tectonic and magmatic processes at the basement of sedimentary sequences. Solutions leached iron, manganese, and other elements from sedimentary rocks and transported them to the seafloor. Their discharge occurred in relatively closed marine basin under intermittent anaerobic conditions. Eh-pH variations led to the differentiation of Fe and Mn and accumulation of chemically contrasting ore-bearing sediments. 相似文献
19.
The ore types of the Zhaokalong Fe-Cu deposit are divided into two categories: sulfide-type and oxide-type. The sulfide-type ore include siderite ore, galena-sphalerite ore and chalcopyrite ore, whereas the oxide-type ore include magnetite ore and hematite ore. The ore textures and structures indicate that the Zhaokalong deposit is of the sedimentary-exhalative mineralization type. Geochemical analyses show that the two ore types have a high As, Sb, Mn, Co and Ni content. The REE patterns reveal an enrichment of the LREE compared to the HREE. Isotopic analysis of siderite ore reveal that the δ13CPDB ranges from 2.01 to 3.34 (‰) whereas the δ18O SMOW ranges from 6.96 to 18.95 (‰). The fluid inclusion microthermometry results indicate that homogenization temperatures of fluid inclusions in quartz range from 131 to 181℃, with salinity values of 1.06 to 8.04 wt% NaCl eq. The mineralizing fluid therefore belongs to the low temperature - low salinity system, with a mineralizing solution of a CO2-Ca2+(Na+, K+)-SO42-(F-, Cl-)-H2O system. The geochemical results and fluid inclusion data provide additional evidence that the Zhaokalong deposit is a sedex-type deposit that experienced two stages of mineralization. The sulfide mineralization probably occurred first, during the sedimentary exhalative process, as exhibited by the abundance of marine materials associated with the sulfide ores, indicating a higher temperature and relatively deoxidized oceanic depositional environment. After the main exhalative stage, hydrothermal activity was superimposed to the sulfide mineralization. The later stage oxide mineralization occurred in a low temperature and relatively oxidized environment, in which magmatic fluid circulation was dominant. 相似文献