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1.
贵州省松桃县道坨超大型锰矿床的发现及其成因探讨 总被引:5,自引:0,他引:5
贵州省松桃县道坨锰矿床是新发现的一个超大型全隐伏锰碳酸盐矿床。文章阐述了该矿床的发现概况及基本的地质和地球化学特征,并应用锰矿石和含锰黑色页岩的元素和碳同位素地球化学特征对菱锰矿的形成机制提出了制约。道坨超大型锰矿床的发现是填图及对区域地质资料综合分析的结果。该矿床具有品位高、厚度大、呈层性好及展布广等特点。其锰矿石的主量元素特征为Al2O3、TiO2、Fe2O3含量较低,P2O5中等程度富集,MnO、MgO含量相对较高,Fe/Mn比值低。在微量元素方面,锰矿石显示出较为明显的Co富集,含锰黑色页岩则显示出较为明显的Co、Mo富集;在稀土元素方面,锰矿石具有较高的稀土元素总量,轻微的"帽式"稀土元素PAAS标准化配分模式及明显的Ce正异常,含锰黑色页岩的稀土元素总量与PAAS接近,其稀土元素PAAS标准化配分模式较为平坦,无Ce异常。碳同位素测试结果显示出菱锰矿富集碳的轻同位素,表明在菱锰矿形成过程中存在有机碳的参与。文章表明,道坨锰矿床内的锰是以氧化物或氢氧化物的形式沉淀,菱锰矿是在缺氧且富含有机物质的成岩环境中转化而成。 相似文献
2.
Takeru Moriyama Mruganka K. Panigrahi Dinesh Pandit Yasushi Watanabe 《Resource Geology》2008,58(4):402-413
The major, trace and rare earth element (REE) composition of Late Archean manganese, ferromanganese and iron ores from the Iron Ore Group (IOG) in Orissa, east India, was examined. Manganese deposits, occurring above the iron formations of the IOG, display massive, rhythmically laminated or botryoidal textures. The ores are composed primarily of iron and manganese, and are low in other major and trace elements such as SiO2, Al2O3, P2O5 and Zr. The total REE concentration is as high as 975 ppm in manganese ores, whereas concentrations as high as 345 ppm and 211 ppm are found in ferromanganese and iron ores, respectively. Heavy REE (HREE) enrichments, negative Ce anomalies and positive Eu anomalies were observed in post‐Archean average shale (PAAS)‐normalized REE patterns of the IOG manganese and ferromanganese ores. The stratiform or stratabound shapes of ore bodies within the shale horizon, and REE geochemistry, suggest that the manganese and ferromanganese ores of the IOG were formed by iron and/or manganese precipitation from a submarine, hydrothermal solution under oxic conditions that occurred as a result of mixing with oxic seawater. While HREE concentrations in the Late Archean manganese and ferromanganese ores in the IOG are slightly less than those of the Phanerozoic ferromanganese ores in Japan, HREE resources in the IOG manganese deposits appear to be two orders of magnitude higher because of the large size of the deposits. Although a reliable, economic concentration technique for HREE from manganese and ferromanganese ores has not yet been developed, those ores could be an important future source of HREE. 相似文献
3.
《Precambrian Research》2003,120(1-2):81-100
Knowledge of the formation conditions of Francevillian uranium and manganese ore deposits as well as natural fission reactors sheds light on the early evolution of the atmosphere between 1950 and 2150 Ma ago. The model explaining the formation of the Oklo uranium deposits suggests that at the time of sediment deposition in the Franceville basin 2150 million years ago, the oxygen deficient atmosphere would have inhibited uranium dissolution. Dissolution of uranium was only possible during later diagenesis, approximately 1950 Ma. Reduction reactions in the presence of hydrocarbons allowed precipitation of dissolved uranium to U4+, forming deposits with high enough uranium contents to trigger subsequent nuclear fission reactions. Such a model is in agreement with earlier suggestions that oxygen contents in atmosphere increased during a ‘transition phase’ some 2450–2100 Ma ago. The manganese deposits were formed before the uranium deposits, during the deposition of the black shales and very early diagenesis, and thus at a time when oxygen content in atmosphere was very low. Carbon isotopes data of organic matter show decrease of δ13C upward in the Francevillian series (−20 to −46% PDB) reflecting the high CH4 and low O2 contents in the atmosphere during sediment deposition. This favoured anoxic conditions during deposition of the basinal FB black shales and likewise the migration of Mn over long distances. The manganese precipitated first as Mn-oxides at the shallow edges of the Franceville basin, in photic zones, where photosynthetic organisms flourished. Mn-oxides were then reduced in the black shales forming Mn-carbonates when conditions became more reducing during transgression episodes and/or the first stages of burial. In the black shales, reducing conditions prevailed until recent weathering, allowing the good preservation of organic matter and the Mn deposits. The present-day alteration is responsible for the dissolution of Mn-carbonates and precipitation of Mn-oxides at the water table to form the high grade Mn ore (45–50% Mn). Development of photosynthesizing organisms, a volcanic source of the Mn, and favourable palaeogeography of the Francevillian basins are all important parameters for the formation of the Mn deposits. For the occurrence of the natural nuclear reactors, the age of 2.0 Ga is the main parameter that controls the abundance of fissile 235U and the critical mass. Before 2.0 Ga the 235U/238U ratio was sufficiently high for fission reactions to occur but conditions favourable for forming high grade uranium ores were not achieved. Then, after 2.0 Ga the increase of oxygen in the atmosphere commonly led to the formation of high grade uranium ores in which the 235U/238U ratio was too low to support criticality. 相似文献
4.
以湘西北民乐锰矿为例,基于矿区内钻孔信息对成矿期(大塘坡组下段)进行地层对比,由新分层信息及厚度变化分析沉积特征并建立三级、四级层序格架,由三级、四级层序尺度的古地貌变化分析成矿期沉积演变特征。主要认识有:1)民乐锰矿含矿层(大塘坡组下段)可根据岩性细分为下亚段1段(致密块状、密集条带状矿体夹黑色炭质页岩)、下亚段2段(黑色页岩夹薄层锰矿条带)、上亚段(黑色炭质页岩夹黄铁矿)。2)民乐锰矿的三级层序凝缩层体系域可划分为四个四级层序,其中第二、三层序菱锰矿发育较厚,形态以块状和密集条带状为主;第一、四层序菱锰矿发育薄,形态多为条带状。3)民乐锰矿沉积过程可以通过三级层序和四级层序两个研究尺度共同解释,三级层序尺度解释锰矿沉积过程,而四级层序尺度则揭示了多期不同形态、厚度锰矿的沉积过程。 相似文献
5.
The Nanhuan manganese deposits in the southeastern Yangtze Platform occur in the black shale series in the lower part of the Datangpo Formation. In order to constrain the genesis of the deposits, a detailed study was undertaken that involved field observations, major and trace element analyses, organic carbon analyses, and isotope analyses (C, O, S). The major findings are as follows. (1) The ore-bearing rock series, morphology of the ore bodies, and characteristics of ores in several deposits are similar. The ore minerals are rhodochrosite and manganocalcite. The gangue minerals are mainly quartz, feldspar, dolomite, and illite. Minor apatite and bastnaesite occur in the manganese ores. (2) The ores are enriched in Ca and Mg, whereas they are depleted in Si, Al, K, and Ti compared to wall rocks. The ores normalized to average Post-Archean Australian shale (PAAS) are enriched in Co, Mo, and Sr. The chondrite-normalized rare earth element (REE) patterns for ores and wall rocks are between those of typical hydrogenous and hydrothermal type manganese deposits. Additionally, the ores have positive Ce anomalies with an average Ce/Ce* of 1.23 and positive Eu anomalies with an average Eu/Eu* of 1.18 (normalized to PAAS). (3) The average content of organic carbon is 2.21% in the samples, and the average organic carbon isotopic value (δ13CV-PDB) is − 33.44‰. The average inorganic carbon isotopic value (δ13CV-PDB) of carbonates in Gucheng is − 3.07‰, while the values are similar in the other deposits with an average of − 8.36‰. The oxygen isotopic compositions (δ18OV-PDB) are similar in different deposits with an average of − 7.72‰. (4) The sulfur isotopic values (δ34SV-CDT) of pyrite are very high and range from + 37.9‰ to + 62.6‰ (average of 52.7‰), which suggests that the pyrite was formed in restricted basins where sulfate replenishment was limited. The sulfate concentrations in the restricted basins were extremely low and enriched in δ34S, which resulted in the very high δ34S values for the pyrite that formed in the manganese deposits. Therefore, a terrigenous weathering origin for manganese can be excluded; otherwise, the sulfate would have been introduced into the basins together with terrigenous manganese, which would have decreased the δ34S values of pyrites. The manganese, which originated from hydrothermal processes, was enriched in the restricted and anoxic basins, and then, it was oxidized to manganese oxyhydroxide in the overlying oxic waters whereby the products precipitated into the sediments. The manganese oxyhydroxide in the sediment was then reduced to Mn2 + and released to the pore waters during the process of diagenesis. Some organic carbon was oxidized to CO32 −, which made the depletion of 13C in manganese carbonates. Therefore, we suggest that the Nanhuan manganese deposits are hydrothermal–sedimentary/diagenetic type deposits. 相似文献
6.
Abstract. Several meso‐scale manganese ore bodies, scattered within Jone's horse‐shoe shaped synclinorium, in Bonai‐Keonjhar region of north Orissa are well known in the mineral map of India. Different grades of manganese ores are being exploited from this region by various agencies over a few decades. However, deceptive nature of ore bodies and complexity in control of mineralisation greatly confuse the exploration geologists for evaluation of these resources. In a recent study, the authors have classified Mn‐ore bodies of this region into three broad categories such as stratiform, stratabound (‐replacement) and lateritoid types based on mode of occurrence and their other chemical characteristics. Mn‐ore bands occur in close association with BIF and iron ores. Volcaniclastic shale in large geographic extension encloses these ore bodies. In the stratiform category of ore bodies (BMnF, analogous of BIF), manganese and shale bands, in variables thickness, alternate with each other and extend to a great depth. Such ore bodies generally constitute marginal to low‐grade ores, are characterised by low Mn/Fe ratio (~2) and have relatively lower abundance of trace (1500 to 2500 ppm) and relatively higher REE constituents. The stratabound‐replacement types of ore bodies are of intra‐stratal nature, occurring within tuffaceous shale. These are mostly shear‐controlled ore bodies extending along a zone of certain width. Increase in average Mn/Fe ratio (~6) and trace content (5000 to 8500 ppm) by 5 to 2.5 order of magnitude respectively or more above stratiform category are characteristic of these deposits. The lateritoid ore bodies have limited depth persistency. Such deposits are usually very low in Mn/Fe ratio (<1), trace (<2000 ppm) and REE contents. Different methods of exploration techniques are suggested for various categories of Mn‐ore bodies. In this context, the above findings would be the database for the exploration geologists to evaluate the potential of newer/existing Mn‐ore resources in this part of north Orissa. 相似文献
7.
贵州从江-黎平地区锰矿产于南华系大塘坡组第一段黑色岩系中。通过对从江-黎平地区开展地质调查工作,查明该区含锰岩系分布于朝里向斜及寨柳向斜,区内两个已知矿床八当锰矿和高增锰矿即位于朝里向斜。文章系统阐述了从江-黎平地区锰矿成矿地质背景、含锰岩系特征、锰矿床地质特征,对该区南华纪大塘坡期锰矿成因进行了探讨研究,并总结了区内锰矿成矿规律,在此基础上,结合野外地质调查成果,对该区锰矿找矿潜力进行了分析,认为朝里向斜南部具一定找矿潜力。 相似文献
8.
为分析贵州遵义二叠纪锰矿的沉积环境,对谢家坝锰矿床进行常量元素、微量和稀土元素地球化学研究。研究认为:谢家坝锰矿赋存于茅口组顶部含锰岩系中,可分为下矿层豆状、角砾状菱锰矿、似层状菱锰矿,以及上矿层碎屑状、块状菱锰矿的二元结构矿石类型组合,可广泛代表遵义锰矿的矿石特征。谢家坝锰矿上下矿层之间主量元素和稀土元素含量差异较大,常量元素SiO2、TiO2、S、Fe2O3含量上矿层均大于下矿层,MnO、MgO与 Al2O3之间均呈负相关关系;上矿层Fe/Mn值较高,属高Fe低P型锰矿,而下矿层Fe/Mn值较低,属中低Fe低P型锰矿。上矿层稀土元素PAAS标准化配分后呈现较明显的重稀土亏损、弱的轻稀土富集、右倾配分的特征,具有弱的Ce正异常,类似海底铁锰结核稀土元素特征;下矿层呈现弱的中稀土富集,轻、重稀土亏损,弱的帽式分配特征,具明显的Ce负异常,类似典型深部海水沉积稀土元素特征。微量元素Th/U、Ni/Co、V/Cr、V/(V+Ni)、AU等沉积环境古氧相分析指标和稀土元素PAAS标准化配分模式指示,谢家坝锰矿下矿层是在贫氧-厌氧条件下Mn2+与CO32-直接形成菱锰矿,上矿层在常氧-贫氧环境下Mn3+、Mn4+以氧化物或氢氧化物形式沉淀。 相似文献
9.
为了分析湘西南南华系大塘坡组照洞锰矿的沉积环境,对照洞锰矿床进行了岩石学和地球化学研究.分析认为:照洞锰矿赋存于大塘坡组底部碳酸锰层中,包括条纹状菱锰矿和块状菱锰矿两种矿石类型.湘西南照洞锰矿的常量元素TiO2、SiO2、K2O、Fe2O3、S与Al2O3之间呈现良好的正相关关系,CaO、MgO、MnO、P2O5和Al2O3之间呈负相关关系,常量元素之间的相关性与黔东、湘西的典型锰矿之间存在一致性,反映这些锰矿可能具有相似的成矿背景.照洞锰矿的Fe/Mn值低,Th/U、Ni/Co、V/Cr、V/(V+Ni)等沉积环境古氧相的指标显示,湘西南照洞锰矿形成时的水体处于常氧-贫氧的条件下.湘西南照洞锰矿稀土元素总量较高,PAAS标准化稀土元素配分模式呈现轻、重稀土亏损,中稀土富集的特征,具有弱的Ce正异常,类似现代海底铁锰结核的稀土元素配分特征. 相似文献
10.
Abstract. Chemistry and sulfur isotopes are analyzed for a series of rocks in the chert‐dominant sequence around the stratiform manganese ore deposit of the Noda‐Tamagawa mine in the northern Kitakami Terrane, northeast Japan. The sequence is litholog‐ically classified into six units in ascending order: lower bedded chert, lower black shale, massive chert, manganese ore, upper black shale, and upper bedded chert. The rocks around the manganese ore deposit exhibit anomalous enrichment in Ni (max. 337 ppm), Zn (102) and U (30) in the upper part of lower bedded chert, Mo (122), Tl (79) and Pb (33) in the lower black shale, MnO, Cu (786) and Co (62) in the manganese ore, and As (247) and Sb (17) in the upper black shale. The aluminum‐normalized profiles reveal zonal enrichment of redox‐sensitive elements around the manganese bed: Zn‐Ni‐Fe‐Mo‐U(‐Co), Tl‐Pb(‐Mo), Mn‐Fe‐Cu‐V‐Cr‐Co(‐Zn) and As‐Sb in ascending order. The uppermost part of the lower bedded chert and black shale exhibit negative Ce/Ce* values, whereas the massive chert, manganese ore and lower part of the upper bedded chert display positive values. The isotopic δ34S values are 0±6 % in the lower part of the lower bedded chert, ‐19 to ‐42 % in the upper part of the lower bedded chert, ‐36 to ‐42 % in the lower black shale, ‐28 to ‐35 % in the massive chert, manganese ore and upper black shale, and ‐23±5 % in the upper bedded chert. Thus, there is a marked negative shift in δ34S values in the lower bedded chert, and an upward‐increasing trend in δ34S through the manganese ore horizon. The present data provide evidence for a change in the paleoceanographic environmental resulting from inflow of oxic deepwater into the stagnant anoxic ocean floor below the manganese ore horizon. This event is likely to have triggered the precipitation of manganese oxyhydroxides. The redistribution of redox‐sensitive elements through the formation of metalliferous black shale and manganese carbonate ore may have occurred in association with bacterial decomposition of organic matter during early diagenesis of initial manganese oxyhydroxides. 相似文献
11.
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
12.
湖南省锰矿资源丰富,类型多样,沉积型锰矿是最重要的类型,主要沉积成锰期集中在早南华世大塘坡期、中奥陶世烟溪期及晚二叠世孤峰期。通过对三个主要成锰期代表性锰矿石电子探针分析显示,三个主要成锰期所成锰矿床,矿石组分类似,组成矿石的锰矿物主要为锰的碳酸盐,包括菱锰矿、钙菱锰矿、镁菱锰矿、锰白云石、锰方解石等。三个主要成锰期代表性锰矿石及地层稀土元素地球化学标准化参数与配分模式显示,各成矿期含锰地层与锰矿石之间无显著差异,暗示了它们是相似的沉积环境下形成的产物,为正常沉积与热水沉积的复合。一方面,各成矿期岩、矿石稀土元素总量中等偏高,表现为正常沉积物的稀土元素特征。另一方面,在北美页岩标准化配分曲线上,呈现出水平或重稀土相对富集的左倾配分曲线,Ce的负异常,又是典型热水沉积成因呈现出的稀土元素地球化学特征。δCe异常特征,指示了成锰作用处于波动的缺氧还原/氧化沉积环境。 相似文献
13.
Sedimentary manganese metallogenesis in response to the evolution of the Earth system 总被引:5,自引:0,他引:5
Supriya Roy 《Earth》2006,77(4):273-305
The concentration of manganese in solution and its precipitation in inorganic systems are primarily redox-controlled, guided by several Earth processes most of which were tectonically induced. The Early Archean atmosphere-hydrosphere system was extremely O2-deficient. Thus, the very high mantle heat flux producing superplumes, severe outgassing and high-temperature hydrothermal activity introduced substantial Mn2+ in anoxic oceans but prevented its precipitation. During the Late Archean, centered at ca. 2.75 Ga, the introduction of Photosystem II and decrease of the oxygen sinks led to a limited buildup of surface O2-content locally, initiating modest deposition of manganese in shallow basin-margin oxygenated niches (e.g., deposits in India and Brazil). Rapid burial of organic matter, decline of reduced gases from a progressively oxygenated mantle and a net increase in photosynthetic oxygen marked the Archean-Proterozoic transition. Concurrently, a massive drawdown of atmospheric CO2 owing to increased weathering rates on the tectonically expanded freeboard of the assembled supercontinents caused Paleoproterozoic glaciations (2.45-2.22 Ga). The spectacular sedimentary manganese deposits (at ca. 2.4 Ga) of Transvaal Supergroup, South Africa, were formed by oxidation of hydrothermally derived Mn2+ transferred from a stratified ocean to the continental shelf by transgression. Episodes of increased burial rate of organic matter during ca. 2.4 and 2.06 Ga are correlatable to ocean stratification and further rise of oxygen in the atmosphere. Black shale-hosted Mn carbonate deposits in the Birimian sequence (ca. 2.3-2.0 Ga), West Africa, its equivalents in South America and those in the Francevillian sequence (ca. 2.2-2.1 Ga), Gabon are correlatable to this period. Tectonically forced doming-up, attenuation and substantial increase in freeboard areas prompted increased silicate weathering and atmospheric CO2 drawdown causing glaciation on the Neoproterozoic Rodinia supercontinent. Tectonic rifting and mantle outgassing led to deglaciation. Dissolved Mn2+ and Fe2+ concentrated earlier in highly saline stagnant seawater below the ice cover were exported to shallow shelves by transgression during deglaciation. During the Sturtian glacial-interglacial event (ca. 750-700 Ma), interstratified Mn oxide and BIF deposits of Damara sequence, Namibia, was formed. The Varangian (≡ Marinoan; ca. 600 Ma) cryogenic event produced Mn oxide and BIF deposits at Urucum, Jacadigo Group, Brazil. The Datangpo interglacial sequence, South China (Liantuo-Nantuo ≡ Varangian event) contains black shale-hosted Mn carbonate deposits. The Early Paleozoic witnessed several glacioeustatic sea level changes producing small Mn carbonate deposits of Tiantaishan (Early Cambrian) and Taojiang (Mid-Ordovician) in black shale sequences, China, and the major Mn oxide-carbonate deposits of Karadzhal-type, Central Kazakhstan (Late Devonian). The Mesozoic period of intense plate movements and volcanism produced greenhouse climate and stratified oceans. During the Early Jurassic OAE, organic-rich sediments host many Mn carbonate deposits in Europe (e.g., Úrkút, Hungary) in black shale sequences. The Late Jurassic giant Mn Carbonate deposit at Molango, Mexico, was also genetically related to sea level change. Mn carbonates were always derived from Mn oxyhydroxides during early diagenesis. Large Mn oxide deposits of Cretaceous age at Groote Eylandt, Australia and Imini-Tasdremt, Morocco, were also formed during transgression-regression in greenhouse climate. The Early Oligocene giant Mn oxide-carbonate deposit of Chiatura (Georgia) and Nikopol (Ukraine) were developed in a similar situation. Thereafter, manganese sedimentation was entirely shifted to the deep seafloor and since ca. 15 Ma B.P. was climatically controlled (glaciation-deglaciation) assisted by oxygenated polar bottom currents (AABW, NADW). The changes in climate and the sea level were mainly tectonically forced. 相似文献
14.
《International Geology Review》2012,54(13):1673-1690
ABSTRACTEconomically the most important iron deposits of Turkey occur as: (1) skarn-hosted (SH)-type ore deposits, occurring along the contacts between syenitic-monzonitic intrusives and limestone or serpentine; (2) vein-type deposits, found between the serpentine and limestone (SLH); or (3) ore deposits that are entirely within the limestone (LH).Elemental associations are defined as: Fe+Ni+Cr+U+Bi+Rb+Mg+Ga for the SH-type ores; Fe+Cr+Mn+Nb+V for the SLH-type ores; and Fe+Ag+Au+Cr+Ba+As+Pb+Sb+Ni for the LH-type ores. Positive correlations between Fe, U, Bi, and Rb for the SH type indicate that late magmatic hydrothermal input was related to monzonitic intrusions. Chondrite-normalized rare earth element (REE) patterns of the 14 deposits show very weak light/heavy REE (LREE/HREE) fractionation. Similarities of REE patterns, particularly between the SH and LH types, may indicate a common source of REEs and Fe. Ce depletion in the LH ores indicates long-term fluid flow and interaction with marine sediments. Ni, Cr, and V enrichment of all deposits indicates that iron was scavenged from the serpentinized ultra-basic-basic rocks and transported along fracture zones by hydrothermal solutions driven by intrusions. The iron deposits were formed around the magmatic bodies, or tectonic contacts between the serpentine and the limestone. 相似文献
15.
XU Hai GAO Junbo YANG Ruidong DU Lijuan LIU Zhichen CHEN Jun FENG Kangning YANG Guanghai 《《地质学报》英文版》2020,94(1):90-102
The Zunyi manganese deposits, which formed during the Middle to Late Permian period and are located in northern Guizhou and adjacent areas, are the core area of a series of large-medium scale manganese enrichment minerogenesis in the southern margin and interior of the Yangtze platform, Southern China. This study reports the universal enrichment of rare earth elements(REEs) in Zunyi manganese deposits and examines the enrichment characteristics, metallogenic environment and genesis of REEs. The manganese ore bodies present stratiform or stratoid in shape, hosted in the silicon–mud–limestones of the Late Permian Maokou Formation. The manganese ores generally present lamellar, massive, banded and brecciated structures, and mainly consist of rhodochrosite, ropperite, tetalite, capillitite, as well as contains paragenetic gangue minerals including pyrite, chalcopyrite, rutile, barite, tuffaceous clay rock, etc. The manganese ores have higher ΣREE contents range from 158 to 1138.9 ppm(average 509.54 ppm). In addition, the ΣREE contents of tuffaceous clay rock in ore beds vary from 1032.2 to 1824.5 ppm(average 1396.42 ppm). The REEs from manganese deposits are characterized by La, Ce, Nd and Y enriched, and existing in the form of independent minerals(e.g., monazite and xenotime), indicating Zunyi manganese deposits enriched in light rare earth elements(LREE). The Ce_(anom) ratios(average-0.13) and lithofacies and paleogeography characteristics indicate that Zunyi manganese deposits were formed in a weak oxidation-reduction environment. The(La/Yb)_(ch), Y/Ho,(La/Nd)_N,(Dy/Yb)_N, Ce/Ce* and Eu/Eu* values of samples from the Zunyi manganese deposits are 5.53–56.92, 18–39, 1.42–3.15, 0.55–2.20, 0.21–1.76 and 0.48–0.86, respectively, indicating a hydrothermal origin for the manganese mineralization and REEs enrichment. The δ~(13) C_(V-PDB)(-0.54 to-18.1‰) and δ~(18) O_(SMOW)(21.6 to 26.0‰) characteristics of manganese ores reveal a mixed source of magmatic and organic matter. Moreover, the manganese ore, tuffaceous clay rock and Emeishan basalt have extremely similar REE fractionation characteristic, suggesting REEs enrichment and manganese mineralization have been mainly origin from hydrothermal fluids. 相似文献
16.
The San Rafael Massif is characterized by widespread fluorite and manganese epithermal ore deposits whose origin has been under debate to the present. Isotopic (Sm/Nd and K/Ar) and geochemical (trace elements and REE) data of fluorite and manganese ore allowed to establish the age and genesis of the deposits and to propose a regional genetic model. The fluorite deposits were formed during the Upper Triassic–Lower Jurassic as a result of the Triassic rifting that launched a hydrothermal activity at regional scale. The hydrothermal fluids had low T and high fO2 with fluorine probably derived from a mantle source and REE scavenged from the volcanics of the Gondwanan Choiyoi Magmatic Cycle upper section. The manganese deposits were formed by oxidizing hydrothermal fluids that collected Mn from deep sources and also leached REE from the upper section of the Choiyoi Magmatic Cycle during two mineralization episodes. One episode was linked to the rift tectonic setting that remained active up to the Upper Cretaceous and the other was related to an Early Miocene back-arc extensional geodynamic setting. Both manganese and fluorite deposits were formed in extensional tectonic settings within an epithermal environment near the surface, and can be ascribed to the general model of detachment-related deposits. 相似文献
17.
Mineralogy and geochemistry of banded iron formation and iron ores from eastern India with implications on their genesis 总被引:1,自引:0,他引:1
The geological complexities of banded iron formation (BIF) and associated iron ores of Jilling-Langalata iron ore deposits,
Singhbhum-North Orissa Craton, belonging to Iron Ore Group (IOG) eastern India have been studied in detail along with the
geochemical evaluation of different iron ores. The geochemical and mineralogical characterization suggests that the massive,
hard laminated, soft laminated ore and blue dust had a genetic lineage from BIFs aided with certain input from hydrothermal
activity. The PAAS normalized REE pattern of Jilling BIF striking positive Eu anomaly, resembling those of modern hydrothermal
solutions from mid-oceanic ridge (MOR). Major part of the iron could have been added to the bottom sea water by hydrothermal
solutions derived from hydrothermally active anoxic marine environments. The ubiquitous presence of intercalated tuffaceous
shales indicates the volcanic signature in BIF.
Mineralogical studies reveal that magnetite was the principal iron oxide mineral, whose depositional history is preserved
in BHJ, where it remains in the form of martite and the platy hematite is mainly the product of martite. The different types
of iron ores are intricately related with the BHJ. Removal of silica from BIF and successive precipitation of iron by hydrothermal
fluids of possible meteoric origin resulted in the formation of martite-goethite ore. The hard laminated ore has been formed
in the second phase of supergene processes, where the deep burial upgrades the hydrous iron oxides to hematite. The massive
ore is syngenetic in origin with BHJ. Soft laminated ores and biscuity ores were formed where further precipitation of iron
was partial or absent. 相似文献
18.
The ore-forming role of black shales is discussed. Correlation of their distribution with high phosphorus and manganese concentrations
is shown. Associations of black shales, phosphorites, and manganese ores are described. A mechanism is proposed for explaining
their co-occurrence in natural environments. It is emphasized that back shales serve as not only ore-forming sequences, but
also ore-generating formations for phosphorus and manganese deposits, as well as ore-concentrating rocks for chalcophile elements. 相似文献
19.
贵州松桃西溪堡锰矿沉积地球化学特征 总被引:4,自引:0,他引:4
贵州黔东断裂坳陷带是贵州重要的锰矿成矿带,并发育新元古代大塘坡期的一套完整“黑色岩系”,锰矿主要赋存于该黑色岩系中。本文以松桃西溪堡锰矿床为例,通过岩石学、矿物学、地球化学等研究方法,探讨这类锰矿床的成矿物质来源及成因。研究表明矿石中的矿物组分复杂,结构构造类型多样,富集As、Sb、Ag、Co、Mo、W、Cs和Ba等元素,Fe/Ti、(Fe+Mn)/Ti、A1/(AI+Fe+Mn)、Y/Ho、Nb/Ta比值,以及Cr.zr和Th.u图解均揭示成矿过程中有热水物质参与;V/(V+Ni)、V/Cr比值表明锰矿形成于缺氧环境;稀土元素分布模式、Ce、Eu异常及La.Ce、La/Yb.EREE图解显示锰矿形成于被动大陆边缘环境,并具有热水沉积特征。因此,古被动大陆边缘是锰矿富集的理想场所,热水(液)活动为其提供了丰富的物质来源。这为锰矿的找矿拓展了新的思路。 相似文献
20.
朱兆奇 《中国地球化学学报》1989,8(1):54-64
Under and climate conditions the chemical weathering of manganese ores is govermed by the fugacities of O2,CO2 and S2 in the atmosphere and soils.Manganese minerals exhibit solid phase transformations without migration of Fe and Mn.Under tropical and subtropical humid climate condi-tions low-valent Mn is instable and apt to be oxidized into high valency state.High-valent Mn miner-als are stable and easy to form secondary high-grade Mn ores.Secondary concentration is possible for Mn ores in carbonate formations,while those in clastic rocks tend to migrate and may be washed away.Such differences are the main obstacles in prospecting Mn ore deposits. 相似文献