遵义黄家湾镍钼多金属矿成矿特征与成因

贵州遵义地区黄家湾镍钼多金属矿是寒武系底部的黑色页岩型矿床。黑色岩系中微量元素特征显示镍钼多金属矿层的Ni,Mo,Cd,V,Cu,Zn明显富集,而高场强元素Nb,Th,Hf,Zr,Ti亏损。稀土元素显示多金属矿层的艿（Eu）呈正异常,中稀土富集,重稀土亏损。结合镜下观察发现的有机质、红藻囊果与金属硫化物之间密切的共生关系和前人研究结果,分析了黑色岩系镍钼多金属矿的成因,认为镍、钼、铜、锌等金属元素的来源与热液有关,通过生物作用聚集并在缺氧的还原沉积环境下大量堆积,富集形成Ni—Mo金属硫化物矿床。     

湘西北早寒武世黑色岩系微量元素地球化学特征

对湘西北杆子坪剖面牛蹄塘组黑色岩系进行了系统的微量元素地球化学研究，结果表明：牛蹄塘组底部黑色岩系Ni、Mo、V、U、Cu、Pb、Zn、Cd、Tl、Ba等亲硫元素与过渡元素高度富集，U／Th大于1，稀土元素具有明显的正Eu异常与正Y异常，是海底热水沉积作用的结果。牛蹄塘组上部碳质页岩与泥质页岩亲硫元素与过渡元素明显降低，而Nb、Ta、Zr、Hf、Rb等高场强与大离子元素明显增高，表明陆源碎屑来源越来越多。     

黔东注溪黑色岩系地球化学特征及矿化富集规律

目前急需分析黔东注溪钒矿形成的环境、成矿的物质来源以及矿化富集规律,指导实际地质勘查工作.系统研究了注溪矿区内中洞、老屋基和坪哨3个典型岩性剖面中黑色岩含矿岩系及矿层的全岩主微量元素组成.结果表明,含矿岩系具有较高的SiO₂、MnO、Ce/Ce*和Eu/Eu*值,而矿层则含相对较高的Al₂O₃、Fe₂O₃、TiO₂、CaO、Na₂O、K₂O、P₂O₅、V₂O₅、REE、As、Cu、Pb、Zn、Mo、Ni、Ti、Cr、Rb、Sr、Th、U和V.含矿岩系与矿层的主微量地球化学特征显示注溪钒矿床的成矿物源具有一定程度陆源物质的输入,且在成矿阶段受到了热水作用及生物作用的影响.另外,由南至北各剖面的热水成矿作用逐渐减弱;含矿岩系及矿层沉积环境均属缺氧环境,其中坪哨剖面的矿层沉积环境的缺氧程度要高于其他剖面.因此,注溪钒矿床钒富集成矿主要受古环境的还原条件和热液活动的影响,其中还原环境对钒元素的富集成矿起主要作用.据此推测坪哨剖面矿层形成时的海水深度应最深,北矿段中洞剖面的最浅;喷流热水带来的V等大量多金属元素在喷口及其附近大规模成矿.      

黑色页岩与土壤重金属污染

本文利用ICP—MS等技术分析了湘中地区黑色页岩及其相应土壤的重金属含量,在对分析结果进行统计分析的基础上,探讨了黑色页岩与土壤重金属污染的关系。研究表明,黑色页岩是富集多种重金属元素的特殊岩石。以黑色页岩岩系为母岩的土壤,不仅明显富集Cu、Cd、Cr、Co、Pb、Zn、Mo、Ni、V、U、Sn、Sb、T1、Th等多种重金属元素,而且受到Mo、Sb、Cd、U、Tl、Cu、V、Sn、Th等重金属的污染,其中以Mo、Cd、Sb、U、Tl等的污染尤为严重。黑色页岩土壤重金属污染在一些地方已产生明显的负面环境效应,值得关注。     

澳大利亚布朗斯(Browns)Co-Cu-Ni多金属矿床地球化学特征及与中国南方黑色岩系金属矿床对比

黑色岩系中金属元素地球化学特征一直是矿床地质研究的重点.澳大利亚布朗斯Co-Cu-Ni多金属矿产于古元古代黑色岩系中,属典型的层控矿床;该矿床中主要成矿元素为Co、Cu、Ni和Pb,矿化分带不明显,蚀变微弱.δ34S均值范围为-5.21‰～14.78‰,估计生物成因的硫占一定比例,后期有细菌还原硫酸盐成因的高硫同位素组...     

浙江省下寒武统荷塘组黑色页岩系地球化学特征

首次根据浙江省西北部荷塘组岩石样品的实测数据,提出了浙江省荷塘组黑色岩系6个岩性层的Pt、Pd、Au、Ag、Cu、As、Sb、Pb、Mo、Ni、V、P、U、B、Cd、Tl、Se、Zn元素的平均值,运用微量元素和稀土元素的配分模式探讨了成岩环境及元素高含量对环境的影响.荷塘组富集元素较多,富集程度高的有Mo、Se、Cd、Ag、Sb、U、As、P;较富集的有V、B、Cu、Tl、Zn,弱富集的为Au、Pt、Pb、Ni.综合地质地球化学特征研究认为,荷塘组黑色岩系具有寻找含钼、磷、矾和有色金属矿产的潜力.     

藏南扎西康锑硫盐多金属矿床成矿物质来源分析:兼论北喜马拉雅成矿带主要矿床矿质来源的差异性

扎西康矿床是北喜马拉雅Sb-Au成矿带上一个较为特殊的大型-超大型锑硫盐多金属矿床,赋存于下侏罗统日当组。矿床容矿围岩以黑色含炭钙质板岩为主体,矿体严格受近南北向和北东向两组断裂控制,呈脉状、透镜状产出。矿石中金属矿物除闪锌矿、方铅矿、辉锑矿等常见硫化物之外,还大量发育硫锑铅矿、脆硫锑铅矿、黝铜矿、车轮矿等硫盐矿物;非金属矿物主要为菱锰矿、菱铁矿、石英和方解石,矿床的形成经历了中低温热液期和表生期。元素地球化学和硫、铅同位素研究表明,矿床中矿石和矿化岩石除富集Sb、Pb、Zn、Ag等主成矿元素外,还富含MnO、Cu、As、Cd、Au等矿化元素;容矿地层中Sb、As、Ag、Pb、Zn、Mn等成矿元素也较为富集,具备提供成矿物质的能力;矿石硫化物的硫同位素组成与容矿地层接近,指示成矿流体在运移过程中萃取了容矿地层中的Sb、As、Ag和S等组分,日当组为硫的主要提供者;铅同位素具变质结晶岩系特征,指示变质结晶岩系及与之有亲缘关系的淡色花岗岩为成矿提供了Pb、Zn等金属组分。北喜马拉雅成矿带主要典型矿床在矿质来源上存在着明显的差异,成矿带中部和北部的Sb和Sb-Au矿床的成矿物质主要来自于容矿地层和矿区岩浆岩(包括中生代中基性岩和新生代闪长岩),而在成矿带南部的Sb(-Au)-Pb-Zn矿床中,除容矿地层和矿区岩浆岩提供Sb、As、S之外,变质结晶岩系(拉轨岗日岩群)及与之有亲缘关系的淡色花岗岩也为成矿提供了Pb、Zn等金属组分。     

湘中HJC铀矿区黑色页岩土壤重金属污染地球化学分析

本文以湘中HJC铀矿区黑色页岩土壤为研究对象,对黑色页岩土壤重金属污染进行了地球化学分析。通过测制A、B、C、D等土壤剖面并系统取样,借助ICPMS等分析技术,对土壤、成土母岩、玉米等进行了系统的主量元素、重金属和其他微量元素（稀土元素）分析。结果表明,矿区黑色页岩土壤具富Al2O3、Fe2O3,而贫CaO、Na2O的化学组成特征,其化学风化指数CIA值在79~84之间。土壤因继承成土母岩的元素富集特征而富集V、Cr、Co、Ni、Cu、Zn、Mo、Cd、Sn、Sb、Tl、Pb、Th、U等多种重金属,其中Mo、Cd、Sb、U的富集最强。土壤重金属综合富集指数（EI值）在3~9之间,各剖面EI值大小顺序是：D>A>B>C, 以D剖面土壤重金属综合富集最强。土壤重金属污染富集因子（F）评价结果显示：矿区土壤普遍存在Cd、Mo、Sn、Sb、U等重金属污染,其中Mo、Cd、Sb等的污染最强,达显著（3级,2 < F < 20）污染程度以上。重金属污染效应既表现为Sc、Cd、Sn、Sb、U、Tl、Pb等生物毒性重金属在玉米中的富集,又表现为Mo、Co、Ni、Cu、Zn等生物有用金属在玉米中的明显亏损。黑色页岩即为土壤重金属污染的污染源。土壤重金属污染与重金属在成土母岩和土壤中的富集程度(Ks、EI、F)、重金属的活动性（Change%）等多种因素有关。重金属污染主影响因子的Pearson相关系数分析显示：Cd对土壤构成持久性污染,Mo、Sn、Sb、U等的污染程度可随土壤风化的进行因淋失而趋于降低,而Zn、Mn、Ba、Co、Ni、Th等目前未达到污染水平的重金属则可因次生富集而在未来引发污染。     

遵义牛蹄塘组黑色岩系的硒同位素变化及其环境指示初探

西南早寒武纪牛蹄塘组是分布在中国南方扬子地台的一套黑色岩系,在区域上发育有典型富集多金属元素的硫化物矿化层.本研究选取遵义松林小竹牛蹄塘组下部富硒、钼、镍等元素的黑色岩系剖面,利用Se同位素初步探讨了该剖面岩石的沉积环境和Se的可能来源.     

重庆巫山地区上二叠统黑色岩系中镉等有害元素赋存状态及环境意义

本文以重庆巫山地区上二叠统黑色岩系为研究对象,通过全岩化学分析、矿物分析、连续化学提取、浸提实验等方法,揭示黑色岩系中有害微量元素的赋存状态及其环境意义.结果表明,研究区黑色岩系样品富含有机碳和硫,为典型缺氧条件下的产物;明显富集Cd、Cr等有害元素.Cd主要赋存于碳酸盐矿物中,Cr主要赋存于硅酸盐矿物,Zn和Ni的赋存载体包括硫化物、有机质等.不同样品中有害元素的赋存状态有所差异,且与矿物组分密切相关.母岩中有害元素赋存状态的差异可能控制其在土壤等环境介质中的活性;硫化物含量高而碳酸盐矿物含量低的黑色岩系样品,有害元素释放量大,潜在生态风险高,应引起高度重视.     

湘西北镍钼多金属矿床的元素组合及微量元素地球化学

湘西北镍钼多金属矿床富集了多种元素，形成一个以Ｎｉ、Ｍｏ、Ｃｕ、Ｚｎ、Ｐｄ、Ｐｔ、Ａｓ、Ｓｅ、Ｂａ、Ｖ、Ｐ为主的特殊元素组合；微量元素Ａｓ、Ｓｅ、Ｂａ等成１０＾１￣１０＾３倍富集，它们的地球化学特征表明，这类矿床属海底喷气沉积矿床，这组特殊元素来源和富集，与海底喷流作用有关。     

Distribution of major and trace elements in La Luna Formation, Southwestern Venezuelan Basin

The La Luna Formation (Maraca section), Maracaibo Basin, was studied by means of V and Ni analysis of the bitumen, total organic carbon (TOC), total sulfur (St), major elements (Si, Al, Fe, Mg, Mn, Ca, Ti, Na, K, P), trace elements (V, Ni, Co, Cr, Cu, and Zn), and electron microprobe analysis (EPMA) of the whole rock, and St, major elements (Si, Al, Fe, Mg, Mn, Ca, Ti, Na, K, P), trace elements (V, Ni, Co, Cr, Cu, Zn, Mo, Ba, U, Th) and rare earth elements (La, Ce, Nd, Sn, Eu, Th, Yb, Lu) of the carbonate-free fraction. The results are discussed based on the organic and inorganic association of trace elements and their use as paleoenvironmental indicators of sedimentation. An association between V and organic matter is suggested by means of correlation between V and Ni vs. TOC, the use of EPMA (whole rock) and V and Ni concentrations (carbonate-free fraction), whereas Ni is found in the organic matter and the sulfide phase. Fe is present as massive and framboidal pyrite, whereas Zn precipitates into a separate phase (sphalerite), and Ni, Cu and, in some cases, Zn, can be found as sulfides associated with pyrite. Concentrations of V and Ni (bitumen), TOC, St, V, Ni, Cr, Cu and Zn (whole rock), U, Th, Mo (carbonate-free fraction) are indicative of changes in the dysoxic sedimentation conditions in the chert layers (TOC, St, V, Ni, Cu and low Zn and V/Cr <4) to euxinic anoxic conditions in the argillaceous limestone (TOC, St, V, Ni, Cu and high Zn and V/Cr >4). In the sequence corresponding to the argillaceous limestone, variations in the concentrations of TOC, St, V, Ni, Zn, Cu and Cr (whole rock) can be observed, also suggesting variable sedimentation conditions. The following is proposed: (i) sedimentation intervals under euxinic conditions associated with high contribution and/or preservation of organic matter, allowing a high concentration level of V and Ni in the organic phase and the accumulation of Cu, Zn and Ni (in a smaller proportion) in the sulfide phase; (ii) sedimentation intervals under anoxic conditions and in the presence of relatively lower H₂S, which allowed lower concentrations of V and Ni in the organic phase and higher concentrations of Cu, Zn, and Ni in the sulfide phase. Rare earth elements (REE) concentrations exhibit a marked increase in Ce, Nd, Sm, Eu, Y and Lu for the QM-3 interval, relative to Post-Archean Average Shale (PAAS). REE enrichment in shales has been related to the presence of phosphate minerals such as monazite or apatite. However, these minerals were not detected through XRD or EPMA in the whole rock or in the carbonate-free fraction. The association of REE with organic matter is suggested due to the absence of phosphate minerals, although assessment of these elements require further analysis.     

Release of heavy metals during weathering of the Lower Cambrian Black Shales in western Hunan,China

Weathering of heavy metal enriched black shales may be one of the most important sources of environmental contamination in areas where black shales are distributed. Heavy metal release during weathering of the Lower Cambrian Black Shales (LCBS) in western Hunan, China, was investigated using traditional geochemical methods and the ICP-MS analytical technique. Concentrations of 16 heavy metals, 8 trace elements and P were measured for samples from selected weathering profiles at the Taiping vanadium ore mine (TP), the Matian phosphorous ore mine (MT), and Taojiang stone-coal mine (TJ). The results show that the bedrock at these three profiles is enriched with Sc, V, Cr, Co, Ni, Cu, Zn, Pb, Th, U, Mo, Cd, Sb, Tl, and P. Based on mass-balance calculation, the percentages of heavy metals released (in % loss) relative to immobile element Nb were estimated. The results show significant rates of release during weathering of: V, Cr, Co, Ni, Cu, Zn, U, Mo, Cd, Sn, Sb, and Tl for the TP profile; Sc, Cr, Mn, Co, Ni, Cu, Zn, Pb, Th, Cd, and Sn for the MT profile; and Sc, Mn, Co, Ni, Zn, Th, Cd, Sn, and Tl for the TJ profile. Among these heavy metals, Co, Ni, Zn, Cd, and Sn show very similar features of release from each of the three weathering profiles. The heavy metals released during weathering may affect the environment (especially topsoil and surface waters) and are possibly related to an observed high incidence of endemic diseases in the area.     

渔塘坝硒矿床多元素富集与沉积环境

对采自湖北西部渔塘坝二叠系独立硒矿区的硅质岩和页岩样品进行了元素测试（微量元素、总铁、总有机碳、总硫）,分析了该区域的多元素富集及沉积环境。该区域V、Cu、As、Cd、Tl、Se、Mo、V、 Sb、 U、Ag、 Cr、Ni相对富集, Ba、Hf、Ta、W、Pb、Th相对贫化或亏损。全硫—全铁（TS—TFe）的关系表明页岩及部分硅质岩的S/Fe比值均大于1.15,说明有过量的硫存在,可能为有机硫或为其他亲硫元素沉淀提供条件。TOC—TS—TFe三角图及V/(V + Ni)表明该区域的岩石形成于缺氧或静海相环境。U/Th、Zr—Cr、P—Y等微量元素地球化学参数表明该区域有热水沉积的存在。通过对微量元素可能的来源研究分析,该区域的微量元素可能存在多种来源:热水来源、海水沉积、峨眉山玄武岩。     

Metal sources for the polymetallic Ni–Mo–PGE mineralization in the black shales of the Lower Cambrian Niutitang Formation,South China

Total organic carbon content (TOC), trace element and platinum-group element (PGE) concentrations were determined in the black shales of the Lower Cambrian Niutitang Formation in the Nayong area, Guizhou Province, South China, in order to study the polymetallic Ni–Mo–PGE mineralization. The results demonstrate that numerous elements are enriched in the polymetallic ores compared to those of the nearby black shale, particularly Ni, Mo, Zn, TOC and total PGE, which can reach up to 7.03 wt.%, 8.49 wt.%, 11.7 wt.%, 11.5 wt.% and 943 ppb, respectively. The elemental enrichment distribution patterns are similar to those in the Zunyi and Zhangjiajie areas except that the Nayong location is exceptionally enriched in Zn. Whereas positive correlations are observed between the ore elements of the polymetallic ores, no such correlations are observed in the black shale. These positively correlated metallic elements are classified into three groups: Co–Ni–Cu–PGE, Zn–Cd–Pb and Mo–Tl–TOC. The geological and geochemical features of these elements suggest that Proterozoic and Early Palaeozoic mafic and ultramafic rocks, dolomites and/or Pb–Zn deposits of the Neoproterozoic Dengying Formation and seawater could be the principal sources for Co–Ni–Cu–PGE, Zn–Cd–Pb, and Mo–Tl–TOC, respectively. Furthermore, the chondrite-normalized patterns of PGEs with Pd/Pt, Pd/Ir and Pt/Ir indicate that PGE enrichment of the polymetallic ores is most likely related to hydrothermal processes associated with the mafic rocks. In contrast, PGE enrichment in the black shale resembles that of the marine oil shale with terrigenous and seawater contributions. Our investigations of TOC, trace elements and PGE geochemistry suggest that multiple sources along with submarine hydrothermal and biological contributions might be responsible for the formation of the polymetallic Ni–Mo–PGE mineralization in the black shales of the Lower Cambrian Niutitang Formation across southern China.     

古海洋生产力与氧化还原指标——元素地球化学综述

海洋表层初级生产力大小以及水体氧化还原条件是古海洋和古气候研究的重要内容,而元素地球化学是研究初级生产力以及氧化还原条件最常用的手段。主量元素Fe和Si是限制生物的营养元素,痕量金属元素Cu、Ni和Zn是微营养元素,而营养条件是沉积生产力的限制因素,因此这些元素的含量能反映初级生产力大小。Ba和Mo是随有机质一起沉淀下来的,与水体的有机碳通量有关,也是古生产力大小的指标。对氧化还原敏感的痕量金属元素含量（如Cr、V和U）以及元素比值（如V/（V＋Ni）、V/Cr、Ni/Co、U/Th和V/Sc）常用来重构水体的氧化还原条件。     

Abundances and modes of occurrence of trace elements in the Çan coals (Miocene), Çanakkale-Turkey

This study presents the concentrations and modes of occurrence of trace elements in 81 coal samples from the Çan basin of northwestern Turkey. The concentration of trace elements in coal were determined by inductively coupled plasma-mass spectrometry and inductively coupled plasma-atomic emission spectrometry. Additionally, traditional coal parameters were studied by proximate, ultimate, X-ray diffraction, and petrographic analyses. Twenty trace elements, including As, B, Ba, Be, Cd, Cu, Co, F, Hg, Mo, Ni, Pb, Sb, Se Sn, Th, Tl, U, V, and Zn, receive much attention due to their related environmental and human health concerns. The Çan coals investigated in this study are lignite to sub-bituminous coal, with a broad range of ash yields and sulphur contents. The trace element concentrations show variety within the coal seams in the basin, and the affinities vary among locations. The concentrations of B, Ba, Be, Cd, Cu, Co, F, Hg, Mo, Ni, Pb, Sb, Se, Sn, Tl, and Zn in Çan coals are within the Swaine's worldwide concentration range, with the exception of As, Th, U, and V. On the other hand, compared with world coals, the Çan basin coals have higher contents of As, B, Cu, Co, Mo, Pb, Th, U, V, and Zn. Based on statistical analyses, most of the trace elements, except for U, show an affinity to ash yield. Elements including As, Cd, Hg, Se, Cu, Mo, Ni, and Zn, show a possible association with pyrite; however, the elements Se, B, and Mo can be have both organic and inorganic associations.     

Multiple Sources of Metals of Mineralization in Lower Cambrian Black Shales of South China: Evidence from Geochemical and Petrographic Study

Black shales of the Lower Cambrian Niutitang Formation in southern China (Huangjiawan mine, Zunyi region, northern part of the Guizhou Province) host regionally distributed stratiform polymetallic Ni‐Mo‐platinum group elements (PGE)‐Au phosphate‐ and sulfide‐rich ores. These are confined to a ≥0.2‐m thick ore horizon composed of mineralized bodies of algal onkolites, phosphate nodules, and sulfide and shale clasts in a mineralized phosphate‐ and organic matter‐rich matrix. Compared to footwall and hanging wall shales, the ore bed is strongly enriched in Ni (up to 100‐fold), As (up to 97‐fold), Mo (up to 95‐fold), Sb (up to 67‐fold), Rh (up to 49‐fold), Cu (up to 37‐fold), Pd (up to 33‐fold), Ru (up to 24‐fold), Zn (up to 23‐fold), Pt (up to 21‐fold), Ir (up to 15‐fold), Co (up to 14‐fold), and Pb (up to 13‐fold). Even footwall and hanging wall black shales are significantly enriched by Mo (21‐fold) and Ni (12‐fold) but depleted in Cr in comparison to average Cambrian black shale. Organic matter is represented by separate accumulations dispersed in the rock matrix or as biotic bitumen droplets and veinlets in ore clasts. Similar organic carbon (C_org) values in an ore bed and enclosing footwall and hanging wall shales of little mineralization indicate that metal accumulation was not controlled only by biogenic productivity and organic matter accumulation rate. Evaporitic conditions during sedimentation of the basal part of the Niutitang Formation were documented by an occurrence of preserved Ni‐, V‐, Cr‐, and Cu‐enriched phosphate‐rich hardground with halite and anhydrite pseudomorphs on the paleosurface of the underlying Neoproterozoic carbonates. Neoproterozoic black shales of the Doushantuo Formation are characterized by increased metal concentrations. Comparison of metal abundances in both hardground and Doushantuo black shales indicate that black shales could have become a source of metal‐rich hardground during weathering. The polymetallic Ni‐Mo‐PGE sulfide‐rich ore bed is interpreted to represent a remnant of shallow‐water hardground horizon rich in metals, which originated in a sediment‐starved, semi‐restricted, seawater environment. During the Early Cambrian transgression an influx of fresh seawater and intensive evaporation, together with the hydrothermal enrichment of seawater in a semi‐restricted basin, resulted in the formation of dense metalliferous brines; co‐precipitation of metals together with phosphates and sulfides occurred at or above the oxic–anoxic sediment interface. Metal‐enriched hardground was disintegrated by the action of waves or bottom currents and deposited in a deeper part of the anoxic basin. Contemporaneously with the formation of a polymetallic Ni‐Mo‐PGE‐Au sulfide ore bed, economic sedimentary exhalative (SEDEX)‐type barite deposits were forming in a stratigraphically and geotectonically similar setting. The results of geochemical study at the Shang Gongtang SEDEX‐type Ba deposit indicate that concentrations of Ag, As, Cr, Cu, Fe, Mn, Ni, Pb, Sb, V, Zn and other metals decrease from top of the barite body toward the hanging wall black shale. Lower Cambrian black shales of the Niutitang Formation above the barite body also display similar element abundances as Neoproterozoic black shales of the Doushantuo Formation, developed in the footwall of the barite body. But the geochemical composition of the sulfide layer is different from the Ni‐Mo ore bed, showing only elevated Pb, Cu, Ni and Mo values. It is suggested that hydrothermal brines at Shang Gongtang might have leached metals from footwall Neoproterozoic sequences and became, after mixing with normal seawater, an additional source of Ag, Cr, Cu, Pb, Sb, Zn, Ni, PGE, V and other metals.