Zircon Geochronology and Trace Element Geochemistry from the Xiaozhen Copper Deposit, North Daba Mountain: Constraints on Albitites Petrogenesis

Albitite often accompanies with various metal and gem mineral deposits and a large number of occurrences have been reported globally, including the South Qinling orogen, China. The Xiaozhen copper deposit is a typical deposit in the North Daba Mountain area of the South Qinling orogen whose distribution is controlled by albitite veins and fractures. As there are few studies on the petrogenesis of albitite in Xiaozhen copper deposit, this paper focuses on the petrogenesis of albitite and its mineralization age. Detailed fieldwork and mineral microscopic observations initially suggest that albitite from the Xiaozhen copper deposit is igneous in origin. Further zircon trace element geochemistry studies indicate that these zircons have high Th/U ratios（〉0.5）, low La content, high（Sm/La）N and Ce/Ce＊values, and a strong negative Eu anomaly, which are commonly seen in magmatic zircons. The chondrite–normalized rare earth element（REE） patterns are consistent with magmatic zircons from throughout the world, and they fall within or near the field of magmatic zircons on discriminant diagrams. The calculated average apparent Ti–in–zircon temperature for young zircons is 780°C, consistent with magmatic zircon crystallization temperatures. Therefore, zircon geochemistry indicates that the albitite origin is magmatic. SIMS U–Pb dating on nine magmatic zircons yielded a concordia age of 154.8±2.2 Ma, which represents the formation of albitite and the metallogenic age. More importantly, it is consistent with the ages of Yanshanian magmatism and metallogenesis in the South Qinling orogen, so formation of the Xiaozhen copper deposit may be a closely related geological event.

Significance of zircon trace element geochemistry,the Shihu gold deposit,western Hebei Province,North China

The Shihu gold deposit is characterized by gold-bearing quartz-polymetallic sulfides and quartz veins.Both Mapeng granitoids batholith and intermediate-basic dikes intruded the metamorphic basement rocks,and are spatially associated with gold mineralization.Trace element abundances in zircons from the Shihu gold deposit,determined by laser-ablation microprobe ICPMS analysis,are sensitive to source rock type and crystallization environment.Concentrations of 21 trace elements were determined for zircons from granitoid rocks,diorites,quartz diorite porphyrites and gold-bearing quartz veins revealed some elemental characteristics and chondrite-normalized trace element patterns from different samples.There were no distinctive differences in REE concentrations of zircons from plutonic rocks and quartz veins,indicating that they probably had the same origin.Relatively flat chondrite-normalized REE patterns with（Yb/Sm）N ratios less than 60 characterized zircons from quartz diorite porphyrites and quartz veins.The highest Nb/Ta ratios were found in zircons from quartz diorite porphyrites,whereas the lowest ratios were found in quartz vein zircons.The Nb/Ta ratios were broadly correlated with HREE＋Y contents,and had weak positive correlations with the depth of the Eu negative anomalies.High values U up to 0.4% and Th up to 0.1%,as well as positive correlations with REE＋Y characterized zircons from quartz vein.The lowest Th/U ratios of zircons present in quartz veins reflected the relatively high concentration of U in hydrothermal fluid,and high Pb concentrations only typified quartz vein grains relatively enriched in U and Th.Zircons from quartz diorite porphyrites showed the most pronounced Ce anomalies,whereas weak Ce anomalies were typical of zircons from quartz veins,in which Eu/Eu＊ of zircons had a broadly negative correlation with Ce/Ce＊.Trace element geochemistry of zircons from mineralized quartz veins and plutonic rocks confirmed that the sources of ore-forming materials were from Precambrian host rocks.Our results significantly enhanced the usefulness of zircon in crustal studies of the North China craton and as an indicator mineral in mineral exploration of the Taihang region.

Geochemical Behaviors of REE and Other Trace Elements during the Formation of Strata-bound Skarns and Related Deposits:A Case Study of the Dongguashan Cu(Au)Deposit,Anhui Province,China

REE and other trace elements in the altered marbles, massive skarns and ores, as well as garnet and quartz were determined in order to examine the behaviors of trace elements during hydrothermal alteration. It is demonstrated that the high-field-strength (HFS) elements Zr, Hf, Th and Nb were immobile while other trace elements were mobile during the formation of skarns and related deposits. REE and ore-forming elements such as Cu and Ag in hydrothermally-altered marbles and skarns were provided primarily by hydrothermal fluids. In the direction transverse of the strata, the more deeply the marbles were altered, the higher the total REE abundance and the larger the negative Eu anomalies would be. The chondrite-normalized REE patterns of skarns are similar to those of the marbles, but the former are distinguished by much higher REE contents and more remarkable negative Eu anomalies. Those patterns were apparently not inherited from the marble protolith, but were controlled by garnets, which were determined by the hydrothermal solutions involved in the infiltration metasomatism. The hydrothermal fluids are characterized by having slightly right-hand dipping REE patterns, being enriched in LREE and having strongly negative Eu anomalies. The uptake of REE from hydrothermal fluids during the growth of garnet crystals resulted in the garnets having similar REE patterns to the hydrothermal fluids. Based on the spatial variation of REE in skarns and the structures of the hosting strata, we can get a better understanding of the transport path and pattern of the fluids involved in the formation of skarns and their related deposits. REE geochemistry investigation can help elucidate the genesis of skarns and skarn-related deposits.

Ore Genesis for Stratiform Ore Bodies of the Dongfengnanshan Copper Polymetallic Deposit in the Yanbian Area, NE China:Constraints from LA-ICP-MS in situ Trace Elements and Sulfide S–Pb Isotopes

The Dongfengnanshan Cu polymetallic deposit is one representative deposit of the Tianbaoshan ore district in the Yanbian area, northeast(NE) China. There occur two types of ore bodies in this deposit, the stratiform ore bodies and veintype ones, controlled by the Early Permian strata and the Late Hercynian diorite intrusion, respectively. Due to the ambiguous genetic type of the stratiform ore bodies, there has been controversy on the relationship between them and veintype ore bodies. To determine the genetic type of stratiform ore bodies, laser ablation inductively coupled plasma mass spectrometry(LA-ICP-MS) in situ trace elements and S–Pb isotope analysis have been carried on the sulfides in the stratiform ore bodies. Compared with that in skarn, Mississippi Valley-type(MVT), and epithermal deposits, sphalerite samples in the stratiform ore bodies of the Dongfengnanshan deposit are significantly enriched in Fe, Mn, and In, while depleted in Ga, Ge, and Cd, which is similar to the sphalerite in volcanic-associated massive sulfide(VMS) deposits. Co/Ni ratio of pyrrhotites in the stratiform ore bodies is similar to that in VMS-type deposits. The concentrations of Zn and Cd of chalcopyrites are similar to those of recrystallized VMS-type deposits. These characteristics also reflect the intermediate ore-forming temperature of the stratiform ore bodies in this deposit. Sulfur isotope compositions of sulfides are similar to those of VMS-type deposits, reflecting that sulfur originated from the Permian Miaoling Formation. Lead isotope compositions indicate mixed-source for lead. Moreover, the comparison of the Dongfengnanshan stratiform ore bodies with some VMStype deposits in China and abroad, on the trace elements and S–Pb isotope characteristics of the sulfides reveals that the stratiform ore bodies of the Dongfengnanshan deposit belong to the VMS-type, and have closely genetic relationship with the early Permian marine volcanic sedimentary rocks.

Trace element and REE geochemistry of Sanshenjiang gold deposit, southeastern Guizhou Province, China

The Sanshenjiang gold deposit in southeastern Guizhou Province, China, is hosted by the Neoproterozoic metasedimentary rocks which experienced low-grade greenschist facies metamorphism. Gold mineralization occurs mainly in the ribbon chiltern slate of the first member of the Longli Formation and is controlled by both strata and faults. Ore bodies are characterized by abundant quartz-arsenopyrite-gold-pyrite-bedding veins, veinlets and small lenses within the shear zone. In this study, trace element and REE geochemistry was analyzed to constrain the origin and genesis of this deposit. The trace element signatures of wall rocks and veins display a basically similar tendency in the spider diagram, showing the genetic relationship. The values of Co/Ni, Y/Ho, Hf/Sm, Nb/La and Th/La reflect that the hydrothermal fluids of this deposit were derived from the mixture of multiple sources with marked enrichment of Cl and moderate to high temperature. There is a broad similarity in the chondrite-normalized patterns and REE fractionation between wall rocks and ore bodies, possibly reflecting their similar origin. Based on the difference in δCe and δEu, quartz veins and lenses can be subdivided into weakly negative Ce-anomalies (δCe=0.81 to 1.06) with slight Eu anomalies (δEu=0.81 to 1.06) type and the significant positive Ce-anomalies (δCe=1.13 to 1.97) with moderate negative Eu-anomalies type, probably suggesting physical-chemical changes in the evolution process of ore-forming fluids from the early to late stage. It can be concluded that the ore-forming process may have experienced three stages: formation of the original ore source bed, regional metamorphism and gold mineralization, on the basis of trace element and REE analysis and field observation.

Geochemical studies on REE and trace elements from several Cu-Au deposits along the lower Yangtze metallogenic valley, central-southern Anhui Province

The Yangtze Valley was one of the most important metallogenic regions during the Jurassic-Cretaceous period in East China, where more than 200 polymetallic Cu-Fe-Au, Mo, Zn, Pb, Ag deposits have been found. Trace elements were chemically analyzed and the relevant data were collected from literature for the Yanshanian (Mesozoic) igneous rocks which have close relationship with Cu-Au mineralization. Copper mineralization in the lower Yangtze Valley can be divided into three major types: skarn type, porphyry type and volcanic type. The porphyry type is of rare occurrence, such as the Shaxi porphyry copper deposit in the northern part of the lower Yangtze metallogenic valley. This paper focuses on the REE and trace element geochemistry of several Cu-Au deposits along the lower part of Yangtze metallogenic valley in Anhui. The results showed that there are differences in REE distribution for these four types of Cu-Au mineralization, which confine the sources of REE and trace elements as well as other mantle and transitional compatible elements. The results of both REE and trace element geochemical studies showed that these elements with different characteristics have different origins, probably representing different sources of Cu-Au deposits in the deep crust and upper mantle environments. The 40Ar/39Ar dating of one biotite sample gave an age of 131 Ma with a high level of confidence, which represents the age of formation of the Shaxi porphyrite intrusive with porphrytic Cu-Au mineralization, which is consistent with that of the majority of the adjacent acid intrusives with mass Cu-Au mineralization along the Yangtze metallogenic belt in the Yanshanian period (Mesozoic). This is the first attempt to use the high precision method to date the Shaxi porphyrite intrusive.

Rare earth element(REE) geochemistry of different colored fluorites from the Baoshan Cu–Pb–Zn deposit, Southern Hunan,South China

The Baoshan Cu–Pb–Zn deposit, located in the central part of the Qin–Hang belt in South China, is closely related to the granodiorite-porphyry. However, the characteristics and the source of the ore-forming fluid are still ubiquitous. According to the crosscutting relationships between veinlets and their mineral assemblages, three stages of hydrothermal mineralization in this deposit were previously distinguished. In this contribution, two different colored fluorites from the major sulfide mineralization stage are recognized:(1) green fluorites coexisting with Pb–Zn ores;and(2) violet fluorites coexisting with pyrite ores. Y/Ho ratios verify the green fluorites and violet fluorites were co-genetic. The fluorites display elevated(La/Yb)Nratios, which decrease from 1201 to 5710 for green fluorites to 689–1568 for violet fluorites, indicating that they precipitated at the early hydrothermal sulfide stage,and Pb–Zn ores crystallized earlier than pyrite ores. The similar Tb/La ratios of the fluorites also indicate that they precipitated at an early stage within a short time. From the green fluorites to violet fluorites, the total rare earth element(ΣREE)concentrationsdecreasefrom1052–1680 ppm to 148–350 ppm, indicating that the green fluorites precipitated from a more acidic fluid. The Eu/Eu*ratios increase from 0.17 to 0.30 for green fluorites to0.29–0.48 for violet fluorites, and the Ce/Ce* ratios decrease from 1.08–1.13 to 0.93–1.11, suggesting a gradual increase in oxygen fugacity(fO_(2)) and pH value of the mineralization fluid. Though the fluorites display similar REE patterns to the granodiorite-porphyry and limestone,the ΣREE concentrations of the fluorites are significantly higher than those of limestone and the granodiorite-porphyry, suggesting that an important undetected non-magmatic source is involved to provide sufficient REE for fluorites. The most plausible mechanism is fluid mixing between magma fluid and an undetected non-magmatic fluid.

Rare Earth Element and Trace Element Features of Gold-bearing Pyrite in the Jinshan Gold Deposit,Jiangxi Province

Jinshan gold deposit is located in northeastern Jiangxi,South China,which is related to the ductile shear zone.It has a gold reserve of more than 200 tons,with 80%of gold occurring in pyrite. The LREE of gold-bearing pyrite is as higher as 171.664 ppm on average,with relatively higher light rare earth elements（LREE;159.556 ppm） and lower HREE（12.108 ppm）.TheΣLREE/ΣHREE ratio is 12.612 and（La/Yb）_N is 11.765.These indicate that pyrite is rich in LREE.The（La/Sm）_N ratio is 3.758 and that of（Gd/Yb）_N is 1.695.These are obvious LREE fractionations.The rare earth element（REE） distribution patterns show obvious Eu anomaly with averageδEu values of 0.664,andδCe anomalies of 1.044.REE characteristics are similar to those of wall rocks（regional metamorphic rocks）,but different from those of the Dexing granodiorite porphyry and Damaoshan biotite granite.These features indicate that the ore-forming materials in the Jinshan gold deposit derived from the wall rocks, and the ore-forming fluids derived from metamorphic water.The Co/Ni ratio（average value 0.38） of pyrite suggests that the Jinshan gold deposit formed under a medium-low temperature.It is inferred from the values of high-field strength elements,LREE,Hf/Sm,Nb/La,and Th/La of the pyrite that the ore-forming fluids of the Jinshan gold deposit derived from metamorphic water with Cl〉F.

U-Pb Geochronology and Geochemistry of Stratiform Garnet from the Aqishan Pb-Zn Deposit,Eastern Tianshan,Xinjiang,NW China:Constraints on Genesis of the Deposit

The Aqishan lead-zinc deposit,located in the Jueluotag metallogenic belt of eastern Tianshan,Xinjiang,Northwest China,has a stratiform occurrence in the marine volcanic tuff of the Yamansu Formation.The ore body has a typical double-layer structure,having a stratified,stratoid,lenticular upper part and a veined,stockwork-like lower part.The occurrence of the upper orebody is consistent with that of the volcanic tuff wall rock.The ore minerals are mainly chalcopyrite,pyrite,sphalerite,galena and magnetite,the altered minerals mainly being silicified,such as sericite,chlorite,epidote,garnet.The garnetized skarn,being stratiform and stratoid,is closely related to the upper part of the orebody.Geological observations show that the limestone in the ore-bearing Yamansu Formation is not marbleized and skarnized.Spatially,it is associated with the ferromanganese deposits in the marine volcanic rocks of the Yamansu Formation.These geological features reflect the likelihood that the Aqishan lead-zinc deposit is a hydrothermal exhalation sedimentary deposit.The results from the EPMA show that the garnet is mainly composed of grossular-andradite series,contents being in a range of 34.791-37.8%SiO_(2),32.493-34.274%CaO,8.454-27.275%FeO,0.012-15.293%Al_(2)O_(3),0.351-1.413%MnO,and lower values of 0.013-1.057%TiO_(2).The content of SiO_(2) vs.CaO and FeO vs.Al_(2)O_(3) has a significant positive correlation.The results of ICP-MS analysis for the garnet show that the REE pattern is oblique to right in general.The total amount of rare earth elements is relatively low,ΣREE=71.045-826.52 ppm,which is relatively enriched for LREE and depleted for HREE.LREE/HREE=8.66-4157.75,La_(N)/Yb_(N)=23.51-984.34,with obvious positive Eu and Ce anomalies(δEu=2.27-76.15,δCe=0.94-1.85).This result is similar to the REE characteristics of ore-bearing rhyolite volcanic rocks,showing that the garnet was formed in an oxidizing environment and affected by clear hydrothermal activity.The U-Pb isotopic dating of garnet by fs-LA-HR-ICP-MS gives an age of 316.3±4.4 Ma(MSWD=1.4),which is consistent with the formation time of the Yamansu Formation.According to the study of deposit characteristics and geochemical characteristics,this study concludes that the Aqishan lead-zinc deposit is a hydrothermal exhalation sedimentary deposit,the garnet being caused by hydrothermal exhalative sedimentation.

红尖兵山钨多金属矿床锆石、黑钨矿、日光榴石UPb年代学及地球化学:对北山造山带三叠纪关键金属成矿作用的启示

北山成矿带是我国西北地区重要的战略性金属矿产资源地之一,区内的岩浆岩年代学工作已得到广泛开展,但对成矿带内成岩与成矿关系等缺乏系统研究。红尖兵山作为北山成矿带最具代表性的钨多金属矿床受到了较多关注,但其成矿时代、矿床成因等一直存在较大争议,已成为理解区域成矿构造事件的重要制约因素。本文对红尖兵山矿床详细的野外地质调查工作显示,该矿床成矿岩体为双驼峰式二长花岗岩,矿化类型可以划分为云英岩型矿石和黄玉-石英脉型矿石。对红尖兵山成矿岩体中的锆石、云英岩型矿石中的黑钨矿和黄玉-石英脉型矿石中的日光榴石进行了LA-ICP-MS U-Pb年代学,研究结果显示其形成时代分别为221.7±1.3 Ma、221.6±2.1 Ma、220.5±7.9 Ma,指示红尖兵山的成岩成矿时代在误差范围内一致,是晚三叠世岩浆-热液活动的产物。黑钨矿、日光榴石和白云母的LA-ICP-MS成分分析结果显示,黑钨矿中富集Sc、Mo等元素,而日光榴石和白云母则分别富集Be、Zn、Sc和Li、Sc关键金属等元素。通过主成分分析(PCA)和元素相关性分析,揭示了黑钨矿、日光榴石和白云母中关键金属元素的赋存状态。综合分析显示,红尖兵山矿床形成于陆内造山后伸展构造背景下,在强烈的岩石圈伸展减薄和幔源岩浆底侵诱发下,地壳发生部分熔融产生的酸性岩浆经分异演化形成的岩浆热液与围岩相互作用后形成富含挥发组分、偏还原、低pH和低Eh的成矿流体,它们沿构造薄弱部位充填交代形成石英脉-云英岩型钨多金属矿床。本研究成果对于理解北山造山带三叠纪陆内伸展构造背景下构造-岩浆-成矿事件具有重要意义,并为该区域同类矿床的勘查和关键金属找矿提供了指导。

西藏玉龙斑岩铜矿床成矿斑岩起源及成矿意义

位于青藏高原东缘的玉龙超大型斑岩铜-钼矿床,是碰撞型斑岩铜矿的典型代表。根据现有研究发现,玉龙矿床的成矿斑岩和含矿斑岩的成矿潜力不同。为深入探讨该矿床的岩浆起源,并揭示控制其成矿潜力的内在因素,本文对玉龙矿区含矿的二长花岗斑岩和成矿的花岗斑岩进行了锆石U-Pb年代学、全岩主微量和Sr-Nd同位素对比研究。结果表明,花岗斑岩具有与二长花岗斑岩相近的结晶年龄(42~41 Ma),同时也具有相似的Sr-Nd同位素组成,其(^(87)Sr/^(86)Sr)_(i)分别为0.7060~0.7076和0.7062~0.7067、ε_(Nd)(t)分别为-2.9~-2.1和-4.6~-1.9,表明两者具有相同的岩浆起源。两期斑岩具有高K_(2)O含量(平均值大于4%),较低的MgO、Mg^(#)、Cr含量,显著的Nb、Ta负异常,较低的Nb/U和Ce/Pb值,重稀土元素相对轻稀土元素亏损,高Sr/Y值的地球化学特征,表明母岩浆起源于新生下地壳的部分熔融。锆石微量元素数据显示,两期斑岩均具有较高的Eu/Eu^(*)(>0.44)、10000×(Eu/Eu^(*))/Y(>3.6)、(Ce/Nd)/Y(>0.01)及较低的Dy/Yb值(<0.31,平均0.22),暗示两者均具有很高且相近的岩浆水含量;二长花岗斑岩ΔFMQ为0.29~2.29(平均为1.44),花岗斑岩ΔFMQ为1.07~2.74(平均为1.80),两者均具有较高的岩浆氧逸度,但花岗斑岩氧逸度具有更大的变化范围,且较二长花岗岩的更高,暗示氧逸度的差异导致了两者的成矿性差异。

塞尔维亚Čukaru Peki铜金矿床的热液绿帘石类型和成分及其找矿意义

Čukaru Peki铜金矿床位于特提斯成矿域西部塞尔维亚Timok矿集区,是近几年新发现的超大型斑岩-浅成低温热液型铜金矿床。该矿床主要产于晚白垩世角闪斜长安山岩中,具有明显的蚀变分带特征,是研究蚀变矿物勘查指标体系的理想对象。笔者结合钻孔编录信息,利用显微镜、电子探针和LA-ICP-MS分析技术,对该矿床中的绿帘石进行矿物化学成分分析。根据产状可将绿帘石划分为2类,分别为赋存于绢英岩化带中的绿帘石(Ⅰ型绿帘石)和赋存于青磐岩化带中的绿帘石(Ⅱ型绿帘石)。电子探针分析结果表明,2类绿帘石中的n(Al)与n(Fe)、n(Ca)与n(Mn)均呈现负相关关系,n(Al)、n(Fe)、w(Mn)存在明显的差异,Ⅰ型绿帘石贫Fe、Mn,富Al元素,具有相对较低的X_(Fe)值,Ⅱ型绿帘石与之相反,富Fe、Mn,贫Al元素,具有相对较高的X_(Fe)值。结合矿相学特征,文章提出Ⅰ型绿帘石由斜长石蚀变而成,Ⅱ型绿帘石由角闪石蚀变而成,暗示绿帘石的主量元素变化受蚀变前的矿物控制。LA-ICP-MS分析测试结果表明,青磐岩化带中由深部至浅部Ⅱ型绿帘石的w(Pb)、w(Sb)、w(Ba)显示升高的趋势,浅部绿帘石具有较低的w(Mo);Ⅱ型绿帘石中的w(Mn)、n(Al)和w(Mg)随着深度的增加呈现出先升高后降低的变化趋势,w(As)、n(Fe)和n(Ca)呈现出相反的空间变化趋势。由于绿帘石的微量元素找矿指标变化受温度等物理化学条件的影响,根据Čukaru Peki铜金矿床绿帘石中的w(Mg)、w(Pb)、w(Sb)、w(Ba)、w(Mo)、w(Mn)、w(As)的空间变化规律,笔者推测该斑岩型矿床热液中心在Mn元素晕之下1~2 km处。笔者研究发现Ⅱ型绿帘石中的主量元素n(Al)和X_(Fe)与w(Mn)微量元素呈现类似的变化趋势,n(Ca)和n(Fe)与w(Mn)呈现相反的变化趋势,故Ⅱ型绿帘石中的n(Al)、X_(Fe)、n(Ca)和n(Fe)元素可以作为找矿勘查的新指标。

滇西北红牛-红山铜矿床复式岩体黑云母特征及成岩成矿指示意义

滇西北红牛-红山斑岩-矽卡岩型大型铜矿床位于格咱铜多金属矿集区中部,其成矿作用与晚白垩世花岗质岩浆活动存在密切联系,矿区内发育燕山晚期花岗斑岩-石英二长斑岩复式岩体,矿体主要产于斑岩体以及与斑岩有关的矽卡岩中。铜钼矿化在空间上的分布具有明显的差异性,深部揭露的花岗斑岩发育弱黄铜矿化、辉钼矿化,而石英二长斑岩中发育较强的铜钼矿化,局部出现全岩矿化的特点,总体表现出浅部、接触带矿化程度高,向深部逐渐降低的趋势,导致这种差异的原因尚未明确。在详细的岩相学观察基础上,文章对复式岩体中的黑云母开展了EMPA及LA-ICP-MS原位微区分析,旨在查明矿区花岗斑岩-石英二长斑岩复式岩体形成时的物理化学条件以及导致二者含矿差异性的制约因素。结果表明,2种类型黑云母具有低Al,高Mg、Ti的特征,均属于镁质黑云母;黑云母成分显示红牛-红山燕山晚期复式岩体为具壳幔混源特征的I型花岗岩,属于高温、浅成-超浅成相、高氧逸度岩体。花岗斑岩结晶温度为737~751℃,压力为46~72 MPa,对应深度1.74~2.73 km,平均为2.17 km;石英二长斑岩结晶温度为722~754℃,压力为37~58 MPa,对应深度1.42~2.20 km,平均为1.91 km,氧逸度略高于花岗斑岩。花岗斑岩中黑云母的Ⅳ(F)值为0.91~1.06,Ⅳ(Cl)值为-4.67~-4.48,石英二长斑岩中黑云母Ⅳ(F)值为0.56~0.77,Ⅳ(Cl)值为-5.16~-4.81,与花岗斑岩共存的热液流体log(f_(H2O)/f_(HF))_(fluid)值为1.31~1.47,与石英二长斑岩共存的热液流体log(f_(H2O)/f_(HF))_(fluid)值为0.96~1.17,表明该复式岩体2种岩性均显示高F、Cl特征,石英二长斑岩流体中更富含HCl和HF。这些特征表明红牛-红山燕山晚期复式岩体具有同时发生Cu、Mo矿化的潜力,并且Cu、Mo元素更趋向于在石英二长斑岩中富集。较高的氧逸度和卤素含量可能是导致石英二长斑岩和花岗斑岩含矿差异性的主要原因。

滇西官房铜矿床微量元素R型因子分析及其地质意义研究

官房铜矿床位于我国著名的三江成矿带南澜沧江火山岩段北段,属云县-景谷(火山弧)铜多金属成矿带,是该区最具代表性的玄武岩铜矿床,储量达中型规模。对矿区内矿石的33种微量元素进行聚类分析与R型因子分析,结果显示:经过聚类分析,33种微量元素可分为基性岩元素组合、中低温矿化元素组合、中酸性岩相关元素及中高温矿化元素组合;R型因子分析得到F_(1)、F_(2)、F_(3)、F_(4)四类元素组合因子。其中,聚类分析与R型因子分析的元素分类结果基本一致,能够代表矿床的成矿过程,即成矿分为热液成矿期和中低温地下水热液改造期两个阶段,成矿流体主要来源于深部,成矿物质具有壳幔混合来源的特征,该矿床属于隐伏岩体及岩浆作用有明显成因联系的浅成中-低温热液矿床。

大兴安岭北段斑岩型钼(铜)矿床主要硫化物化学成分特征及地质意义--以770钼(铜)矿床为例

斑岩型钼(铜)矿床一直以来都是地质学领域的研究热点。770钼(铜)矿床是近年来在大兴安岭北段新发现的斑岩型钼(铜)矿床,目前对于该矿床的报道较少。以大兴安岭北段770钼(铜)矿床中黄铁矿和黄铜矿为研究对象,利用电子显微镜和电子探针分析技术(EPMA),深入探讨黄铁矿和黄铜矿的晶体形态和主量元素、微量元素组成,以便更全面地解析黄铁矿和黄铜矿的化学成分特征及其地质意义。770钼(铜)矿床为大型斑岩型钼(铜)矿床,矿体赋存于晚侏罗世的花岗斑岩中。从中心向外部,蚀变区域可分为钾化带和黄铁-绢英岩化带。电子探针分析结果显示,黄铁矿中w(S)普遍小于53.45%,w(Fe)普遍小于46.55%,w(S)/w(Fe)≥1.148,表明770钼(铜)矿床黄铁矿主要为贫铁贫硫型黄铁矿,成矿环境的硫逸度较高。黄铁矿微量元素与主量元素的正负相关性特征表明,黄铁矿中的微量元素如Zn、Mo、Ni、Co和As,通常以矿物包裹体或类质同象的形式存在于矿物中。770钼(铜)矿床中黄铁矿w(Co)/w(Ni)值(2.25~4.50)显示,其具有岩浆热液成因的性质。黄铜矿的[n(Cu)+n(Fe)]/n(S)值(平均值为0.91)表明,黄铜矿等金属硫化物的形成可能发生在中低温(约200℃)热液环境中。

拉拉铜矿黄铁矿微量元素地球化学特征及其成因意义

四川会理拉拉铜矿床是我国著名大型富铜矿床，针对该矿床中黄铁矿的微量元素、稀土元素地球化学分析表明：拉拉铜矿经历了早期火山喷发成岩成矿和晚期变质成岩成矿作用。条带状矿石中的黄铁矿Co／Ni比值集中于4．92～79．2之间，落入火山成因黄铁矿区，稀土元素分布具有Eu正异常和轻稀土富集的特征，反映矿床具有伴随河口群火山喷流沉积成岩过程的同生沉积成矿作用。脉状矿石中的黄铁矿Co／Ni比值集中于1．10～3．45，落在热液成因黄铁矿区，稀土元素较河口群岩石及其他典型块状硫化物矿床矿石稀土元素更加富集轻稀土元素，稀土含量变化范围更大，显著的负Eu异常，则又说明，矿床形成的主要成矿作用是伴随新元古代晋宁运动而发生的大规模的变质作用。

陕西几类重要铅锌矿床的矿物微量元素和稀土元素特征

文章将陕西铅锌矿分为海底喷气沉积型(即SEDEX型)、与海底喷气沉积-改造作用有关的类SEDEX型和MVT型3类。对马元(MVT型)、南沙沟和江坡(类SEDEX型)、铅硐山和二里河(SEDEX型)铅锌矿床中的闪锌矿等矿物进行的微量元素和稀土元素测定结果表明,3类矿床各具特点:马元铅锌矿床闪锌矿的Co、Ni、Th、Y含量较低,而Mo、Cs、Sr、Ba、Tl含量较高;南沙沟和江坡铅锌矿床闪锌矿的Sn、Sb、W含量较低,而Mn、Y、Zr、In含量较高;铅硐山和二里河铅锌矿床闪锌矿的Li、Zr、Cs、Ba含量较低,而W含量较高;在闪锌矿Li-Cs、Zr-In、W-Sn、ΣREE-δEu、δEu-δCe散点图上,5个矿床的投点按上述3类分别集中。但铅硐山和二里河铅锌矿床与南沙沟和江坡铅锌矿床具有更多的相似性,而与马元铅锌矿床差异较大:在闪锌矿Sr-Ba、Co-Ni、Th-Y、Mo-Tl散点图上,马元的投点集中于一处,而其他4个矿床的投点集中于另一处;马元闪锌矿具有十分明显的铕正异常,而南沙沟、江坡、铅硐山和二里河闪锌矿铕异常不明显,或具有负铕异常;5元素矿床闪锌矿稀土元素配分曲线均为轻稀土元素稍富集的右倾型,但马元的稀土元素总量明显低于其他4个矿床。

滇黔交界地区峨眉山玄武岩铜矿的PGE及微量元素特征

为了进一步探讨玄武岩铜矿的成因,文章对滇黔交界地区玄武岩铜矿石的铜、铂族元素及其他微量元素的地球化学特征进行了研究。结果表明:与铜矿化关系密切的有机质对铜的初始富集作用不明显,铜矿化是后生热液成因的,进一步支持了玄武岩为铜矿化的矿源岩、沥青及碳质等有机质的存在只是为自然铜沉淀提供了条件的认识。而且,铜矿石的低U、Th含量为该类铜矿石的铅是正常铅提供了合理的解释。

江西金山金矿床含金黄铁矿的稀土元素和微量元素特征

金山金矿床位于赣东北矿集区内,是与韧性剪切带有关的超大型金矿床。黄铁矿是该矿床最主要的载金矿物。文章利用含金黄铁矿的稀土元素组成示踪了金山金矿床的成矿物质及成矿流体的来源和性质。研究结果表明,金山金矿床黄铁矿稀土元素总量较高,∑REE平均为171.664×10-6,富集轻稀土元素,LREE平均为159.556×10-6,HREE平均为12.108×10-6,轻重稀土元素比∑LREE/∑HREE平均为12.612,(La/Yb)N值平均为11.765,为轻稀土元素富集型;轻稀土元素有较明显的分馏,而重稀土元素的分馏不明显,(La/Sm)N值平均为3.758,(Gd/Yb)N值平均为1.695;Eu负异常明显,δEu值平均为0.664;基本无Ce异常,δCe值平均为1.044。黄铁矿的稀土元素特征与该矿床的围岩(蚀变变形的变质岩)、区域地层具有相似的地球化学特点,而与邻近的花岗闪长斑岩稀土元素特征不同,所以金山金矿床的成矿物质来源于变质岩围岩,成矿流体主要为变质水。黄铁矿中的Co/Ni比值显示金山金矿床为中低温矿床;成矿经历了沉积成岩、区域变质、韧性剪切带的动力变质作用及表生氧化作用的演化过程。从黄铁矿的Y/Ho比值推断金山金矿床含金黄铁矿的成矿流体为变质流体。黄铁矿中微量元素与矿区变质岩也有相似的组成,亏损HFSE。从黄铁矿的REE、LREE、HFSE、Hf/Sm、Nb/La、Th/La、Co/Ni、Y/Ho等特征,可推断金山金矿床的成矿流体是Cl多于F的变质流体。

滇西北中甸普朗斑岩铜矿床地球化学与成矿机理初探

普朗斑岩铜矿是一个典型的与洋壳俯冲相关的大型乃至超大型矿床,通过对矿区代表性含矿斑岩与无/弱矿化斑岩的稀土元素特征对比、硫同位素示踪等方面的研究,表明矿石随Cu品位的增高,稀土总量(∑REE)和稀土分馏参数〔(LREE/HREE)、(La/Yb)N及(La/Yb)N、(Gd/Yb)N〕呈连续降低趋势,负铕异常一般显示为逐渐增强的趋势,但在发育有强烈的晚期钾长石脉的情况下,出现反弹减弱特征。硫化物(黄铜矿、黄铁矿和辉钼矿)的δ34SCDT变化范围为-2.23‰～3.75‰,基本呈塔式分布特征,主要为深源岩浆硫。