太行山南段有矿岩体与无矿岩体的对比

摘 要　 太行山南段是我国著名的矽卡岩铁矿成矿区域。区内有很多岩体‚有的有矿‚有的 无矿。选择了一些有代表性的岩体‚进行系统的岩石学研究工作‚总结了有矿、无矿两类岩 体的判别标志‚并对一些现象产生的原因进行了初步讨论。     

In-situ LA-ICP-MS trace elemental analyses of magnetite: Fe–Ti–(V) oxide-bearing mafic–ultramafic layered intrusions of the Emeishan Large Igneous Province,SW China

The Taihe, Baima, Hongge, Panzhihua and Anyi intrusions of the Emeishan Large Igneous Province (ELIP), SW China, contain large magmatic Fe–Ti–(V) oxide ore deposits. Magnetites from these intrusions have extensive trellis or sandwich exsolution lamellae of ilmenite and spinel. Regular electron microprobe analyses are insufficient to obtain the primary compositions of such magnetites. Instead, laser ablation ICP-MS uses large spot sizes (~ 40 μm) and can produce reliable data for magnetites with exsolution lamellae. Although magnetites from these deposits have variable trace element contents, they have similar multi-element variation patterns. Primary controls of trace element variations of magnetite in these deposits include crystallography in terms of the affinity of the ionic radius and the overall charge balance, oxygen fugacity, magma composition and coexisting minerals. Early deposition of chromite or Cr-magnetite can greatly deplete magmas in Cr and thus Cr-poor magnetite crystallized from such magmas. Co-crystallizing minerals, olivine, pyroxenes, plagioclase and apatite, have little influence on trace element contents of magnetite because elements compatible in magnetite are incompatible in these silicate and phosphate minerals. Low contents and bi-modal distribution of the highly compatible trace elements such as V and Cr in magnetite from Fe–Ti oxide ores of the ELIP suggest that magnetite may not form from fractional crystallization, but from relatively homogeneous Fe-rich melts. QUILF equilibrium modeling further indicates that the parental magmas of the Panzhihua and Baima intrusions had high oxygen fugacities and thus crystallized massive and/or net-textured Fe–Ti oxide ores at the bottom of the intrusive bodies. Magnetite of the Taihe, Hongge and Anyi intrusions, on the other hand, crystallized under relatively low oxygen fugacities and, therefore, formed net-textured and/or disseminated Fe–Ti oxides after a lengthy period of silicate fractionation. Plots of Ge vs. Ga + Co can be used as a discrimination diagram to differentiate magnetite of Fe–Ti–(V) oxide-bearing layered intrusions in the ELIP from that of massif anorthosites and magmatic Cu–Ni sulfide deposits. Variable amounts of trace elements of magmatic magnetites from Fe–Ti–(P) oxide ores of the Damiao anorthosite massif (North China) and from Cu–Ni sulfide deposits of Sudbury (Canada) and Huangshandong (northwest China) demonstrate the primary control of magma compositions on major and trace element contents of magnetite.     

新疆西天山查岗诺尔铁矿床磁铁矿和石榴石微量元素特征及其对矿床成因的制约

查岗诺尔大型磁铁矿床位于西天山阿吾拉勒东段,赋存于下石炭统大哈拉军山组安山岩及安山质火山碎屑岩之中,主体矿底板夹透镜状的大理岩,矿体主要为层状、似层状、透镜状。根据矿石组构和矿物共生特征,可以划分为岩浆期和热液期两个成矿期,后者包括矽卡岩和石英-硫化物两个亚成矿期,进一步可以细分为6个成矿阶段。岩浆期的磁铁矿∑REE很低,稀土配分模式大致呈轻稀土、重稀土较富集而中稀土亏损的U型,富Ti、V、Cr,表明铁质可能来自安山质岩浆的结晶分异作用; 矽卡岩亚成矿期的磁铁矿∑REE极低,略微富集LREE,其它稀土元素亏损强烈,贫Ti、V,略富集Ni、Co和Cu。矽卡岩亚期的含矿和无矿矽卡岩中的石榴石的稀土配分模式类似,∑REE含量相对较高,呈HREE富集、LREE亏损、弱正Eu异常的分布型式,显示了交代成因石榴石的特征,暗示与其共生的磁铁矿也是通过热液流体与围岩地层的交代反应生成的,铁质来自围岩。结合矿床地质与微量元素地球化学,认为查岗诺尔铁矿可能是岩浆型和矽卡岩型(主要)的复合叠加矿床。     

Petrological and Geochemical Constraints on the Protoliths of Serpentine‐Magnetite Ores in the Zhaoanzhuang Iron Deposit,Southern North China Craton

The uncommon Mg-rich and Ti-poor Zhaoanzhuang serpentine-magnetite ores within Taihua Group of the North China Craton(NCC) remain unclear whether the protolith was sourced from ultramafic rocks or chemical sedimentary sequences. Here we present integrated petrographic and geochemical studies to characterize the protoliths and to gain insights on the ore-forming processes. Iron ores mainly contain low-Ti magnetite(TiO_2 ~0.1 wt%) and serpentine(Mg#=92.42–96.55), as well as residual olivine(Fo=89–90), orthopyroxene(En=89–90) and hornblende. Magnetite in the iron ores shows lower Al, Sc, Ti, Cr, Zn relative to that from ultramafic Fe-Ti-V iron ores, but similar to that from metamorphic chemical sedimentary iron deposit. In addition, interstitial minerals of dolomite, calcite, apatite and anhydrite are intergrown with magnetite and serpentine, revealing they were metamorphic, but not magmatic or late hydrothermal minerals. Wall rocks principally contain magnesian silicates of olivine(Fo=83–87), orthopyroxene(En=82–86), humite(Mg#=82–84) and hornblende [XMg=0.87–0.96]. Dolomite, apatite and anhydrite together with minor magnetite, thorianite(Th-rich oxide) and monazite(LREE-rich phosphate) are often seen as relicts or inclusions within magnesian silicates in the wall rocks, revealing that they were primary or earlier metamorphic minerals than magnesian silicates. And olivine exists as subhedral interstitial texture between hornblende, which shows later formation of olivine than hornblende and does not conform with sequence of magmatic crystallization. All these mineralogical features thus bias towards their metamorphic, rather than magmatic origin. The dominant chemical components of the iron ores are SiO_2(4.77–25.23 wt%), Fe_2O_3 T(32.9–80.39 wt%) and MgO(5.72–27.17 wt%) and uniformly, those of the wall rocks are also SiO_2(16.34–48.72 wt%), Mg O(16.71–33.97 wt%) and Fe_2O_3 T(6.98–30.92 wt%). The striking high Fe-Mg-Si contents reveal that protolith of the Zhaoanzhuang iron deposit was more likely to be chemical sedimentary rocks. The distinct high-Mg feature and presence of abundant anhydrite possibly indicate it primarily precipitated in a confined seawater basin under an evaporitic environment. Besides, higher contents of Al, Ti, P, Th, U, Pb, REE relative to other Precambrian iron-rich chemical precipitates(BIF) suggest some clastic terrestrial materials were probably input. As a result, we think the Zhaoanzhuang iron deposit had experienced the initial Fe-Mg-Si marine precipitation, followed by further Mg enrichment through marine evaporated process, subsequent high-grade metamorphism and late-stage hydrothermal fluid modification.     

In-situ LA-ICP-MS trace elemental analyses of magnetite: The Bayan Obo Fe-REE-Nb deposit,North China

The Bayan Obo Fe-REE-Nb deposit in northern China is the world's largest light REE deposit, and also contains considerable amounts of iron and niobium metals. Although there are numerous studies on the REE mineralization, the origin of the Fe mineralization is not well known. Laser ablation (LA) ICP-MS is used to obtain trace elements of Fe oxides in order to better understand the process involved in the formation of magnetite and hematite associated with the formation of the giant REE deposit. There are banded, disseminated and massive Fe ores with variable amounts of magnetite and hematite at Bayan Obo. Magnetite and hematite from the same ores show similar REE patterns and have similar Mg, Ti, V, Mn, Co, Ni, Zn, Ga, Sn, and Ba contents, indicating a similar origin. Magnetite grains from the banded ores have Al + Mn and Ti + V contents similar to those of banded iron formations (BIF), whereas those from the disseminated and massive ores have Al + Mn and Ti + V contents similar to those of skarn deposits and other types of magmatic-hydrothermal deposits. Magnetite grains from the banded ores with a major gangue mineral of barite have the highest REE contents and show slight moderate REE enrichment, whereas those from other types of ores show light REE enrichment, indicating two stages of REE mineralization associated with Fe mineralization. The Bayan Obo deposit had multiple sources for Fe and REEs. It is likely that sedimentary carbonates provided original REEs and were metasomatized by REE-rich hydrothermal fluids to form the giant REE deposit.     

Did the massive magnetite “lava flows” of El Laco (Chile) form by magmatic or hydrothermal processes? New constraints from magnetite composition by LA-ICP-MS

The El Laco magnetite deposits consist of more than 98 % magnetite but show field textures remarkably similar to mafic lava flows. Therefore, it has long been suggested that they represent a rare example of an effusive Fe oxide liquid. Field and petrographic evidence, however, suggest that the magnetite deposits represent replacement of andesite flows and that the textures are pseudomorphs. We determined the trace element content of magnetite by laser ablation inductively coupled plasma mass spectrometry (LA-ICP-MS) from various settings at El Laco and compared them with magnetite from both igneous and hydrothermal environments. This new technique allows us to place constraints on the conditions under which magnetite in these supposed magnetite “lava flows” formed. The trace element content of magnetite from the massive magnetite samples is different to any known magmatic magnetite, including primary magnetite phenocrysts from the unaltered andesite host rocks at El Laco. Instead, the El Laco magnetite is most similar in composition to hydrothermal magnetite from high-temperature environments (>500 °C), such as iron oxide-copper-gold (IOCG) and porphyry-Cu deposits. The magnetite trace elements from massive magnetite are characterised by (1) depletion in elements considered relatively immobile in hydrothermal fluids (e.g. Ti, Al, Cr, Zr, Hf and Sc); (2) enrichment in elements that are highly incompatible with magmatic magnetite (rare earth elements (REE), Si, Ca, Na and P) and normally present in very low abundance in magmatic magnetite; (3) high Ni/Cr ratios which are typical of magnetite from hydrothermal environments; and (4) oscillatory zoning of Si, Ca, Mg, REE and most high field strength elements, and zoning truncations indicating dissolution, similar to that formed in hydrothermal Fe skarn deposits. In addition, secondary magnetite in altered, brecciated host rock, forming disseminations and veins, has the same composition as magnetite from the massive lenses. Euhedral magnetite lining both open-spaced veins in the brecciated host rock and along the walls of large, hollow chimneys in the massive magnetite lenses also displays oscillatory zoning and most likely formed by fluctuating composition and/or physio-chemical conditions of the fluid. Thus, the chemical fingerprint of magnetite from the supposed El Laco magnetite lava flows supports the hydrothermal model of metasomatic replacement of andesite lava flows, by dissolution and precipitation of magnetite from high-temperature fluids, rather than a magmatic origin from an effusive Fe oxide liquid.     

塔里木克拉通东北缘二叠纪镁铁质岩浆氧化物与硫化物成矿条件对比

塔里木克拉通东北缘坡北、磁海等地二叠纪幔源岩浆活动形成了镍钴硫化物矿床和铁钴氧化物矿床,两者赋矿镁铁-超镁铁岩体的年龄相近(290～260 Ma),主、微量元素和Sr-Nd-Hf同位素组成相似,分配系数接近的微量元素比值分布于相同趋势线,揭示两者岩浆源区相同,可能为俯冲板片流体交代的亏损地幔或软流圈地幔。两类矿床镁铁-超镁铁质岩中Co与Ni含量正相关,Co主要富集在基性程度高的岩石中;块状硫化物与磁铁矿矿石中Co与Ni相关性差,Co和Ni具有不同的富集机制,Co热液富集作用明显。北山镁铁-超镁铁杂岩体是地幔柱相关软流圈上涌,诱发俯冲板片交代的亏损岩石圈地幔发生部分熔融,形成的高镁母岩浆演化过程中经历壳源混染、硫化物饱和富集镍钴形成铜镍钴硫化物矿床,富铁母岩浆氧逸度高、富水,岩浆分离结晶磁铁矿、叠加热液作用富集钴,形成铁钴氧化物矿床。     

大火成岩省的成矿效应

大火成岩省(LIPs)是地质历史上重大的地质事件,巨量的岩浆堆积形成了丰富的矿产资源.按照成矿作用与LIPs事件的关系,将其划分为两种类型:①成矿作用与LIPs事件直接相关,两者时间一致或者成矿作用稍晚,该类型矿床可以作为LIPs的组成部分;②成矿作用与LIPs事件在时间上有明显的间断,但与LIPs有间接的成因联系.与...     

鄂东南程潮铁矿多世代叠加成矿作用:磁铁矿证据

湖北程潮铁矿是长江中下游成矿带最大的矽卡岩型铁矿床,主要产于早白垩世中酸性侵入岩与三叠系地层的接触带上。为了进一步探讨其富铁矿的形成机制,本文对该矿床中不同产状的磁铁矿和不同岩性侵入岩中的副矿物磁铁矿进行了详细的野外地质观察和显微结构分析,发现在多数磁铁矿矿石和矿化矽卡岩中均存在多世代磁铁矿矿化叠加现象。根据显微观察和BSE图像特征,程潮铁矿中热液期磁铁矿可以划分为四个世代,即Mt1、Mt2、Mt3、Mt4,其中Mt1颗粒表面不均匀,溶解-再沉淀现象明显;Mt2沿Mt1边缘生长,颗粒表面均匀,环带发育;Mt3沿Mt2边缘生长,颗粒表面均匀,环带不发育;Mt4多呈板条状或他形粒状,环带不发育。电子探针分析结果表明:同一世代不同产状或同一产状不同世代磁铁矿之间具有明显的成分差异,其中以Si、Al、Ca、Mg等含量较高的元素差异最为明显,而Ti、Cr、V、Zn、Ni等含量较低的元素差异则相对较小。这些差异性可能与磁铁矿结晶时成矿流体氧逸度、温度、元素浓度和水岩反应比例密切相关。不同世代热液磁铁矿与矿区岩体副矿物磁铁矿对比发现,二者在矿物结构和微量元素组成上存在明显差异,特别以微量元素Ti含量差异最大。程潮铁矿与不同成因类型矿床中的磁铁矿成分对比分析结果,进一步暗示出程潮铁矿中的磁铁矿为接触交代成因,并非矿浆成因。半定量模拟计算结果表明,Mt1、Mt2、Mt3在整个成矿过程中贡献了至少96%的铁质,对成矿起到了决定性作用。多世代磁铁矿矿化叠加过程不仅为揭示程潮大型铁矿的富集过程提供了重要依据,同时也为进一步理解矽卡岩型富铁矿的成矿机制提供了重要启示。     

火山-侵入杂岩带的成岩-成矿专属性

成岩成矿关系问题,特别是成矿作用与岩浆活动的专属性问题,一直是矿床学研究中的重要课题。粤东地区热液脉状锡、钨（多金属）矿床产于中生代花岗质火山岩、次火山岩和侵入岩组成的火山侵入杂岩带中,成岩年龄与成矿年龄一致,但矿床地质、矿床矿物流体包裹体和同位素地球化学没有相对标准来区分这些来源于岩浆作用不同阶段、不同产出状态岩浆岩的成矿物质特征,使得人们对于区内矿床成因的认识不一。文中运用稀土元素地球化学方法,着重探讨和对比了矿床矿石、蚀变岩石及与成矿有关的岩浆岩的稀土元素特征和配分型式,并进一步根据在不同压力条件下Ｃｌ－在熔体和热液间的分配系数实验数据和不同压力条件下热液与相应熔体平衡时的稀土元素分配系数实验结果,分别计算了厚婆坳锡矿床和莲花山钨矿床与矿区有关岩浆岩熔体平衡的热液中的稀土元素浓度并制出配分型式,再与矿床矿石及矿石矿物稀土元素配分型式比较,从而确定成矿与侵入阶段的花岗岩岩浆活动关系密切。区内矿床为岩浆热液矿床。研究结果表明,稀土元素作为热液流体来源的示踪剂能有效地确定火山侵入杂岩带的成岩成矿专属性。     

Chloriniferous minerals and certain problems in genesis of metasomatic magnetite ore deposits in Mul'ga-Burluk and Krasnokamenka groups,Eastern Sayan

Accumulations of magnetite ores in contacts of compositionally and chronologically different intrusions, with their different sedimentary host rocks and anomalously high chlorine content of certain minerals associated with the ores, suggest the possibility of a common source of iron in the magnetites and a common source of chlorine in the minerals, with allowances for a degree of assimilation of Fe and Cl from the hosts. The ferruginous Kuvay series at the base of the section may have functioned as the source of iron for the magnetite deposits. Chlorine, an important carrier of iron, under the given conditions may have been borrowed by the magmatic solutions from the saline rocks in the depths. —V.P. Sokoloff.     

四川杨柳坪Cu—Ni—PGE富矿体的成因及意义

Cu-Ni-PGE矿床绝大多数赋存在基性超基性岩岩体内部,在成因上主要与岩浆结晶分异熔离作用有关,岩浆期后或者独立的热液对于矿床的形成往往起叠加富集的作用。但在四川杨柳坪矿区,除了一般岩浆结晶分异熔离作用形成的Cu-Ni-PGE矿体之外,新近还发现存在独立的完全由热液形成的Cu-Ni-PGE矿体,矿体赋存在基性超基性岩体之外的大理岩片岩中,与基性超基性岩没有直接的关系,矿石品位很高,而且已经成为首要的开采对象。考虑到这样的富矿体在国外文献中鲜有报道,本文介绍其地质概况及初步的研究结果。     

西天山查岗诺尔铁矿矿床地质特征及矿床成因研究

查岗诺尔铁矿区位于西天山伊犁地块东北缘博罗科努山系的主脊线上,属中天山北缘活动陆缘带.该矿区位于破火山口的西北缘,矿体产状受火山穹窿构造的制约.赋矿围岩为下石炭统大哈拉军山组安山岩及安山质火山碎屑岩.该矿床的成矿期可划分为矿浆期和热液期,隐爆作用伴随成矿全过程.矿浆成矿期形成了浮渣状、斑点状、致密块状、贯入角砾岩状和阴...     

Rare Earth Elements as an Indicator to Origins of Skarn Deposits: Examples of the Kamioka Zn-Pb and Yoshiwara-Sannotake Cu(–Fe) Deposits in Japan

Abstract: Systematic data of rare earth elements (REEs) are presented in order to put some constraints on the origin of hydrothermal fluids responsible for two contrastive skarn deposits in Japan; the Kamioka Zn-Pb and Yoshiwara-Sannotake Cu(-Fe) deposits. Carbon and oxygen isotopic studies have demonstrated that the hydrothermal fluids responsible for the Kamioka Zn-Pb deposits are of meteoric water origin whereas those for the Yoshiwara-Sannotake Cu(-Fe) deposits are of magmatic water origin. The REE abundances of epidote skarn derived from aluminous rocks, garnet and clinopyroxene in calcic exoskarn derived from limestone, and interstitial calcite associated with sulfide minerals were determined for these contrastive skarn deposits by inductively-coupled plasma mass spectrometry (ICP-MS). A significant difference in the REE concentrations is not found between epidote skarn and aluminous original rock (plagioclase-clinopyroxene rock, called Inishi rock) from the Kamioka Zn-Pb deposits, indicating that the REEs are generally immobile during the formation of epidote skarn, and that the REE concentrations of the hydrothermal fluid are considerably low relative to the aluminous original rock. In contrast, the epidote skarn exhibits enrichment of Eu with increasing total REE concentrations relative to the aluminous original rock (quartz diorite) in the Yoshiwara-Sannotake Cu(-Fe) deposits, implying a contribution of magmatic fluid derived from granitoids during the skarn formation. Limestone generally has much lower REE concentrations related to surrounding aluminous rocks, and thus the REE concentrations of garnet and clinopyroxene in calcic exoskarn, originated from limestone, are variable due to the interaction with the hydrothermal fluids. The chondrite-normalized REE patterns of garnet, clinopyroxene, and interstitial calcite exactly provide useful information on origins of hydrothermal fluids. The REE patterns of these minerals from the Kamioka Zn-Pb deposits show lower (Pr/Yb)cn ratios, and negative Ce and Eu anomalies inherited from limestone with the decrease of This suggests that the hydrothermal fluids responsible for the Kamioka Zn-Pb deposits were depleted in REEs, and were not magmatic water in origin, but presumably meteoric one. In striking contrast, the REE patterns of exoskarn minerals and calcite from the Yoshiwara-Sannotake Cu(-Fe) deposits exhibit a positive Eu anomaly, and high (Pr/Yb)cn ratios with the considerable increase of σREE and the disappearance of negative Ce anomaly, implying that the fluids were dominantly of magmatic origin. The REE indices are very likely to be an excellent indicator to origins of the skarn deposits.     

宁芜和尚桥铁氧化物-磷灰石矿床(IOA)成矿过程研究:来自磁铁矿LA-ICP-MS原位分析的证据

铁氧化物-磷灰石矿床(IOA)是全球铁矿资源重要的供给矿床类型之一,受到国内外科研和矿产开采工作者的广泛关注。对铁氧化物-磷灰石矿床研究的争议主要集中在矿床成因上,即岩浆成因或者热液成因。作为一类具有多阶段成矿作用的矿床,IOA型矿床很难用热液或者矿浆成因予以简单概括,需要动态地看待成矿作用。和尚桥铁矿床是一个大型的铁氧化物-磷灰石(IOA)矿床,位于中国东部长江中下游多金属成矿带宁芜矿集区中。和尚桥铁矿床成矿作用含有三个清晰的磁铁矿矿化阶段,分别形成浸染状(Mt1)、角砾状(Mt2)和脉状(Mt3)矿石。对各阶段磁铁矿矿石中磁铁矿进行激光剥蚀等离子质谱(LA-ICP-MS)微区成分测试。在成矿过程中,从早到晚,磁铁矿表现出了从具有岩浆成因特征向具有热液成因特征的方向演化。磁铁矿中Mg和Al含量升高,Cr含量先降低后略微升高,Mn、Co、Ni和V含量先降低后升高,Mo和Sn含量先升高后降低的趋势,表明成矿过程中各阶段围岩及大气水对成矿流体的贡献不一。结合前人研究成果,我们认为和尚桥铁矿床中磁铁矿铁质的来源与安山质侵入岩密切相关,可能来源于岩浆不混溶作用形成的铁质富集流体(熔体),磁铁矿在高温热液环境中结晶沉淀。成矿过程具有多阶段性,推测在各成矿阶段间隙,富铁流体得到富集,同时地层物质不断的加入并导致了磁铁矿成分显示出越来越多的热液成因信息,地层物质(特别是膏盐层)对成矿过程起到了重要的控制作用。     

宁芜玢岩铁矿磷灰石的稀土元素特征

文章分析了宁芜玢岩铁矿 4种产状磷灰石的稀土元素组成 ,并与Kiruna型铁矿和斜长岩、苏长岩及钛铁霞辉岩中磷灰石的稀土元素组成进行了对比。结果表明产地和母岩不同的矿床中 ,它们的磷灰石稀土元素分布型式一致 ,以轻稀土富集和Eu负异常明显为特征 ,属陆相岩浆成因。前 3种产状磷灰石的ΣREE变化于 30 31.48×10 -6～ 12 0 80× 10 -6,第 4种产状磷灰石的ΣREE仅为 195 8× 10 -6,反映岩浆演化到热液的晚期阶段成矿溶液稀土元素含量较低。尽管辉长闪长玢岩与磷灰石的稀土元素分布型式一致 ,但辉长闪长玢岩无Eu异常或有弱Eu正异常 ,代表它们的地幔源区低氧逸度的还原环境 ,或反映氧逸度较高情况下的分离结晶作用。不混溶作用形成的矿浆在冷凝过程中 ,Eu2 + 优先被透辉石捕获 ,使得稍晚结晶的磷灰石产生负Eu异常     

REE in fluid inclusions of quartz from gold deposits of north-eastern Russia

Inductively coupled plasma-mass spectrometry (ICP-MS) has been used to determine rare earth element concentrations in aqueous solutions extracted from fluid inclusions. Quartz has been sampled from ores of three major types of polygenic gold hydrothermal systems of North-Eastern Russia: (1) gold-quartz-sulphide (Au-Q, Nezhdaninsk); (2) gold-antimony (Au-Sb, Sarylakh) and (3) intrusion-related gold-bismuth-siderite-polysulphide (Au-Bi-Sid, Arkachan) large deposits located in terrigenous rocks of the Verkhoyansk fold belt. The total concentration of REE in the fluid inclusions is not high (up to 52 ppm). The contribution of LREE dominates in REE balance (??LREE/??HREE=7.4?C112.1). The chondrite-normalized REE patterns of inclusion fluids for the Au-Q and Au-Bi-Sid deposits are characterized by LREE enrichment with a positive or negative Eu anomaly. REE patterns for the regenerated quartz from Au-Sb deposits are characterized by pronounced differentiation between light and heavy lanthanides in fluid inclusions. Significant total REE concentration decreasing (on 1?C2 order) from early to late stages of Nezhdaninsk and Arkachan deposits is revealed. The positive correlations of total REE concentrations with Rb, Cs, Li and B contents in fluid inclusions are shown. The REE distribution in fluid inclusions can be used as indicators of the contribution of magmatic fluid in the hydrothermal system.     

黔东松桃地区李家湾锰矿床地质、地球化学特征及成因信息

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,TiO2、Al2O3、K2O、Na2O含量较低,含锰岩系富集Rb、Ba、Th、Cs、Zr、Ga等元素;SiO2/Al2O3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、∑REE和∑HREE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。     

Gushan magnetite–apatite deposit in the Ningwu basin, Lower Yangtze River Valley, SE China: Hydrothermal or Kiruna-type?

The Gushan deposit is one of the typical magnetite–apatite deposits associated with dioritic porphyries in the Lower Yangtze River Valley belt of the eastern Yangtze craton. The origin of this deposit is still uncertain and remains a controversial issue. Divergent opinions are centered on whether the iron deposits are magmatic or hydrothermal in origin. However, our field observations and mineralogical studies, combined with previous published petrological and geochemical features strongly suggest that the main ore bodies in the Gushan magnetite–apatite deposit are magmatic. Specific evidence includes the existence of gas bubbles, tubes, and miarolitic and amygdaloidal structures, melt flow banding structure and the presence of “ore breccia”. New electron microprobe analyses of the pyroxene phenocrysts of the dioritic porphyry genetically associated with the Gushan magnetite–apatite deposit show that the Fe contents in the evolving magma dramatically decrease, and then gradually increase. Because there is no evidence of mafic magma recharge, this scenario (decreasing Fe) could be plausibly interpreted by Fe-rich melts separated from Fe-poor silicate melts, i.e., liquid immiscibility was triggered by minor addition of phosphorus by crustal contamination. The occurrence of massive iron ore bodies can be satisfactorily explained by the immiscible Fe-rich melt with enormous volatile contents was driven to the top of the magma chamber due to the low density. The hot and volatile-rich iron ore magma was injected along fractures and spaces between the dioritic intrusions and wall-rocks, and led to an explosion near the surface, resulting in the immediate fragmentation of the roof of the intrusion and wall-rocks, forming brecciated ores. Moreover, other types of ores can be considered as a result of post-magmatic hydrothermal activities. Our proposed metallogenic model involving the Kiruna-type mineralization is consistent with the observed phenomenon in the Gushan deposit.     

新疆北部幔源岩浆矿床的类型、时空分布及成矿谱系

新疆北部与幔源岩浆有关的矿床种类齐全,成矿环境复杂,时代和类型繁多,在中国乃至世界颇具特色。主要矿床类型包括铬铁矿矿床、钒钛磁铁矿矿床、铜镍硫化物矿床、铂族元素(PGE)矿床、铜镍-钒钛铁复合型矿床、含钴磁铁矿矿床、玄武岩自然铜矿床、热液型钴-多金属矿床,以及非金属矿床等。按照含矿地质体的类型,可分为6种类型:蛇绿岩型、层状杂岩型、小侵入体型、阿拉斯加型、浅成岩型和喷出岩型。这些幔源岩浆矿床可划分为3个成岩成矿系列:铜镍系列、钛铁系列和铬铁系列。钛铁系列以碱性层状岩体型钒钛磁铁矿、铁磷矿为代表,岩石具有明显的富Fe特征,属于碱性富铁质的高钛玄武岩系列;铜镍系列以小侵入体型铜镍矿、阿拉斯加型铜镍-PGE矿为代表,岩石属于铁质的拉斑玄武岩-钙碱性系列;铬铁系列主要为蛇绿岩型铬铁矿,岩石具富Mg贫Fe特征,属于镁质系列。3个系列的岩浆都具有亏损地幔源特征,可能都与地幔柱活动有关;岩浆源区富含相应的成矿元素,是形成3个系列矿床相应成矿地质体的主要条件。3个系列矿床的成矿机制可分为深部熔离/岩浆分异、就地分凝、矿浆贯入、岩浆热液等过程。根据各系列矿床之间存在的紧密联系,建立了与幔源岩浆作用有关的3个系列矿床综合模式: 亏损地幔部分熔融产生的幔源岩浆在上升过程中发生熔离/分异,分离为3个系列,由于外部物质加入在地壳深部发生分异和熔离,在不同深度富集形成铬铁矿、钒钛磁铁矿和铜镍硫化物矿床,临近地表时流体富集和分离成含矿流体,分别形成浅成岩型磁铁矿和喷出岩型自然铜矿。新疆北部各类幔源岩浆矿床从早到晚主要产于3期构造阶段/构造类型: 大陆裂解期、板块俯冲期、碰撞/后碰撞造山期(又分3个阶段: 碰撞后伸展阶段、幔柱叠加造山阶段、后碰撞结束阶段)。