夏日哈木岩浆硫化物矿床中钴和镍关键金属的赋存状态及分布规律

东昆仑夏日哈木超大型岩浆镍钴硫化物矿床的工业价值，不仅取决于矿石中Co、Ni的含量，还取决于钴和镍关键金属的赋存状态和分布规律。笔者利用全自动矿物分析系统钻孔样品分析，确定Co和Ni在样品中有2种赋存状态：独立钴、镍矿物和含Co、Ni矿物。对钴、镍金属矿物进行原位主、微量元素分析发现，Co在钴、镍金属矿物中含量由高到低为：辉砷钴矿>砷镍矿、方硫铁镍矿、镍黄铁矿>红砷镍矿、磁铁矿>磁黄铁矿、黄铜矿；Ni在钴、镍金属矿物中含量由高到低为：砷镍矿、红砷镍矿>硫铋镍矿、方硫铁镍矿、镍黄铁矿>辉砷钴矿>磁铁矿、磁黄铁矿、黄铜矿。选择钻孔中体积分数占比最高的磁黄铁矿、镍黄铁矿和黄铜矿，进行原位核–边微量元素及面扫描分析发现，Co、 Ni在镍黄铁矿和黄铜矿单颗粒尺度上是均一分布的，两种矿物的Co/Ni值变化不大，表明矿物没有受到热液作用影响。然而，Ni在磁黄铁矿中分布不均一，并且矿物的Co/Ni值变化较大，表明磁黄铁矿对热液作用更为敏感。矿物原位主、微量元素分析结果显示，镍黄铁矿中的Co、Ni含量与镍、钴独立矿物接近，远超岩体中其他含钴、镍金属硫化物。因此，含Ni...     

金川铜镍硫化物矿床磁黄铁矿矿物学特征及成因意义

金川铜镍硫化物矿床矿石类型主要为浸染状矿石、海绵陨铁状矿石及块状矿石。采用矿相显微镜观察、磁性胶体浸润与电子探针分析等方法,对3种类型矿石中磁黄铁矿的结构状态、共生组合与成分特征作了研究,探讨了矿石成因及成矿过程。在浸染状矿石与海绵陨铁状矿石中,磁黄铁矿为单纯的六方(NC型)磁黄铁矿,或者六方与单斜(4C型)磁黄铁矿构成的不规则状交生体。这2类矿石中磁黄铁矿的成因很可能是岩(矿)浆中S含量低,且高温结晶后缓慢降温,后期又受到了富硫和/或高氧逸度流体的交代作用。在Ⅱ矿区块状矿石中,单斜与六方磁黄铁矿构成平行叶片状交生体,表明六方磁黄铁矿在高温下结晶后温度曾快速下降,这期间仅出溶了微量的黄铁矿,而当温度下降到254℃以下时,发生了六方磁黄铁矿中单斜磁黄铁矿出溶作用。磁黄铁矿的结晶类型、金属原子(Fe、Ni、Cu、Co)与硫原子比值M/S演化等佐证了块状矿石晚期贯入成因。依据Fe-S系统相图拟合曲线计算得到块状矿石中六方磁黄铁矿结晶温度为743~518℃,且在结晶过程中,硫逸度logf(S2)曾从0.427降至-3.767。     

辽宁东平金矿床地质特征及找矿方向

南秦岭南部构造带具备较好的金矿成矿条件与成矿背景，是该区域规模较大金矿带.金沟矿段是黄龙金矿床最主要的组成部分，该矿段矿石中磁黄铁矿和黄铁矿发育，其中磁黄铁矿矿石是矿床中含量最高的硫化物矿石.磁黄铁矿存在两种产出状态，分别为早期形成的呈浸染状、团块状分布的磁黄铁矿与晚期形成的脉状磁黄铁矿.成分分析结果表明以单斜磁黄铁矿为主.该矿床属中-低温矿床.微量元素结果显示富Co贫Ni，与金矿化关系密切.在含金性方面，脉状产出的磁黄铁矿优于团块状分布的磁黄铁矿，且脉体越细含金性越好，因此细脉状磁黄铁矿可作为该区重要的找矿标志.     

长春市东风硫铁矿的矿体特征及成因

通过成矿地质条件分析,吉林省长春市二道区东风硫铁矿矿体呈斜列式分布于石英闪长岩与围岩接触带及围岩外带不同围岩界面上,矿石自然类型:主要为含铜磁黄铁矿,其次为黄铁矿、黄铜矿及磁铁矿;矿石工业类型为:高中温热液型、矽卡岩型。磁铁矿和磁黄铁矿在成矿作用上都与石英闪长岩体有关,矿床的成矿作用表现为多阶段性。     

攀西会理县白草钒钛磁铁矿床磁黄铁矿矿物学特征及成因

攀西会理县白草矿区以钒钛磁铁矿而闻名,但该钒钛磁铁矿床中还发育一定规模的富钴硫化物矿石,对该类型矿石的形成机制研究还不深入.本文选择白草矿区产出的浸染状、致密块状、网脉状和斑杂状富钴硫化物矿石中的磁黄铁矿做为研究对象,在野外地质调查的基础上,通过矿相学和电子探针等方法对磁黄铁矿的成分和晶体类型进行研究.利用磁性胶体可以鉴别磁黄铁矿晶体类型的原理,确定了研究区的磁黄铁矿具有单斜磁黄铁矿(Mpo)和六方磁黄铁矿(Hpo)两种晶体类型,厘定了细脉状、叶片状和不规则状交生体.通过研究磁黄铁矿中各主量元素特征,计算了磁黄铁矿形成温度、硫逸度和M/S值等参数.将磁黄铁矿形成划分岩浆成矿期(熔离阶段、接触交代阶段)和热液成矿期,并初步厘定了4类磁黄铁矿生成顺序:首先形成浸染状矿石磁黄铁矿与致密块状矿石磁黄铁矿,其次形成斑杂状矿石磁黄铁矿,最后形成网脉状矿石磁黄铁矿.     

金川超大型铜镍矿床钴的赋存状态与富集过程研究

金川矿床位于龙首山隆起带东段，是中国最大的岩浆镍钴（铂族元素）矿床。该矿床中最重要的金属硫化物组合是磁黄铁矿、镍黄铁矿和黄铜矿，仅局部含有微量的辉钴矿等独立钴矿物。全岩成矿元素分析显示：矿石中Co与S、Ni之间呈良好的正相关性，与As相关性较差，Co/Ni随硫化物含量的增加而降低。电子探针分析结果表明：镍黄铁矿中Co含量较高，其含量为0.32%～1.93%，平均为0.81%；磁黄铁矿和黄铜矿（方黄铜矿）中Co的含量较低，变化范围分别为0.02%～0.11%和0.01%～0.08%。元素面扫描结果表明：Co含量较高的部位与镍黄铁矿范围完全一致，说明Co主要赋存于镍黄铁矿中。金川矿床整体Co/Ni平均值为0.042，与全球典型橄榄岩相地幔Co/Ni值（0.055）相似，表明其岩浆源区主要为橄榄岩相。高程度的部分熔融可能是导致其母岩浆中Co绝对含量较高，但Co/Ni值相对较低的原因之一。硫化物熔离时，Co更倾向于进入硫化物；但相对于Ni，进入硫化物的Co较少，导致不同矿石类型之间S含量与Co/Ni值之间呈明显的负相关性。硫化物分离结晶作用进一步促使Co向镍黄铁矿中富集。     

南秦岭黄龙金矿磁黄铁矿标型矿物学特征及含金性研究

南秦岭南部构造带具备较好的金矿成矿条件与成矿背景,是该区域规模较大金矿带.金沟矿段是黄龙金矿床最主要的组成部分,该矿段矿石中磁黄铁矿和黄铁矿发育,其中磁黄铁矿矿石是矿床中含量最高的硫化物矿石.磁黄铁矿存在两种产出状态,分别为早期形成的呈浸染状、团块状分布的磁黄铁矿与晚期形成的脉状磁黄铁矿.成分分析结果表明以单斜磁黄铁矿为主.该矿床属中-低温矿床.微量元素结果显示富Co贫Ni,与金矿化关系密切.在含金性方面,脉状产出的磁黄铁矿优于团块状分布的磁黄铁矿,且脉体越细含金性越好,因此细脉状磁黄铁矿可作为该区重要的找矿标志.     

吉林小西南岔金铜矿床主要金属矿物的成因矿物学特征

本文通过对矿床中主要金属矿物黄铁矿、磁黄铁矿、黄铜矿的成因矿物学研究,指出黄铁矿中Co/Ni、S/Se、Se/Te、Au/Ag比值均显示出岩浆热液成因特征;黄铁矿、磁黄铁矿、黄铜矿的硫同位素组成具深源岩浆源流特征,并随成矿深度发生有规律的变化;黄铁矿、磁黄铁矿、黄铜矿中某些微量元素质量分数北山矿段与南山矿段之间有一定差...     

金川岩浆铜镍硫化物矿床中的镍钴分布规律及其控制因素

幔源岩浆形成与演化过程中镍(Ni)、钴(Co)具有相似的地球化学行为。金川岩浆铜镍硫化物矿床以Ni、铜(Cu)为主要矿种,Co为伴生,Ni、Co在金川矿床中的空间分布规律同步变化,然而其Ni/Co比值(36.7)远高于地幔值(18.2)。这表明在金川矿床形成过程中Ni-Co发生了共生分离,但Ni-Co分布特征尚不清楚、其控制因素尚不明确。本文对该矿床中主要矿石矿物的Ni、Co含量及分布进行了系统总结,并与脉石矿物进行对比。结果表明矿石矿物镍黄铁矿是最重要的含Ni、Co矿物相,其Ni、Co含量均远高于磁黄铁矿、黄铜矿及脉石矿物。对于脉石矿物,Ni在橄榄石、磁铁矿、铬铁矿内的含量依次降低,在斜方辉石与单斜辉石中含量最低。Co则在铬铁矿、橄榄石内含量依次降低,在斜方辉石、单斜辉石、磁铁矿中含量最低。在硫化物熔离过程中,Ni在硫化物熔体内相容性更强,更加倾向于进入硫化物熔体,使Ni显著富集于硫化物熔体内,而Co则相对富集于硅酸盐熔体内,由此导致Ni-Co解耦。硫化物冷却结晶过程中,Ni、Co倾向于进入最早结晶的单硫化物固溶体(MSS),并在随后分解作用中集中进入镍黄铁矿内,使镍黄铁矿成为金川矿...     

川西盐边县红格钒钛磁铁矿中镍钴硫化物的铂族元素地球化学特征

世界上尚未发现过V—Ti磁铁矿和硫化物矿床共生,在川西延边县红格矿床,原认为在矿体底部存在一个富含PGE、Cr的层位,但我们在多个钻孔中取样分析,均未发现。然而我们发现在红格矿床白草矿段存在大量的块状硫化物矿体,硫化物贯入铁矿后,可叠加形成镍—钴—铁矿体。块状硫化物矿石主要成分为磁黄铁矿(94%)、镍黄铁矿、黄铜矿,少量普通辉石、次透辉石、古铜辉石、普通角闪石、金云母、磁铁矿、钛铁矿、中长石等。其中Ni 0.72%～0.90%,Co 0.10%。主要赋存在磁黄铁矿中。通过铂族元素分析发现,块状硫化物(磁黄铁矿)Cu/Pd为12908～15109,含硫化物3%的贯入式铁矿Cu/Pd为24520。Cu/Pd比值远高于原始地幔值,暗示有少量硫化物在岩浆源区的残留。同时,在铁矿形成之前已发生过硫化物的熔离。红格地区样品的Pd/Ir值变化范围为2.8～30主要集中在8～14附近,可见红格地区经历过很强的岩浆结晶作用。红格矿床的PGE元素已发生明显的分异现象,暗示硫化物与铁可能在流体中有共同富集的情况。不同矿段的PGE含量有明显差异,很难用一个岩浆房进行解释,可能是多级岩浆房岩浆演化的产物。暗示深部还有岩浆房,在地下深处,还可以找Ni—Cu—PGE和Fe—Ti—V矿床。     

内蒙古北山东段珠斯楞铜金矿床的基本特征

珠斯楞铜金矿位于晚古生代板块缝合部位,产于华力西晚期花岗斑岩和闪长玢岩岩脉中,通过矿区基础地质、物化探等的研究,确定有2个矿体、1个矿化体。主要矿石矿物为黄铜矿、黄铁矿、磁黄铁矿、闪锌矿、方铅矿、毒砂等,呈浸染状、细脉状分布。化探垂直分带性表明,Au和前缘晕元素在浅部富集,Cu在中深部富集。矿床为斑岩型,主要发育青磐岩化带,其可作为区域上大型斑岩铜矿的找矿标志。     

中国硫铁矿成矿学演化的物质基础

硫铁矿成矿物质有多种来源。硫－铁以及杂质元素在地壳发展进程中，随硫化铁成矿作用不同阶段物理化学条件的改变，发生了相应的变化。硫铁矿主要化学组分的成矿演化，可划分为热液、沉积、生物、变质及多成因复合五种模式。     

河北寿王坟铜矿黄铜矿铷锶同位素年龄测定及其成矿意义

本文以黄铜矿及其共生矿物为定年对象,采用亚样品取样和铷锶等时线定年方法测定了寿王坟铜矿的成矿时代.分析测试获得黄铜矿 黄铁矿单矿物组合的等时线年龄113.6Ma,黄铜矿 夕卡岩组合的等时线年龄112.3Ma和黄铜矿 黄铁矿 夕卡岩组合的等时线年龄115.0Ma.对比同一矿石亚样品,认为河北寿王坟夕卡岩型铜矿成矿时代为111.0Ma.实验表明,采用矿石亚样品取样方法和直接测定金属硫化物单矿物铷-锶同位素年龄可以有效地确定矿床成矿时代.     

Zircon U–Pb and pyrite Re–Os age constraints on pyrite mineralization in the Yinjiagou deposit,China

We report new zircon U–Pb and pyrite Re–Os geochronological studies of the Yinjiagou poly-metallic deposit, sited along the southern margin of the North China Craton (SMNCC). In this deposit, pyrite, the most important economic mineral, is intergrown/associated with Mo, Cu, Au, Pb, Zn, and Ag. Prior to our new work, the age of chalcopyrite–pyrite mineralization was known only from its spatial relationship with molybdenite mineralization and with intrusions of known ages. The U–Pb and Re–Os isotope systems provide an excellent means of dating the mineralization itself and additionally place constraints on the ore genesis and metal source. Zircons separated from the quartz–chalcopyrite–pyrite veins include both detrital and magmatic groups. The magmatic zircons confine the maximum age of chalcopyrite–pyrite mineralization to 142.0 ± 1.5 Ma. The Re–Os results yield an age of 141.1 ± 1.1 Ma, which represents the age of the chalcopyrite–pyrite mineralization quite well. The common Os contents are notably low (0.5–20.1 ppt) in all samples. In contrast, the Re contents vary considerably (3.0–199.2 ppb), most likely depending on intensive boiling, which resulted in an increase of Re within the pyrite. This study demonstrates that the main chalcopyrite–pyrite mineralization occurred late in the magmatic history and was linked to a deeper intrusion involving dominant mantle-derived materials. This mineralization event might be related to the Early Cretaceous lithospheric destruction and thinning of the SMNCC.     

Tellurium-Bearing Mineralization in Clastic Ores at the Yubileynoe Copper Massive Sulfide Deposit (Southern Urals)

At the well-preserved Yubileynoe VMS deposit (Southern Urals), sulfide breccias and turbidites host abundant tellurides represented by hessite, coloradoite, altaite, volynskite, stützite, petzite, and calaverite, as well as phases of the intermediate tellurobismuthite → rucklidgeite solid solution. Three telluride generations were highlighted: (1) primary hydrothermal tellurides in fragments of chalcopyrite and sphalerite of chalcopyrite-rich black smoker chimneys; (2) authigenic tellurides in pseudomorphic chalcopyrite and chalcopyrite veins after fragments of colloform and granular pyrite; and (3) authigenic tellurides in pyrite nodules. Authigenic tellurides are widespread in pyrite-chalcopyrite turbidites. Primary hydrothermal and authigenic tellurides are less common in sulfide turbidites and gritstones with fragments of sphalerite-pyrite, pyrite-sphalerite paleosmoker chimneys and clasts of colloform and fine-grained seafloor hydrothermal crusts. Siliceous siltstones intercalated with sulfide turbidites contain pyrite nodules, whose peripheral parts contain inclusions of epigenetic tellurides. It is assumed that Te for authigenic tellurides originated from fragments of colloform pyrite and hydrothermal chalcopyrite of pyrite-chalcopyrite chimneys, which dissolved during the postsedimentation processes. The main Te concentrators in clastic ores include pseudomorphic chalcopyrite, which inherits high Te, Bi, Au, Ag, Co, Ni, and As contents from the substituted colloform pyrite, and varieties of granular pyrite containing microinclusions of tellurobismuthite (Bi, Te), petzite (Au, Ag, Te), altaite (Pb, Te), coloradoite, and hessite (Ag, Te).

     

云南个旧大白岩铜锡矿床铜锡与共伴生组分赋存状态研究

位于个旧市南部的卡房矿田大白岩铜锡矿是个旧地区重要的铜矿产出地段,共伴生锡、金、银、钨、铋等有益组分。通过光薄片鉴定、电子探针测试和人工重砂分析发现,大白岩铜锡矿铜主要赋存状态为黄铜矿,其次为银黝铜矿和黝锡矿;锡主要以锡石,黝锡矿形式存在;伴生组分钨主要为白钨矿,铋元素以辉铋矿和自然铋存在,硫主要为磁黄铁矿、黄铁矿,其次为黄铜矿等硫化物,磁黄铁矿和黄铜矿中含有微量金。     

Alteration and regeneration of sulfides by reaction with oxidizing hydrothermal solutions

Reactions between sulfides of heavy metals and solutions of hexavalent uranium sulfate at pH about 2, in the range of 200-360°C, led to replacement of pyrrhotite by marcasite-pyrite aggregate, development of bornite and pyrite after chalcopyrite, growth of regenerated chalcopyrite on the periphery of uranium oxides, replacement of chalcopyrite by bornite (with the accompanying complications, fig. 3), redepositions of chalcocite and native copper, and, in experiments with pyrite-galena and galena-marmatite pairs, redepositions of the minerals with the corresponding growth of pyrite. —V.P. Sokoloff.     

Study of galvanic interactions between pyrite and chalcopyrite in a flowing system: implications for the environment

When galvanic interactions between pyrite and chalcopyrite occur in solution, pyrite, with the higher rest potential, acts as a cathode and is protected whereas chalcopyrite, with the lower rest potential, acts as an anode and its oxidation is increased. In this work a three-electrode system was used to investigate the corrosion current density and mixed potential of a galvanic cell comprising a pyrite cathode and a chalcopyrite anode in a flowing system. The results showed that with increasing concentration of ferric ion in the solution, with increasing acidity, and with increasing flow rate of the solution, the corrosion current density increased and the mixed potential of the galvanic cell became more positive. These experimental results are of direct significance to the control of environmental pollution in mining activity. By using the galvanic model, mixed potential theory, and the Butler–Volmer equation, the experimental results were explained theoretically.     

青海纳日贡玛斑岩钼(铜)矿床:蚀变

通过对纳日贡玛斑岩钼（铜）矿床的蚀变类型的详细研究,识别了矿床蚀变的3种主要类型：钾硅酸盐化、青磐岩化和长石分解蚀变.前二者为矿区早期形成的蚀变,长石分解蚀变形成于晚期.钾硅酸盐化蚀变主要以黑云母化、钾长石化为特征,青磐岩化以脉状绿泥石、绿帘石、方解石等蚀变矿物的发育为基本特征,长石分解蚀变则发育绢云母、高岭土、方解石、硬石膏等矿物.研究认为矿化与石英-辉钼矿±硬石膏±黄铜矿±黄铁矿脉、辉钼矿±黄铁矿±黄铜矿脉有较为密切的联系.