Partizansky base-metal skarn deposit, Dal’negorsk ore district, Russia: Stages of ore formation, mineral assemblages, and typomorphism of fahlore

As indicated by mineralogical, geochemical, and structural-textural data, the base-metal skarn ore at the Partizansky deposit was formed during two stages (base-metal skarn and silver-sulfosalt), which were separated by intrusion of basaltic dikes. The bulk of the base-metal ore was deposited at the first stage, which comprises four sequential mineral assemblages: skarn-silicate, quartz-arsenopyrite, productive galena-sphalerite, and pyrrhotite-pyrite-chalcopyrite. The mineralization of the second stage was mainly confined to the upper margins of orebodies and pertains to the sulfosalt-galena-chalcopyrite assemblage, which was super-imposed on minerals of the first stage. The vertical mineralogical-geochemical zoning of the deposit is telescopic (related to the formation of the late silver-sulfosalt mineralization) and facies (typical of the early skarn and base-metal assemblages). The zoning of the skarn-silicate assemblage is expressed in the metasomatic replacement of skarn by quartz and calcite in the uppermost zone of skarn bodies and is emphasized by variation of the mineral composition throughout the skarn column, for instance, by the distinct updip enrichment of hedenbergite in manganese. The vertical zoning of the productive assemblage is emphasized by variations in the ratio of sphalerite to galena (the Pb/Zn ratio in the ore increases upward from 0.1 to 1), changes in mineral assemblages, and compositional variation of major ore-forming and minor minerals. In particular, galena from the deep levels is extremely enriched in Bi and Ag, while that from the upper levels is almost completely devoid of isomorphic admixtures. Fahlore displays updip enrichment in Sb, Ag, and Fe and corresponding depletion in Cu and Zn. The vertical chemical variations in fahlore are caused by the specific geological setting of ore deposition, the composition of the ore-forming solutions, and the physicochemical conditions of their transportation and ore deposition.     

江西武山铜矿床形成过程:来自岩相学和矿物学的证据

江西武山铜矿床是长江中下游地区具有代表性的叠加复合矿床之一。文章选取武山铜矿床典型剖面为研究对象,在野外地质调研和室内岩相学研究的基础上,识别出层状硫化物型、层状矽卡岩型和接触交代矽卡岩型三类矿体,及相对应的3种类型矿石。3类矿石在矿物组合、结构构造和矿物学特征等方面有明显差异,分别显示出原生沉积、叠加改造和岩浆热液成因特征。选择代表性脉石矿物和矿石矿物进行矿物化学研究,认为石榴子石是岩浆期后热液渗滤交代作用的产物,层状矽卡岩中石榴子石相对富Fe,而接触交代矽卡岩中石榴子石相对富Al;矿区内存在2类黄铁矿,即胶状黄铁矿和粒状黄铁矿,分别对应原生沉积成因和岩浆热液交代成因;磁铁矿是与矽卡岩有关的岩浆期后热液交代作用的产物,层状矽卡岩中磁铁矿相对富Mg O和Mn O,贫Al2O3,受地层影响明显,而接触交代矽卡岩中磁铁矿相对富Al2O3,贫Mg O和Mn O,受岩浆岩影响明显。武山铜矿床的形成经历了原生沉积作用、岩浆热液交代作用及叠加改造作用等复杂成矿过程。     

Porphyry-Style Petropavlovskoe Gold Deposit,the Polar Urals: Geological Position,Mineralogy, and Formation Conditions

Geological and structural conditions of localization, hydrothermal metasomatic alteration, and mineralization of the Petropavlovskoe gold deposit (Novogodnenskoe ore field) situated in the northern part of the Lesser Ural volcanic–plutonic belt, which is a constituent of the Middle Paleozoic island-arc system of the Polar Urals, are discussed. The porphyritic diorite bodies pertaining to the late phase of the intrusive Sob Complex play an ore-controlling role. The large-volume orebodies are related to the upper parts of these intrusions. Two types of stringer–disseminated ores have been revealed: (1) predominant gold-sulfide and (2) superimposed low-sulfide–gold–quartz ore markedly enriched in Au. Taken together, they make up complicated flattened isometric orebodies transitory to linear stockworks. The gold potential of the deposit is controlled by pyrite–(chlorite)–albite metasomatic rock of the main productive stage, which mainly develops in a volcanic–sedimentary sequence especially close to the contacts with porphyritic diorite. The relationships between intrusive and subvolcanic bodies and dating of individual zircon crystals corroborate a multistage evolution of the ore field, which predetermines its complex hydrothermal history. Magmatic activity of mature island-arc plagiogranite of the Sob Complex and monzonite of the Kongor Complex initiated development of skarn and beresite alterations accompanied by crystallization of hydrothermal sulfides. In the Early Devonian, due to emplacement of the Sob Complex at a depth of approximately 2 km, skarn magnetite ore with subordinate sulfides was formed. At the onset of the Middle Devonian, the large-volume gold porphyry Au–Ag–Te–W ± Mo,Cu stockworks related to quartz diorite porphyry—the final phase of the Sob Complex— were formed. In the Late Devonian, a part of sulfide mineralization was redistributed with the formation of linear low-sulfide quartz vein zones. Isotopic geochemical study has shown that the ore is deposited from reduced, substantially magmatic fluid, which is characterized by close to mantle values δ³⁴S = 0 ± 1‰, δ¹³C =–6 to–7‰, and δ¹⁸O = +5‰ as the temperature decreases from 420–300°C (gold–sulfide ore) to 250–130°C (gold–(sulfide)–quartz ore) and pressure decreases from 0.8 to 0.3 kbar. According to the data of microanalysis (EPMA and LA-ICP-MS), the main trace elements in pyrite of gold orebodies are represented by Co (up to 2.52 wt %), As (up to 0.70 wt %), and Ni (up to 0.38 wt %); Te, Se, Ag, Au, Bi, Sb, and Sn also occur. Pyrite of the early assemblages is characterized by high Co, Te, Au, and Bi contents, whereas the late pyrite is distinguished by elevated concentrations of As (up to 0.7 wt %), Ni (up to 0.38 wt %), Se (223 ppm), Ag (up to 111 ppm), and Sn (4.4 ppm). The minimal Au content in pyrite of the late quartz–carbonate assemblage is up to 1.7 ppm and geometric average is 0.3 ppm. The significant correlation between Au and As (furthermore, negative–0.6) in pyrite from ore of the Petropavlovskoe deposit is recorded only for the gold–sulfide assemblage, whereas it is not established for other assemblages. Pyrite with higher As concentration (up to 0.7 wt %) is distinguished only for the Au–Te mineral assemblage. Taking into account structural–morphological and mineralogical–geochemical features, the ore–magmatic system of the Petropavlovskoe deposit is referred to as gold porphyry style. Among the main criteria of such typification are the spatial association of orebodies with bodies of subvolcanic porphyry-like intrusive phases at the roof of large multiphase pluton; the stockwork-like morphology of gold orebodies; 3D character of ore–alteration zoning and distribution of ore components; geochemical association of gold with Ag, W, Mo, Cu, As, Te, and Bi; and predominant finely dispersed submicroscopic gold in ore.     

东天山中段区域化探异常评价方法研究

本文利用1/20万区域化探数据,研究了东天山中段地区针对不同类型铜矿化的元素组合异常圈定方法。选择典型（含）铜矿床及其周围地段的化探测量点为建模样本,通过因子分析,查明针对不同矿化类型的指示元素定量组合;以因子得分为综合指标,用泛克里格剩余值圈定化探异常。结果得到3个元素组合：Cu-Co-Ni-Mn-V-Fe-Cr组合...     

A Preliminary Study on Exhalative Mineralization in Permian Basins, the Southern Segment of the Da Hinggan Mountains, China – Case Studies of the Huanggang and Dajing Deposits–

Abstract: The southern segment of the Da Hinggan Mountains is a well‐known tin–polymetallic metallogenic belt of North China with Jurassic‐Cretaceous volcanic–plutonic rocks widespread. Principally because of this, most of the deposits are regarded as epigenetic hydrothermal deposits in genetic connection with the Mesozoic magmatism. But nearly 90 % of the deposits occur in Permian strata, and show concordant stratiform mineralization with a spatial distribution constrained by sedimentary facies of the Permian strata. A close association between mineralization and Permian strata is recognizable. The Huanggang Fe‐Sn deposit was regarded as a standard skarn‐type deposit formed by magmatic hydrothermal solutions in connection with Mesozoic granites. But there are abundant fabrics indicating submarine hydrothermal exhalation both in magnetite ores and in skarns, including bedding/lamination, soft–deformation, synsedimentary brecciation, and collo‐form fabrics. The magnetite orebodies and skarn‐bodies are predominantly concordant stratiform, and extend nearly 20 km along certain stratigraphic horizon, that is, the upper section of the Lower‐Permian submarine volcanic rocks. The Mesozoic granitic rocks crosscut the magnetite and skarn zone. Instead of skarnization, they show strong greisenization associated with cassiterite‐quartz veins, distinct from the magnetite skarn‐ore with disseminated tin in the Permian rocks. The Dajing Sn‐polymetallic deposit is generally regarded as subvolcanic‐hydrothermal origin, principally because of the close spatial association between ores and some of the Mesozoic subvolcanic dikes (called rhyolitic porphyry). Detailed geological, fabric, petrographical and mineralogical study demonstrates that this very kind of subvolcanic rocks is actually a new type of exhalites (called ‘siderite‐sericite chert’ according to its mineral assemblage), formed by hydrothermal sedimentation during the evolution of the Later‐Permian lacustrine basin. There are, however, indeed some rhyolitic porphyry dikes that crosscut orebod–ies. The orebodies and their associated exhalite predate, and thus have no genetic relation, to the Mesozoic magmatic process. We thus conclude that subaqueous exhalative mineralization did occur during the basin evolution at the Permian time in the southern segment of the Da Hinggan Mountains, which is ignored and poorly understood, but might be as important as the hydrothermal mineralization connected with the Mesozoic magmatism.     

Material composition and geochemical characteristics of ores of the Malinovskoe gold-ore deposit (Primorskii Krai,Russia)

The mineral composition and geochemical characteristics of the ores of the Malinovskoe gold-ore deposit are studied by the data from mining works (ditches, cleanings, and boreholes). It is found that the ore–magma system of the deposit was formed in several stages of mineralization characterized by two phases of magmatism differing in age. In terms of the set of features (the geological–structural position of the deposit, as well as the material composition and geochemical characteristics of the ores), the deposit is attributed to the gold–tourmaline type of mineralization associated spatially and genetically with the “raremetal” granitoid magmatism. This type has not previously been found in Primorskii Krai. The studies of the material composition and geochemical characteristics of the ores allow us to ascertain the correlations between the elements along with the reasons of their origination. By analogy with other gold-ore formations of the Russian Far East, the mineralogical and geochemical model of the deposit is developed (Be–Sn–Cr–Ba–Au–Cu–Mo–Pb–V–Ti–Co–W–Ag–Bi–Ni–Mn–Sr–Zn–Sb–As modeling element series of vertical zoning), which enables us to estimate the levels of the erosion section of the ore bodies and to evaluate their prospects. It is found that the most productive associations in the deposit are the gold–bismuth geochemical association (Au–Ag–Bi–Cu–As–Co) and, to a lesser degree, the gold–tungsten association (W–Au–Ag–Cu–Bi–As).     

陕西省勉略宁矿集区铜厂铜-铁矿床地质特征及其成因探讨

铜厂铜-铁矿床是勉略宁矿集区具有代表性的矿床之一,主要由上部的铜厂铜矿床和下部的杨家坝铁矿床(铜厂铁矿床)组成。根据磁铁矿和硫化物的相对含量,铜厂铜-铁矿床的矿石可分为磁铁矿矿石、含硫化物磁铁矿矿石和硫化物矿石三类。系统的岩相学和矿相学研究表明,其矿石矿物主要为磁铁矿、黄铜矿、黄铁矿和磁黄铁矿;矿石结构包括自形-半自形-他形粒状结构、交代残余结构和包含结构,矿石构造包括块状、浸染状、脉状和条带状构造。铜厂铜-铁矿床的围岩蚀变种类较多,且具有一定的分带性,上部铜矿体围岩蚀变以硅化、碳酸盐化和黑云母化为主,以石英、方解石和黑云母为主的蚀变矿物组合显示钾化特征;下部铁矿体围岩蚀变有钠长石化、蛇纹石化、滑石化、透闪石化、碳酸盐化、绿泥石化等,以钠长石、蛇纹石、滑石、透闪石、方解石、白云石、菱铁矿、绿泥石、黑云母和磷灰石等为主的蚀变矿物组合显示钠化特征。铜厂铜-铁矿床中磁铁矿的TiO₂含量小于1.72%,Al₂O₃含量小于1.81%,均显示热液磁铁矿的特征,结合铜矿石脉穿插铜厂闪长岩及二者突变接触的地质特征,说明铜厂铜-铁矿床的形成与热液活动密切相关。同时,铜厂铜-铁矿床形成于早古生代加里东期,勉略宁矿集区在该时期处于大陆裂谷的扩张环境中,与铁氧化物-铜-金(Iron Oxide-Copper-Gold,简称IOCG)矿床的形成环境类似。通过与典型IOCG矿床地质特征、矿化蚀变特征、矿物组合特征、矿物地球化学特征及大地构造背景的系统对比,初步提出铜厂铜-铁矿床应属于IOCG矿床。     

吉林省小石人金矿区微量元素地球化学特征

以吉林省小石人金矿区内不同类型岩(矿)石微量元素测试结果为基础,从数据结构和空间结构两方面,对微量元素的地球化学特征进行探讨。统计参数表明:所观测元素在矿区内具有明显的浓集、富集特点,在不同类型岩(矿)石中元素的分布分配也不尽相同。依据分布分配特点,可将矿区内的岩(矿)石分为正常岩石、弱蚀变岩石和强蚀变/矿化岩石3类。多元统计分析成果揭示:所观测元素都参与了金的成矿活动,但行为特点有所差异。依据多元统计特征,可将微量元素分为3个组合类型:Au、As、Sb、Bi、Hg、Mn,Cu、Pb、Zn、Ag,Co、Ni、V;第一组合为成矿成晕组合,第二组合为金的多金属矿化组合,第三组合为黄铁矿化蚀变组合;元素组合也对应于不同的矿化阶段,指示金的成矿活动及特征。土壤、岩石地化剖面显示所观测的元素间存在空间相关性,但Mn与Au相异,其异常出现在矿化蚀变带的外侧。     

黑龙江五道岭钼铁矿床地质地球化学特征及成因

五道岭钼铁矿床是小兴安岭-张广才岭成矿带内典型的矽卡岩型矿床。矿体赋存于碱长花岗岩的蚀变产物--黄铁矿化石英斑岩与五道岭组凝灰质砂岩、酸性凝灰岩接触的矽卡岩带内。矽卡岩矿物组合为石榴子石、透辉石、阳起石和绿帘石等组成,矿体呈不规则脉状,具分枝复合形态特征,矿石类型包括钼矿石、铁矿石和黄铁矿矿石。与成矿密切相关的碱长花岗岩和石英斑岩为准铝质--过铝质、高钾钙碱性系列的I 型花岗岩; 富集Rb、K、U 等大离子亲石元素,亏损P、Ti 等高场强元素,具有与俯冲带花岗岩相似的地球化学特征。锆石LA--ICP --MS U--Pb 测年结果表明,石英斑岩和碱长花岗岩的形成时代分别为193. 6 ± 1. 1 Ma 和193. 9 ± 1. 3 Ma。结合区域地质演化特征,认为五道岭钼铁矿床的形成与古太平洋板块俯冲挤压造山后期的伸展环境有关,成矿时代为早侏罗世( 186 ± 2 Ma) ,矿床属于矽卡岩型成因。     

广西珊瑚钨锡矿田的原生分带及矿化富集规律

为指导深部、边部生产勘探及开采工作,对珊瑚钨锡矿田的原生分带及矿化富集规律进行了研究,发现:珊瑚钨锡矿田产出有钨锡石英脉、钨锑萤石石英脉和含钨石英角砾脉3种矿化类型,这3类矿化在水平上以长营岭隐伏花岗岩为中心,从东向西形成了单侧分带;钨锡石英脉矿床在垂向上呈"五层楼"形态分带模式;原生矿物组合分带呈亲氧和挥发性元素在上,亲硫元素在下的"逆向"分带,即上部富锡,中部富钨,下部Cu、Zn、Ag增加的规律;矿化富集同围岩的岩性、矿脉脉辐、矿脉产状形态等多种因素有关,造成了矿化分布极不均匀。根据矿床的原生分带特征和矿化富集规律,推测在矿床的深部仍然具有较大的找矿潜力。     

Heavy concentrate halos as prospecting guides for PGE mineralization

Platinum-group minerals (PGM) in primary ores and placers are compared in order to substantiate prospecting guides for layered and differentiated intrusions containing sulfide Cu-Ni ores with platinum-group elements (PGE). It is shown that supergene placer mineral assemblages bear information on primary sources and their probable economic value. The mineralogical and geochemical data on the large Siberian intrusions that host Cu-Ni and low-sulfide PGM deposits (Noril’sk 1, Kingash, Chinei, and Yoko-Dovyren) are used to elaborate mineralogical prospecting guides based on the comparative study of PGM assemblages in primary ore, heavy concentrate halos, and hillside sediments. The mechanism of PGM redistribution under supergene conditions is exemplified in the Chinei deposit. The placer mineral assemblage with prevalence of Pt-Fe alloys, atokite-rustenburgite, sperrylite, and multicomponent Pd-Sn-Cu-Pb compounds can be used as a prospecting guide for Noril’sk-type primary PGM ore and related economic placers. The paolovite-sperrylite or sperrylite PGM assemblage in heavy concentrate halos indicates occurrence of Cu-Ni ore in the prospecting area. Sperrylite with isomorphic admixture of Ir and Os typical of the Kingash pluton could be a orospecting guide for Ni-bearing mafic-ultramafic intrusions.     

Loypishnyun Low-Sulfide Pt–Pd Deposit of the Monchetundra Basic Massif,Kola Peninsula,Russia

The geology of the basal-structural Loypishnyun low-sulfide Pt–Pd deposit is characterized, including its mineral composition and the peculiarities of its PGE and chalcophile-element distribution in ore. The deposit is situated in the northeastern part of the Monchetundra basic massif and is localized in its lower norite–orthopyroxenite zone, intensely injected with late gabbroic rocks. Two ore zones are distinguished within the deposit. Ore zone 1 has been traced by drilling for about 1.5 km at a thickness from 10–15 to 120 m and incorporates from two to nine separate lenticular–sheetlike orebodies 0.5–25 m in thickness. Ore zone 2 has been traced for 550 m and is represented by one orebody 5–35 m thick. The internal structure of the orebodies is characterized by alternation of low-grade (Pt + Pd = 0.5–0.9 gpt), ordinary (Pt + Pd = 1.0–1.9 gpt), and high-grade (Pt + Pd > 2 gpt) interlayers of various thickness. The ores are spatially and genetically related to sulfide mineralization (pentlandite–chalcopyrite–pyrrhotite) in an amount of 1–5 vol %. The PGE distribution in ores normalized to primitive mantle is characterized by fractionation of easily fusible platinoids with a positive Pd anomaly. The spectra of chalcophile elements normalized to primitive mantle are notable for elevated Te, Bi, As, and Se contents with respect to Sn, Hg, and Pb, which reflects the significant contribution of Te, Bi, and As in the formation of platinum group minerals (PGM), whereas Se, which is devoid of proper mineral phases, most likely is an admixture in the composition of sulfides. The S/Se value in ore of the Loypishnyun deposit varies from 31 to 814. The platinum group elements (PGE) in ore are represented by 45 noble metal minerals. Ore zone 1 is characterized by lateral mineral zoning, which is expressed as replacement of a bismuthotelluride–sulfide PGM assemblage by an assemblage of copper–PGE compounds and alloys. In ore zone 2, a mineral assemblage of tellurides, copper–PGE compounds and alloys predominates, with native gold, silver, and palladium, as well as sulfides and bismuthotellurides, playing a subordinate role. The formation of PGM ore proceeded under variable sulfur fugacity conditions, beginning with the late magmatic stage at temperatures of 900–700°C and ending with hydrothermal transformation at a temperature of <500°C.     

拉么锌铜矿床成矿地球化学特征及物理化学条件探讨

根据矿区花岗岩和夕卡岩的全岩成分、花岗岩和夕卡岩的挥发分、微量元素及稀土元素含量、不同矿体的金含量以及矿物包裹体研究和对矿床形成时ｐｃｏ２、ｆｓ２、ｆｏ２及ｐＨ值的估算资料，讨论了拉么矿床的成矿地球化学特征和物理化学条件。     

铜陵新桥铁矿田地质地球化学特征及成因浅析

长期以来有关新桥 (S Fe Cu)矿田的成因一直争论不休 ,如沉积 -改造型、层控 -矽卡岩型、海底喷流沉积型等。作者在综合分析该矿田的地质 -地球化学特征的基础上 ,认为新桥矿田具有二期成矿作用的特点。早期沉积成矿作用形成菱铁矿矿体和不具有工业意义的黄铁矿层。后期岩浆成矿作用形成层状、似层状块状硫化物型、热接触交代矽卡岩型和热液脉型等不同类型的硫化物矿体。沉积作用形成的矿体与岩浆作用形成的矿体各自有着不同的地球化学特征     

个旧塘子凹锡多金属矿床微量元素地球化学特征

塘子凹矿床位于个旧老厂矿田的西北部，矿体按产出方式可分为接触带原生硫化矿和脉状氧化矿。本文着重从微量元素地球化学和矿物地球化学角度探讨了本区脉状氧化矿的成因问题，认为该区脉状氧化矿与接触带原生硫化矿具有同源性，而与围岩大理岩没有成因联系；在成矿后期，地表流体对脉状矿体中多种微量元素特别是V、As、Sb、Bi等有强烈的富集作用。     

西藏邦铺钼多金属矿床矽卡岩矿物学特征及其地质意义

西藏邦铺超大型钼多金属矿床中矽卡岩铅锌矿体赋存于下二叠统洛巴堆组矽卡岩和大理岩中,矿体呈似层状、透镜状产出,矽卡岩矿物较为发育。为进一步查明矿床矽卡岩矿物种属及矽卡岩类型,剖析矽卡岩形成环境及其与矿化类型之间的关系,基于对矽卡岩矿物系统地显微镜下观测,利用电子探针对矿床主要矽卡岩矿物化学成分进行了系统分析。结果表明,石榴子石端员组分以钙铁榴石为主,含少量锰铝榴石和钙铝榴石;单斜辉石主要为透辉石-钙铁辉石系列,含少量锰钙辉石;似辉石为铁钙蔷薇辉石;角闪石主要为钙质阳起石;绿帘石贫Fe、Mg。矽卡岩矿物组合特征表明,矿床矽卡岩兼具钙矽卡岩和锰质矽卡岩特征;早期矽卡岩形成于较强的氧化环境,成矿岩浆流体亦具有较高氧逸度。邦铺首次发现锰质矽卡岩矿物组合,表明矿区具有银矿找矿潜力,为下一步找矿工作提供了理论支撑。     

Lermontovskoe Tungsten Skarn Deposit: the Oldest Mineralization in the Sikhote-Alin Orogen, Far East Russia

Abstract. Lermontovskoe tungsten skarn deposit in central Sikhote-Alin is concluded to have formed at 132 Ma in the Early Cretaceous, based on K-Ar age data for muscovite concentrates from high-grade scheelite ore and greisenized granite. Late Paleozoic limestone in Jurassic - early Early Cretaceous accretionary complexes was replaced during hydrothermal activity related to the Lermontovskoe granodiorite stock of reduced type. The ores, characterized by Mo-poor scheelite and Fe^3+- poor mineral assemblages, indicate that this deposit is a reduced-type tungsten skarn (Sato, 1980, 1982), in accordance with the reduced nature of the granodiorite stock.
The Lermontovskoe deposit, the oldest mineralization so far known in the Sikhote-Alin orogen, formed in the initial stage of Early Cretaceous felsic magmatism. The magmatism began shortly after the accretionary tectonics ceased, suggesting an abrupt change of subduction system. Style of the Early Cretaceous magmatism and mineralization is significantly different between central Sikhote-Alin and Northeast Japan; reduced-type and oxidized-type, respectively. The different styles may reflect different tectonic environments; compressional and extensional, respectively. These two areas, which were closer together before the opening of the Japan Sea in the Miocene, may have been juxtaposed under a transpressional tectonic regime after the magmatism.     

福建紫金山矿田罗卜岭斑岩型铜钼矿地球化学立体探测示范

罗卜岭矿床是与晚中生代花岗闪长斑岩体有关的隐伏斑岩型铜钼矿床, 矿区位于紫金山矿田的东北部; 铜钼矿体主要产于绿泥石化-绢英岩化和(弱)钾化-绢英岩化带中, 矿石矿物组合为黄铜矿+辉钼矿; 少量过渡类型矿体产于高级泥化带中, 矿石矿物组合为蓝辉铜矿+铜蓝+辉钼矿。罗卜岭矿区的原生晕地球化学三维模型显示, 微量元素具有一定的分带特征, 低温元素Au与高温元素组合W、Sn、Bi分布于矿体上方, 中低温元素Pb、Zn、Ag分布于Cu、Mo元素之间; 元素直观垂向分带序列大致为: (As、Sb、Hg)-(W、Bi、Sn)-Ga-Au、Ba-Cu、Ag-Pb、Zn-Mn-Mo; 前缘晕的元素与氧化物组合为As、Sb、Au、Ga、Al2O3, 矿体近矿晕元素组合为Ag、Pb、Zn, 缺失尾晕元素组合; Cu、Mo可直接作为找矿指示元素, Au、Ag、Pb、Zn、As、Sb、Ga、Ba、Mn可作为间接指示元素, 矿床深部K2O正异常与Al2O3负异常可作为斑岩型铜钼矿的重要找矿标志, 这一规律对紫金山矿田深部和外围隐伏斑岩型矿体的勘查工作具有重要的参考意义。     

河南冷水北沟铅锌矿地质地球化学特征及成因探讨

冷水北沟铅锌矿床赋存于元古界栾川群和管道口群内,矿体受断裂破碎带及矽卡岩带的控制。矿石类型可分为热液脉型和矽卡岩型,矿体围岩蚀变强烈。根据矿床地质-地球化学特征,结合矿石的矿物共生组合、铅和硫同位素组成及成矿年龄、包裹体成分及特征,认为该矿床的矿源为岩浆岩,成矿溶液主要来自岩浆水和大气降水的混合溶液,矿床成因类型属中高温条件下形成的热液脉型-矽卡岩型矿床。     

豫西熊耳山地区槐树坪金矿岩石-土壤找矿指示元素的确定及其应用

槐树坪金矿床位于河南省洛阳市嵩县境内,是豫西熊耳山地区近年来新发现的大型金矿床。本次研究对槐树坪金矿区地表及井下不同类型的较新鲜围岩、蚀变岩和矿石以及地表1∶20000面积性土壤采样,分析29项微量元素,从岩石和土壤两种采样介质来确定槐树坪金矿床的地球化学找矿指示元素。一方面基于较新鲜围岩的元素含量特征确定每个微量元素在该区岩石中的异常下限,进而分别计算了蚀变岩和矿石中微量元素平均含量与异常下限的比值,即异常衬度。按照异常衬度大于1.4的标尺确定了蚀变岩与矿石中明显富集的微量元素组合。另一方面,基于Au与28项微量元素在较新鲜围岩、蚀变岩、矿石三种介质中含量关系散点图直观确定了指示金成矿的微量元素组合。综合二者确定出槐树坪金矿区岩石地球化学找矿的指示元素组合为Au、Ag、As、Sb、Hg、Sn、Mo、Bi、Cu、Pb、Zn、Cd、Nb计13项。针对地表1∶20000面积性土壤调查,采用上述岩石中异常衬度为1.4作为土壤异常下限绘制了槐树坪金矿区微量元素的地球化学异常剖析图,以槐树坪金矿区已探明鸡公山一带的主成矿段为模型确定了土壤地球化学找矿的指示元素组合为Au、Ag、As、Sb、Hg、Bi、Cu、Pb、Zn、Cd、B计11项。综合上述结果认为在找矿指示元素组合方面土壤对岩石具有明显的继承性。基于岩石与土壤介质中共同的10项找矿指示元素,构建了归一化的综合异常指标,以鸡公山矿段为标准对整个槐树坪矿区进行了综合评价,发现槐树坪矿区内马蹄沟、秦佛爷沟、姜疙瘩和天坪西4处具有类似鸡公山矿段的找矿潜力。