云南昌宁文沧铜矿矿床特征及找矿思路

矿体产于平掌组变质绿片岩中,NW向F3断裂破碎带控矿。边缘向中央品位增高。研究构造延伸和矿源可扩大远景。     

云南景东县卜勺磁铁矿矿床地质

磁铁矿矿体似层状、透镜状赋存于淇海岩组中上一中部的钠长绿泥片岩、钠长绿泥绿岩、钠长绿帘绿泥片岩中,严格受层位、岩性和构造的控制。     

江苏东海地区石英脉地质特征及找矿方向

区域变质作用、韧性剪切作用和超高压变质作用为SiO2富集创造条件,印支期-燕山期的构造活动为石英脉富集定位创造构造环境。东海群地层、韧性剪切带、超高压变质带为石英脉的形成提供了SiO2物质来源。     

云南巧家仓房沟铅锌矿矿床成矿模式

铅锌矿赋存于灯影组硅质条带白云岩中,局部产于筇竹寺组,脉状、透镜状,与峨眉山玄武岩喷发关系密切,属岩浆晚期热液成因。     

云南矿山深部找矿新突破及启示

会泽超大型富锗铅锌矿、澜沧老厂大—超大型银铅多金属矿床和保山金厂河航磁异常深部找矿,先后取得重大突破,推动云南新一轮新、老矿山和磁异常区深部找矿积极性。建议禄丰中兴井125#—元谋甘泉村航磁异常、巧家药山航磁异常与石屏龙潭含多金属铁帽等的深部找矿应及早提上议事日程。     

浙江青田石平川钼矿控矿条件分析

石平川钼矿由燕山晚期第四次侵入碱性长石花岗岩体提供物源和热动力,火山机构、断裂和西山头组第二岩性段为成矿提供了导矿通道和容矿场所。     

定向岩芯构造分析及在金矿勘查中的运用

系统测量定向岩芯中构造面的α角和β角,结合钻孔的方位角和钻孔倾角,通过赤平投影可以还原真实的构造面产状.通过穿过金矿体的定向岩芯的构造编录和系统分析,计算矿体中的主要含矿节理、含矿蚀变带等构造面的产状,并进行统计分析,可以了解矿化与各类构造之间的关系,计算矿体的空间产状,并推断主矿体的延伸等,为矿区的深部勘查设计提供依据.     

物探软件MAGS2.0在峨腊厂高精度磁测中的应用

划分出3个磁异常场区,Ⅲ区规模较大.出露中元古界昆阳群大龙口组,是勘查区内铁矿床的赋矿层位,受断裂构造和岩体控制.     

宾川小龙潭斑岩铜钼矿矿化特征及控矿条件

区域性的程海深大断裂是该区的导岩、导矿构造,直接控制了富碱性斑岩和次级构造的展布,富碱性斑岩又是区内铜钼矿化的直接成矿因素,所以应重视沿北东向构造—岩浆带的找矿工作.     

Chalcophile element partitioning between sulfide phases and hydrous mantle melt: Applications to mantle melting and the formation of ore deposits

Understanding the geochemical behavior of chalcophile elements in magmatic processes is hindered by the limited partition coefficients between sulfide phases and silicate melt, in particular at conditions relevant to partial melting of the hydrated, metasomatized upper mantle. In this study, the partitioning of elements Co, Ni, Cu, Zn, As, Mo, Ag, and Pb between sulfide liquid, monosulfide solid solution (MSS), and hydrous mantle melt has been investigated at 1200 °C/1.5 GPa and oxygen fugacity ranging from FMQ−2 to FMQ+1 in a piston-cylinder apparatus. The determined partition coefficients between sulfide liquid and hydrous mantle melt are: 750–1500 for Cu; 600–1200 for Ni; 35–42 for Co; 35–53 for Pb; and 1–2 for Zn, As, and Mo. The partition coefficients between MSS and hydrous mantle melt are: 380–500 for Cu; 520–750 for Ni; ∼50 for Co; <0.5 for Zn; 0.3–6 for Pb; 0.1–2 for As; 1–2 for Mo; and >34 for Ag. The variation of the data is primarily due to differences in oxygen fugacity. These partitioning data in conjunction with previous data are applied to partial melting of the upper mantle and the formation of magmatic-hydrothermal Cu–Au deposits and magmatic sulfide deposits.I show that the metasomatized arc mantle may no longer contain sulfide after >10–14% melt extraction but is still capable of producing the Cu concentrations in the primitive arc basalts, and that the comparable Cu concentrations in primitive arc basalts and in MORB do not necessarily imply similar oxidation states in their source regions.Previous models proposed for producing Cu- and/or Au-rich magmas have been reassessed, with the conclusions summarized as follows. (1) Partial melting of the oxidized (fO₂ > FMQ), metasomatized arc mantle with sulfide exhaustion at degrees >10–14% may not generate Cu-rich, primitive arc basalts. (2) Partial melting of sulfide-bearing cumulates in the root of thickened lower continental crust or lithospheric mantle does not typically generate Cu- and/or Au-rich magmas, but they do have equivalent potential as normal arc magmas in forming magmatic-hydrothermal Cu–Au deposits in terms of their Cu–Au contents. (3) It is not clear whether partial melting of subducting metabasalts generates Cu-rich adakitic magmas, however adakitic magmas may extract Cu and Au via interaction with mantle peridotite. Furthermore, partial melting of sulfide-bearing cumulates in the deep oceanic crust may be able to generate Cu- and Au-rich magmas. (4) The stabilization of MSS during partial melting may explain the genetic link between Au-Cu mineralization and the metasomatized lithospheric mantle.The chalcophile element tonnage, ratio, and distribution in magmatic sulfide deposits depend on a series of factors. This study reveals that oxygen fugacity also plays an important role in controlling Cu and Ni tonnage and Cu/Ni ratio in magmatic sulfide deposits. Cobalt, Zn, As, Sn, Sb, Mo, Ag, Pb, and Bi concentrations and their ratios in sulfide, due to their different partitioning behavior between sulfide liquid and MSS, can be useful indices for the distribution of platinum-group elements and Au in magmatic sulfide deposits.