甘肃北山造山带南缘白石坝一带南岭型花岗岩地球化学特征与锡成矿作用浅析

白石坝一带花岗岩具高硅低铝、富钾贫钠、非常低Sr(24.9×10~(-6)~82.9×10~(-6))高Yb(2.61×10~(-6)~5.74×10~(-6))的南岭型花岗岩特征,A/CNK介于0.91~0.98之间,σ在1.92~2.22之间。明显富集Rb、Th、K等大离子不相容元素,亏损Ba、Sr、P、Ti等元素,并具有弱Nb亏损,稀土元素分布曲线呈明显的"燕式"型,其形成可能来源于下地壳底部部分熔融与地壳物质发生混合形成的产物,源区深度较浅、水含量低和氧逸度低,处于还原状态下的伸展构造背景,有利于锡矿的萃取和富集,研究其区域构造-岩浆演化,对指导区域矿产预测和评价均具有重要的理论和实际意义。     

我国砂岩型铀矿成矿理论的创新和发展

简述了从国外到国内的砂岩型铀矿概况及成矿理论研究的发展,归纳出了我国砂岩型铀矿的"叠合复成因氧化-还原成矿理论",并就"预富集"、"板状矿体成因"、"深部油气作用"、"可地浸概念"、"大砂体"等问题进行了粗浅的讨论。     

四川会理天宝山矿床深部新发现铜矿与铅锌矿的成因关系探讨

天宝山矿床是川滇黔接壤铅锌矿集区内的代表性铅锌矿床之一,赋存于上震旦统灯影组白云岩中。近年来,该矿床深部发现了以铜为主的矿化,甚至形成铜矿体。目前,对铜矿成因及其与铅锌矿的关系尚不清晰。本文报道新发现铜矿的矿物学和同位素地球化学资料,以期揭示铜矿的成矿物质来源,结合铅锌矿的相关研究,探讨铜矿形成机制及其与铅锌矿的成因关系。镜下观察和扫描电镜分析显示,铜矿石中主要金属矿物为黄铜矿和银黝铜矿,其次为方铅矿和毒砂,含少量闪锌矿和黄铁矿;铅锌矿石中闪锌矿是主要金属矿物,方铅矿和黄铁矿次之,含少量黄铜矿和深红银矿。铜矿石中闪锌矿主要呈半自形-他形粒状,与黄铜矿共生或被其包裹,方铅矿主要呈细脉状充填在黄铜矿、银黝铜矿和毒砂的裂隙中或呈他形粒状分布在这些矿物中;铅锌矿石中黄铜矿主要呈浸染状分布于闪锌矿之中。两类矿石金属矿物的组构特征,显示铜矿物与铅锌矿物具有密切的共生、穿插和包裹关系,应属同期成矿。同位素地球化学数据显示,铜矿石中黄铜矿的δ34SCDT值为3.9‰~4.2‰(均值为4.1‰,n=3),铅锌矿石闪锌矿的δ34SCDT值为3.3‰~3.9‰(均值为3.5‰,n=3),十分相近,暗示它们具有相似的S源,应均属赋矿地层海相蒸发岩中硫酸盐热化学还原作用的产物。铜矿石中黄铜矿的~(206)Pb/~(204)Pb=18.441~18.476(均值为18.461,n=3),~(207)Pb/~(204)Pb=15.731~15.751(均值为15.741,n=3),~(208)Pb/~(204)Pb=38.809~38.873(均值为38.849,n=3),μ=9.72~9.76;铅锌矿石中方铅矿的~(206)Pb/~(204)Pb=18.442~18.480(均值为18.455,n=3),~(207)Pb/~(204)Pb=15.746~15.763(均值为15.752,n=3),~(208)Pb/~(204)Pb=38.793~38.892(均值为38.840,n=3),μ=9.75~9.78。两者具有相近的Pb同位素组成且其壳源特征明显,表明它们的成矿金属来源相似,均来自上地壳,与赋矿沉积岩有关。综上,矿物学和同位素地球化学证据表明,天宝山矿床深部新发现铜矿与铅锌矿具有明显的同期共生关系和相似的成矿物质来源,是同一成矿热液体系不同阶段演化的产物。天宝山铜铅锌矿床与MVT矿床的成矿特征不同,暗示其成矿作用(环境)特殊,可能与矿床所处的地质背景有关,其成因认识对川滇黔接壤区同类型矿床深部找铜矿具有重要的指导意义。     

火山岩型铀矿山环境地质调查评价方法研究

通过对典型火山岩型铀矿山及周边地区的环境地质调查及样品分析测试,厘定矿山放射性气态、液态、固态源项特征及分布,开展放射性迁移循环途径研究及矿山周边公众潜在附加剂量评价研究,初步建立放射性矿山环境地质调查评价体系。结果表明,该研究可以为查明火山岩型铀矿山开发过程中对环境介质的影响程度和范围提供方法指导。     

煤田资料的铀矿二次开发技术及其找矿意义——以二连盆地ZS煤田铀矿点的发现为例

在中国北方主要盆地铀矿地质调查工作中,煤田自然伽马异常作为主要矿化信息和找矿线索,为一系列铀矿床(点)的快速发现奠定了坚实基础。为进一步提高煤田资料铀矿二次开发的高效性和准确性,运用水成铀矿理论,以中国二连盆地ZS煤矿区典型铀矿点的发现为例,初步探讨了煤田资料的铀矿二次开发技术,提出了"异常筛选与选区分析、原位验证与环境判别、等时地层格架建立与沉积体系分析、综合分析与靶区定位"四位一体的煤矿区铀矿地质调查模式。这对中国北方含煤盆地铀矿地质调查工作提供了新的找矿思路和技术路线,具有较重要的指导意义。     

Identification of Uranyl Minerals Using Oxygen K‐Edge X‐Ray Absorption Spectroscopy

Although most of the world's uranium exists as pitchblende or uraninite, this mineral can be weathered to a great variety of secondary uranium minerals, most containing the uranyl cation. Anthropogenic uranium compounds can also react in the environment, leading to spatial–chemical alterations that could be useful for nuclear forensics analyses. Soft X‐ray absorption spectroscopy (XAS) has the advantages of being non‐destructive, element‐specific and sensitive to electronic and physical structure. The soft X‐ray probe can also be focused to a spot size on the order of tens of nanometres, providing chemical information with high spatial resolution. However, before XAS can be applied at high spatial resolution, it is necessary to find spectroscopic signatures for a variety of uranium compounds in the soft X‐ray spectral region. To that end, we collected the near edge X‐ray absorption fine structure (NEXAFS) spectra of a variety of common uranyl‐bearing minerals, including uranyl carbonates, oxyhydroxides, phosphates and silicates. We find that uranyl compounds can be distinguished by class (carbonate, oxyhydroxide, phosphate or silicate) based on their oxygen K‐edge absorption spectra. This work establishes a database of reference spectra for future spatially resolved analyses. We proceed to show scanning X‐ray transmission microscopy (STXM) data from a schoepite particle in the presence of an unknown contaminant.     

张家口崇礼小西湾侵入岩成矿条件及矿化机制研究

张家口市崇礼区北部完成了1∶5万地球化学测量,小西湾侵入岩位置恰与化探工作圈定的AS33,即小西湾综合异常高度套合。利用区域资料及异常查证所获得的大比例尺地质、物化探数据,对该区成矿条件进行了综合分析,并推测了矿化蚀变的形成机制及其矿化蚀变体主要赋存位置。通过推断该区矿化机制并建立模型,认为该区具有寻找中高温热液型多金属矿床的潜力,并对下一步的勘查方向提出了建议。     

小兴安岭霍吉河钼矿床成矿过程——透岩浆成矿作用

传统上将小兴安岭霍吉河钼矿床归类为斑岩型钼矿.通过对矿区地质特征的研究,即矿区无斑岩体、矿体围绕隐爆角砾岩呈环状出露、石英细脉-网脉状和浸染状矿石结构、成矿年龄明显晚于赋矿围岩形成时间等,认为该矿床是透岩浆成矿作用的结果.早中生代伊春-延寿花岗岩岩基带上相伴的大型-超大型钼矿是典型的透岩浆成矿作用的产物,是岩基后成矿作用.     

Genesis and Metallogenic Process of the Lujing Uranium Deposit,Southwest Jiangxi Province,China: Constraints of Micropetrography and S–C–O Isotopes

The Lujing uranium deposit, located in the southeastern part of the Nanling metallogenic province, is one of the representative granite‐related hydrothermal uranium deposits in South China. Basic geology, geochemistry, and geochronology of the deposit have been extensively studied. However, there is still a chronic lack of systematic research on the genesis and metallogenic process of the deposit. Thus, we recently carried out an electron microprobe and stable isotopic analysis. The main research results and progresses are as follows: Uranium minerals in this deposit include coffinite, pitchblende, and uranothorite, and small amounts of uranium exist in accessory minerals in the form of isomorphism. Coffinite, which occurs predominantly as the pseudomorphs after pitchblende, also occurs as a primary mineral and is locally formed from the remobilization of uranium from adjacent uranium‐bearing minerals. The mineralizing fluid was originally composed of a magmatic fluid generated by late Yanshanian magmatism. The high As content of pyrite in ores may reflect the addition of meteoric water, or the formation water (or both), to the magmatic hydrothermal system. The δ³⁴S values vary from −14.4‰ to 13.9‰ (mean δ³⁴S = −3.9‰), showing a range that is similar to nearby Cambrian metamorphic strata and Indosinian granites, indicating that these host rocks represent the source of sulfur; however, the possibility of a mantle source cannot be completely ruled out. According to our new isotopic data and recent Pb isotopic data, we conclude that the uranium in ores was derived by leaching dominantly from the uranium‐rich host rocks, especially the Cambrian metamorphic strata. The δ¹³C_PDB values (−8.75‰ to 1.40‰; mean δ¹³C_PDB = −5.41‰) and δ¹⁸O_SMOW values (5.45–18.62‰; mean δ¹⁸O = 13.02‰) of reddish calcite from the ore‐forming stage suggest that the CO₂ in the mineralizing fluids was derived predominantly from the mantle, with a small component contributed by marine carbonates. Based on these new data and previous research results, this paper proposes that uranium metallogenesis in the Lujing deposit is closely associated with mafic magmatism resulting from crustal extension during the Cretaceous to Paleogene in South China.     

河北省张家口崇礼区北部地球化学特征及其找矿指示

地球化学测量成果被广泛而成熟地运用在矿产勘查工作中,为明确张家口崇礼区北部成矿、找矿的地球化学指示信息,对该区水系沉积物测量及异常查证成果进行了综合分析。通过计算元素富集系数和变异系数、开展R型聚类分析、统计化探异常区岩石的地质年代、对比该区化探异常及已知矿床与典型矿床的成矿要素,从而推断了该区找矿主攻元素为Ag、Pb、Zn、Mo、Cd,且Ag、Pb、Zn和Mo、W 2组元素分别具有共伴生关系,指出该区化探异常主要受燕山期岩浆热液控制。综合分析认为,本区找矿模型为蔡家营式次火山-热液型多金属矿床,具有寻找次火山-热液型Ag、Pb、Zn、Mo多金属矿床的潜力。