渗出砂岩型铀矿成矿预测与找矿标志

文章基于渗出砂岩型铀矿成矿机理和模式,认为渗出砂岩型铀成矿作用不同于渗入砂岩型铀矿成矿作用,其成矿预测和找矿标志也不同;提出了渗出砂岩型铀矿成矿作用两大基本关键条件识别标志:红杂色含矿建造原生成因和其中控矿灰色砂体的后生成因识别;在提出的红杂色沉积建造中渗出砂岩型铀矿“上红下黑、上下连通、红中找灰、灰中找矿”总体找矿新思路基础上,阐明渗出砂岩型铀成矿区域预测评价条件和标志:深部富铀富有机质沉积岩建造、区域构造、区域建造、放射性异常信息和综合预测标志等,提出并阐述“小凹陷成大矿”条件;系统建立渗出砂岩型铀矿床预测定位标志体系,特别是野外可识别的宏观标志,包括控矿构造、沉积建造、蚀变改造、铀矿化砂岩颜色、外来有机质特征等,并对比了渗入和渗出砂岩型铀成矿预测标志。提出的渗出砂岩型铀矿识别标志体系不仅对区分“渗入”和“渗出”两种矿化成因,而且对厘清控矿要素、指导成矿预测和找矿工程部署具有重要意义和价值。

鄂尔多斯盆地西北部特拉敖包铀矿产地华池-环河组黄铁矿特征及其成因探讨

特拉敖包铀矿产地位于鄂尔多斯盆地西北部,区内白垩系发育大量铀矿化。目前,针对该区的铀成矿作用尚未开展深入研究,但发现华池-环河组黄铁矿与铀富集关系密切。黄铁矿常具有一定的标型特征,因此文章在野外地质调查和岩相学基础上,利用扫描电镜、电子探针与LA-ICPMS原位分析等技术,对特拉敖包铀矿产地黄铁矿矿物学特征、主微量元素和硫同位素开展研究。结果表明:特拉敖包铀矿产地华池-环河组黄铁矿分布形式多样,黄铁矿根据其形态差异主要分为三类:单颗粒自形晶黄铁矿、胶状黄铁矿和莓球状黄铁矿。胶结状黄铁矿含有较高的Co、Ni、Mo与As,单颗粒黄铁矿与莓球状黄铁矿含有生长薄边,薄边的Co与As含量较高。黄铁矿的特征表明特拉敖包铀矿产地华池-环河组砂岩还经历了高温流体与低温流体的双重作用。

江西相山铀矿田铀矿物稀土元素特征及富集机制探讨

铀矿物是铀矿床勘探与选冶的重要研究对象。相山铀矿田是我国最大的火山岩型铀-多金属矿田,主要发育有早期碱交代和晚期酸交代两期铀矿化,但目前对这两期铀矿化中铀矿物的地球化学特征尚缺乏系统的对比研究。文章运用电子探针和激光剥蚀电感耦合等离子体质谱对相山铀矿田两期铀矿化矿石中铀矿物稀土元素特征进行研究。结果显示,相山铀矿田碱交代和酸交代型铀矿化矿石中铀矿物类型均包含钛铀矿、铀石和沥青铀矿,碱交代型铀矿化矿石中铀矿物以钛铀矿、铀石为主,酸交代型铀矿化矿石中铀矿物以沥青铀矿为主。碱交代型铀矿化矿石中铀矿物稀土元素配分模式为右倾型,富集La、Ce和Nd等元素;酸交代型铀矿化矿石中铀矿物稀土元素配分模式为左倾型,富集Yb、Er和Dy等元素。酸交代型铀矿化矿石中沥青铀矿相对富集重稀土元素,与国内外其他类型的铀矿床相比其成矿过程有明显特殊性,这可能与成矿流体富F-有关;深部沥青铀矿较浅部富集重稀土元素的原因可能是深部沥青铀矿结晶温度高于浅部;相对于铀石和钛铀矿等铀矿物,重稀土富集对沥青铀矿有倾向性可能是因为沥青铀矿形成的过程与CO_(3)^(2-)和Cl^(-)关系密切。

鄂尔多斯盆地西北部华池-环河组绿色砂岩成因探讨

鄂尔多斯盆地西北部华池-环河组赋矿层中存在大套的绿色砂岩,这套绿色砂岩致绿因素至今尚不清楚。文章在野外观察的基础上,利用测色仪对不同颜色的砂岩进行对比研究,基于CIE1976 LAB色度空间,通过a值的差异将华池-环河组砂岩分为灰色砂岩与绿色砂岩,利用高倍显微镜、X射线衍射、扫描电镜等,分析赋矿砂岩的矿物组成,最后结合主微量元素、全岩S和有机碳含量,综合分析了绿色砂岩致绿成因。研究表明,绿色砂岩的主要致绿矿物是绿泥石和绿/蒙混层,其中绿泥石的成因主要是砂岩中的黑云母、角闪石等含铁矿物中的铁离子与镁离子不断被流体萃取出来,致使砂岩中的蒙脱石经由绿/蒙混层向绿泥石转换。

鄂尔多斯盆地早白垩世构造-热事件与铀成矿的关系——来自玄武岩锆石U-Pb年代学的约束

鄂尔多斯盆地北部纳岭沟铀矿床以北,大营及巴音青格利铀矿床以东的黑石头沟发育一层玄武岩,为探讨这期玄武岩与鄂尔多斯盆地北部铀成矿的关系,文章对该玄武岩进行了地球化学与年代学的分析。该玄武岩切穿下白垩统东胜组,SiO_(2)含量较低(46.99%),里特曼指数σ为8.69,显示出碱性玄武岩的特征;其锆石U-Pb定年结果为(126.7±2.4) Ma,表明黑石头沟玄武岩形成于早白垩世,反映鄂尔多斯地块在早白垩世发生了一次构造-岩浆-热事件,与大区域的华北地区乃至中国东部在早白垩世发生的较普遍的构造-岩浆-热事件具有一致性。结合前人的研究成果,这次构造-岩浆-热事件是由于岩石圈地幔减薄造成的。该事件使地下深部热流体上涌及板内运移,导致早白垩世古地温梯度增高,这一过程为铀元素在鄂尔多斯盆地北部的迁移、沉淀、富集成矿创造了条件。

Outline of Metallogenic Regularity of Bauxite Deposits in China

Among the abundant aluminum ore resources in China, bauxite is dominated, which is mainly distributed in 19 provinces and regions, including Shanxi, Henan, Guizhou and Guangxi. The major deposit type of bauxite is paleo-weathering crust sedimentary type, and the other one is the accumulation type. The main metallogenic period is the late Paleozoic Era followed by the Cenozoic Era. The metallogenic tectonic background is characterized by a cratonic environment. This paper summarizes the bauxite metallogenic regularity based on the characteristics of bauxite resources, bauxite deposit type, bauxite metallogenic belt and metallogenic series in China, and 15 bauxite metallogenic belts, 8 bauxite metallogenic series and 7 bauxite ore concentrated areas were identified in the study. This paper also provides a theoretical basis for the evaluation of the potential of bauxite resources.

Geological and Geochemical Characteristics of the Zhiluo Formation in the Bayinqinggeli Uranium Deposit, Northern Ordos Basin: Significance for Uranium Mineralization

The Bayinqinggeli deposit in the northern Ordos Basin, northwestern of China, is a recently discovered sandstone-type uranium deposit. The uranium(U) orebodies are generally hosted in the lower member of the Jurassic Zhiluo Formation(Fm.), and are primarily tabular or irregular in shape. In the study area, 23 sandstone samples were collected from the Zhiluo Fm. and analyzed for major, trace, and rare earth elements(REEs). The geochemical characteristics of these sandstones are used to evaluate the factors controlling U mineralization. The source rocks of the Zhiluo Fm. sandstones are mainly volcanic and felsic magmatic rocks formed in continental arc and active continentalmarginal arc environments, and they provided the material required for the mineralization. The index of compositional variability ranges from 1.02 to 3.29(average1.38), indicating that the Zhiluo Fm. sandstones are immature and composed of first-cycle sediments. The corrected chemical index of alteration averages 56, suggesting that the source rocks underwent weak chemical weathering. The ore host rocks are loose, providing favorable conditions for epigenetic oxidation and U precipitation and enrichment. Ferrous iron in minerals such as chlorite, biotite, ilmenite, and pyrite might have played a role either in adsorbing or reducing the uranium.