河北小石门银金矿床地质地球化学特征与矿床成因

河北小石门银金矿床位于小寺沟斑岩铜钼矿床的南西侧.矿体呈脉状、透镜状,银金矿化受NNE向断裂控制,成矿与杂岩体及二长斑岩有关;矿物组合主要为中低温矿物组合,成矿温度240～365℃;流体包裹体研究表明成矿流体富硫,有较高的K ,NH4 ,Ca2 和Na ,成矿热液为岩浆热液;硫同位素分析显示,硫来源于岩浆;稀土元素分析亦表明成矿物质来自于二长斑岩及小寺沟岩体,而铅锌矿可能部分来源于地层.推断小石门银金矿床为中低温热液矿床.     

北京市怀柔区北干沟金矿床与韧性剪切带的关系

北干沟金矿床是韧性剪切带含金石英脉型金矿床。韧性剪切带以发育糜棱岩和片理化带为特征,应变强度和退化变质作用从边缘到中心逐渐增强,并形成鞘褶皱;韧性构造岩具有分带性;产于韧性剪切带中心部位的石英脉是主要的含金脉体;韧性剪切带的形态、活动阶段及韧性剪切变质岩的分带性对金矿具有明显的控制作用。     

黄腊石滑坡基岩弯曲松弛带工程地质特性、形成机制及失稳预测

黄腊石滑坡是发育在三叠系中统巴东组砂泥岩夹灰岩构成的逆倾坡上的滑坡群,总方量约1 800×104 m3.滑坡滑带下面存在着大致连续分布的基岩弯曲松弛带.对于该松弛带工程地质特性的认识,将影响防治工程方案的设计及实施.本文通过野外工作、以往工作资料和研究成果的收集整理及再认识,对该滑坡下伏松弛带工程地质特性、形成机制及失稳预测作了一定深度的探讨,认为基岩弯曲松弛带是发生在特定的岩层中,由构造、重力、侵蚀、岩溶、风化、降雨及上部滑坡等因素共同作用的产物,工程地质环境质量较差,受重力及其上滑体滑动等因素影响,后期改造明显.在斜坡长期受重力累积变形、三峡水库运行期江水位变化及库岸再造作用下,将形成牵引式滑动.防治工程应在削方、排水等基础上,重点考虑防止库岸再造和斜坡坡脚部位变形.     

雅砻江谷底卸荷松弛现象与深厚覆盖层特征

雅砻江河床覆盖层厚度多在30m以上,最厚可达51.6m。覆盖层横向上厚度变化较大,纵向上可明显分为3层,上、下部以正常河流相为主,厚度较薄;中部以洪积、崩积、坡积、湖泊沉积堆积与冲积混合堆积为主的加积序列,厚度相对较大。在谷底基岩面以下,岩体通常存在20m厚左右的卸荷松弛带,弱风化,具有透水性好,岩体完整性较差,工程力学性状差等特征,其潜在的工程效应是坝基渗漏。覆盖层深厚是第二层加积序列所致,谷底形成时间长,以致谷底有足够的时间卸荷松弛和风化。     

福建政和星溪金矿床构造控矿特征及找矿前景

通过政和星溪金矿区矿床地质和构造控矿特征分析,指出了矿区找矿远景和外围找矿靶区,认为矿区内及外围找矿前景广阔。     

内蒙古迪彦钦阿木斑岩钼矿床绿泥石和绿帘石矿物化学特征及其成矿指示意义

迪彦钦阿木矿床位于大兴安岭中段二连浩特-东乌旗多金属成矿带,是区内新近发现的一个超大型斑岩钼矿床.为了厘清蚀变矿物的成分对找矿的指示意义,文章运用电子探针和LA-ICP-MS对迪彦钦阿木矿床青磐岩化带绿帘石亚带的绿泥石和绿帘石的主微量元素成分进行了分析.电子探针数据表明,这些绿泥石属于铁斜绿泥石(辉绿泥石).绿泥石四面...     

安徽霍邱李老庄铁矿-菱镁矿床地质特征及矿床成因类型

霍邱铁矿田位于华北地台南缘,处于北淮阳山字型构造脊柱部位.李老庄铁矿-菱镁矿床置于霍邱铁矿田中部.该矿床主要产于新太古界霍邱群变质岩系中,矿体赋存于富镁碳酸盐中,矿石类型可以分为菱镁矿磁铁矿石和蛇纹石磁铁矿石,各占25%.成矿物质来源于变质岩系的多层、分散的含铁建造矿源层中.依据矿床地质特征,结合矿石同位素地质和测年结果,认为李老庄铁矿-菱镁矿铁矿床为一新太古代海相火山-沉积变质型矿床.     

放射性物探方法在辽宁团山子地区金矿找矿中的应用

辽宁省兴城市团山子地区位于青龙-葫芦岛近东西向断裂的东段,碱厂岩体南缘,八家子-杨家杖子多金属成矿区的中南部.通过钻探证实,金矿化受近东西向断裂构造控制,矿化类型为碎裂蚀变岩型,具有低品位、大矿量特点,在辽西地区属首次发现.为加强对本区控矿构造特征和金矿化赋存规律的研究,采用了放射性物探方法进行探索,取得了较好的找矿效果.由于该方法简便易行,对于在区域上寻找该类型金矿具有重要意义,值得借鉴和推广.     

商丹断裂带(河南段)构造变形特征及其找矿意义

商丹断裂带是一条多期次活动的大型断裂带,区域上也是大型金属矿的赋存带,对金属矿产具有重要的控制作用.文章以商丹断裂带(河南段)为研究对象,在基于孔沟至寨根一带构造剖面的宏观特征和显微构造特征解析的基础上,对研究区控矿构造和机理提出了新的认识.综合研究表明,商丹断裂带(河南段)具多期活动特征,整体呈现"正花状构造"样式....     

Geodynamic modelling of the Century deposit,Mt Isa Province,Queensland

This paper is concerned with an example of quantitative modelling of orebody formation as a guide to reducing the risk for future mineral exploration. Specifically, the paper presents a detailed 3–D numerical model for the formation of the Century zinc deposit in northern Queensland. The model couples fluid flow with deformation, thermal transport and chemical reactions. The emphasis of the study is a systems approach where the holistic mineralising system is considered rather than concentrating solely on the mineral deposit. In so doing the complete plumbing system for mineralisation is considered with a view to specifying the critical conditions responsible for the ore deposit occurring where it does and having the size and metal grades that are observed. The numerical model is based on detailed geological, tectonic, isotopic and mineralogical data collected over the past 20 years. The conclusions are that the Century zinc deposit is located where it is because of the following factors: (i) a thermal anomaly is associated with the Termite Range Fault due to advection of heat from depth by fluid flow up the Termite Range Fault; (ii) bedding‐plane fissility in the shale rocks hosting the Century zinc deposit has controlled the wavelength and nature of D₁ folding in the vicinity of the deposit and has also controlled increases in permeability due to hydrofracture of the shales; such hydrofracture is also associated with the production of hydrocarbons as these shales passed through the ‘oil‐window’; (iii) Pb–Zn leached from crustal rocks in the stratigraphic column migrated up along faults normal to the Termite Range Fault driven by topographic relief associated with inversion at the end of the Isan Orogeny; these fluids mixed with H₂S derived at depth moving up the Termite Range Fault to mix with the crustal fluids to precipitate Pb–Zn in a plume downstream from the point of mixing. Critical factors to be used as exploration guides are high temperatures, carbonaceous fissile shales now folded into relatively tight D₁ folds, fault‐controlled plumbing systems that enable fluid mixing, depletion of metals upstream of the deposit and,in particular,a very wide Fe‐depletion halo upstream of the deposit.