陕西双王金矿床东段矿体地质特征及成矿预测

陕西省太白县双王金矿床属大型低品位角砾岩型金矿，矿床东段的矿体赋存层位是古道岭组，矿体产于角砾岩带中，含金角砾岩带的形成与断裂构造有关，其热液活动可划分5个阶段，Ⅱ1，Ⅲ2亚阶段为主要成矿阶段。矿体矿化规律、矿体特征、矿体成因具有独特性。文章对未探明地段进行了成矿预测，提出找矿靶区，并在部分地段已经得到验证。     

内蒙古虎拉林爆破角砾岩型金矿床特征

虎拉林金矿区主要地层为中侏罗统绣峰组陆源碎屑岩，岩浆岩以燕山期花岗斑岩和石英斑岩为主。在地层与岩体接触带附近发育爆破角砾岩，金矿(化)体主要受断裂控制而产于爆破角砾岩筒(带)中。矿区内已圈出6条矿(化)体，总体走向近SN，以1、2号为主要矿体。成矿与爆破角砾岩有关，形成一体多型的矿化分布形式。δ^34S变化范围为-0．2‰-0．8‰，具有深源岩浆S特征。S和Pb同位素、流体包裹体、稀土元素等特征表明，成矿物质来自地壳深部或地幔，成矿流体以深部岩浆热液为主。^39Al/^40Ari法测得金矿成矿年龄为135．5Ma。     

海南琼海烟塘梅岭铜钼矿床地质特征

琼海烟塘梅岭铜钼矿床位于海南五指山隆起东北侧的一个“角砾岩筒”中，该“角砾岩筒”的形成受南北向、东西向构造一岩浆岩带控制，与燕山期花岗闪长岩、花岗闪长斑岩关系密切。工业矿体主要集中在岩筒边缘接触带附近，共发现大小铜、钼矿体23个，矿体多呈透镜状、脉状，全为盲矿体，埋深数十米至400余米。矿石为细脉浸染状，Cu品位0．4％～0．9％，Mo品位0．01％～0．1％。蚀变带可粗略划分为钾化带、石英-绢云母化带和青盘岩化带，可能属斑岩型矿床。     

与斑岩型铜矿有关的角砾岩(筒)

斑岩型铜矿床是重要的铜矿类型，在已探明的铜储量中斑岩型铜矿居首位。研究认为，在板块构造的敛合带上，斑岩铜矿发育地区，常见有角砾状地质体和角砾岩筒。这些角砾状地质体和角砾岩筒对矿化与謇集起着重要作用，是斑岩铜矿的重要找矿标志，有时其本身就是铜矿体。本文中从理论与野外工作相结合的角度，总结了与斑岩型铜矿床有关的角砾状地质体和角砾岩筒的类型及地质特征，通过具体实例介绍了与斑岩铜矿有关的角砾岩筒的找矿思路与方法，适宜野外工作的实际应用。     

马来西亚沙捞越邦达、什兰江控矿角砾岩筒构造对比研究及其找矿意义

马来西亚沙捞越邦达、什兰江控矿角砾岩筒构造均为典型的浅成—半浅成角砾岩筒构造，角砾岩及控矿类型具有明显的垂向分带特点。邦达控矿角砾岩筒构造发育角砾岩筒上段的塌陷角砾岩，角砾岩筒剥蚀深度较浅，控制典型的高硫化型浅成低温金铜矿床，且其深部具有较大的找矿潜力。什兰江控矿角砾岩筒构造发育角砾岩筒下段的爆发角砾岩和中段的流化角砾岩，分别控制斑岩型金矿化和低硫化型浅成低温热液型金矿化，角砾岩筒剥蚀深度较大，对矿床的保存和找矿极为不利。     

利用高铁钾长石粉合成13X沸石分子筛的实验研究

对江苏丰县的富钾页岩进行预处理，得到钾长石含量达76．4％的钾长石粉，其Fe2O3含量高达7．52％。以此钾长石粉为原料经过焙烧处理、水热合成实验，在铁含量较高情况下成功合成了13X沸石分子筛，并采用正交实验法确定了优化工艺参数。对实验产物的主要性能测试表明，合成的富铁沸石产品与13X沸石分子筛工业产品相似，吸附量达到国家化学工业产品标准，可用于对含重金属离子废水的吸附处理。     

1995年日本新泻北部M6.0地震及其由地震烈度和地下水地热异常分布所揭示的隐伏地震断层

1995年日本新泻北部M6.0地震发生在新泻地震空区的东部边缘.由于此次地震震源较浅(10 km),造成了55栋房屋倒塌、165栋房屋半倒.通过计算倾倒墓碑的地震矩,对本区地震烈度进行了分析,发现烈度6度区(据日本JMA度)为一覆盖面积6.1×1 km2,呈NNE-SSW向分布的条带,表明震中区的冲积平原下存在一条隐伏断层.震中区地下水的温度、电导率和Cl-浓度等异常区与呈线性分布的6度烈度区大致吻合,也有力地证明了震中区下面存在一条隐伏断层.这次地震可能是由高压型热水系沿隐伏活动断层喷溢引起.带着高温的高压热水降低了岩石的断裂强度,从而触发了地震.     

Synthesis of zeolites using fly ash and their application in removing heavy metals from waters

Fly ash is the solid waste of thermal power plants where coal is used as fuel, and its management and utilization have been of environmental concern for decades. Since the technique of synthesizing zeolite from coal fly ash was introduced by Holler[1] (19…     

Monitoring volcanic hazard using eddy covariance at Solfatara volcano, Naples, Italy

An eddy covariance (EC) station was deployed at Solfatara crater, Italy, June 8–25, 2001 to assess if EC could reliably monitor CO₂ fluxes continuously at this site. Deployment at six different locations within the crater allowed areas of focused gas venting to be variably included in the measured flux. Turbulent (EC) fluxes calculated in 30-min averages varied between 950 and 4460 g CO₂ m⁻² d⁻¹; the highest measurements were made downwind of degassing pools. Comparing turbulent fluxes with chamber measurements of surface fluxes using footprint models in diffuse degassing regions yielded an average difference of 0% (±4%), indicating that EC measurements are representative of surface fluxes at this volcanic site. Similar comparisons made downwind of degassing pools yielded emission rates from 12 to 27 t CO₂ d⁻¹ for these features. Reliable EC measurements (i.e. measurements with sufficient and stationary turbulence) were obtained primarily during daytime hours (08:00 and 20:00 local time) when the wind speed exceeded 2 m s⁻¹. Daily average EC fluxes varied by ±50% and variations were likely correlated to changes in atmospheric pressure. Variations in CO₂ emissions due to volcanic processes at depth would have to be on the same order of magnitude as the measured diurnal variability in order to be useful in predicting volcanic hazard. First-order models of magma emplacement suggest that emissions could exceed this rate for reasonable assumptions of magma movement. EC therefore provides a useful method of monitoring volcanic hazard at Solfatara. Further, EC can monitor significantly larger areas than can be monitored by previous methods.     

Exploration and discovery in Yellowstone Lake: results from high-resolution sonar imaging, seismic reflection profiling, and submersible studies

‘No portion of the American continent is perhaps so rich in wonders as the Yellow Stone’ (F.V. Hayden, September 2, 1874)Discoveries from multi-beam sonar mapping and seismic reflection surveys of the northern, central, and West Thumb basins of Yellowstone Lake provide new insight into the extent of post-collapse volcanism and active hydrothermal processes occurring in a large lake environment above a large magma chamber. Yellowstone Lake has an irregular bottom covered with dozens of features directly related to hydrothermal, tectonic, volcanic, and sedimentary processes. Detailed bathymetric, seismic reflection, and magnetic evidence reveals that rhyolitic lava flows underlie much of Yellowstone Lake and exert fundamental control on lake bathymetry and localization of hydrothermal activity. Many previously unknown features have been identified and include over 250 hydrothermal vents, several very large (>500 m diameter) hydrothermal explosion craters, many small hydrothermal vent craters (1–200 m diameter), domed lacustrine sediments related to hydrothermal activity, elongate fissures cutting post-glacial sediments, siliceous hydrothermal spire structures, sublacustrine landslide deposits, submerged former shorelines, and a recently active graben. Sampling and observations with a submersible remotely operated vehicle confirm and extend our understanding of the identified features. Faults, fissures, hydrothermally inflated domal structures, hydrothermal explosion craters, and sublacustrine landslides constitute potentially significant geologic hazards. Toxic elements derived from hydrothermal processes also may significantly affect the Yellowstone ecosystem.