沅麻盆地西南缘凤凰-麻阳白垩系红层中脉状铅锌矿控矿条件

沅麻盆地为一中生代断陷盆地,盆地西缘铅锌矿点较多.矿床（点）类型为赋存于白垩系红层砂岩-砾岩中脉状铅锌矿,具有规模较大、品位较高、矿石选冶性能良好等特点.对凤凰-麻阳地区白垩系红层中脉状铅锌矿（点）特征及控矿条件进行分析、归纳、总结.加强对区内铅锌矿控矿条件的研究,对促进区内铅锌矿的找矿勘查具有重要意义.     

全球铅锌矿资源分布

世界范围内铅锌矿资源较为丰富，在全球50多个国家均有分布.通过搜集国内外铅锌矿相关的资料和信息，在对世界1035处铅锌矿床及3319个矿（化）点资料进行提炼、系统梳理的基础上，对不同数据来源的全球铅锌矿的储量和资源储量进行比较研究，对全球铅锌矿3种主要成因类型，即喷流沉积型、火山块状硫化物型和密西西比型铅锌矿的资源分布、成矿时间和成矿空间分布规律进行了全面的综合分析研究，对世界大型铅锌矿床的储量、资源储量、品位、成矿类型和成矿特征进行归纳总结，以期为全球铅锌矿的综合研究提供参考.     

贵州五指山矿集区新麦铅锌矿床地质特征及找矿远景分析

<正>五指山铅锌矿集区位于贵州省西北部织金县与普定县交界处。新麦铅锌矿位于五指山矿集区中部,地质研究程度较低,笔者对新麦铅锌矿进行了实地调研,对矿床特征进行了初步总结,结合前人成果资料,分析了矿区的找矿远景。1区域地质背景五指山铅锌矿集区大地构造位于扬子准地台西南段,黔北台隆遵义断拱贵阳复杂构造变形区的西     

黔东地区铅锌矿地质特征及成矿作用分析

本文根据控矿构造格局,将黔东地区铅锌矿划为扬子准地台东缘、华南褶皱带西缘,以及扬子准地台与华南褶皱带过渡带等三个铅锌矿带,并分别对其典型矿床进行了解剖和特征描述。在此基础上,分析了铅锌矿成矿作用,将黔东地区铅锌矿分为准同生沉积型铅锌矿床和热液交代一充填型铅锌矿床两种成因类型,综述了相应的控矿条件及矿床成因。最后,进行了黔东地区铅锌矿找矿远景分析,提出了6个找矿远景区。     

川滇黔铅锌成矿区西部木里给地铅锌矿地质特征及找矿方向

通过介绍给地铅锌矿区域地质背景、矿区及矿床地质特征,对该矿区铅锌矿的成矿规律进行了初步探讨。总体认为该铅锌矿矿床类型为层控碳酸盐岩建造-火山热液充填-淋滤叠加改造型铅锌矿床,并为该矿区下步找矿方向提供了一些思路。     

贵州省两个铅锌矿的地质特征及找矿勘探经验

一、引言我队(贵州省地质局某地质队)在贵州某地从事铅锌矿普查与勘探工作。我们在党的正确领导下,除已向上级提交了一部分铅锌矿的工业储量外,还在黔西地区找到了数十个铅锌矿产地。对其中两处已进行     

集安市大石湖多金属矿地质特征及找矿标志

大石湖多金属矿区处于鸭绿江裂谷边缘的辽东—吉南成矿带之中,其间分布着集安市前石岭铅锌矿点、集安市杨木林子铅锌矿点、集安市大关门砬子铅锌矿点、集安市望江楼铅锌矿点、集安市秋皮沟铜矿点等,具有相同的成矿地质环境,找矿标志明显,通过对铅锌等矿种成矿地质条件、成矿作用、成矿规律和控矿因素的全面总结研究和重新认识,建立区域成矿模式,并对区域成矿潜力进行评价。     

黔西北铅锌矿稀土元素组成特征——兼论黔西北地区铅锌矿成矿与峨眉山玄武岩的关系

通过对黔西北地区铅锌矿中硫化物稀土元素组成特征、峨眉山玄武岩中成矿元素铅锌的含量、铅锌矿硫同位素及锶同位素组成分析表明,该区铅锌矿成矿物质不是来源于峨眉山玄武岩,由于峨眉山玄武岩的喷出时代与本区铅锌矿成矿时代相差较远,也不可能为本区铅锌矿的形成提供热源。     

四川省布拖县乌依铅锌矿地质特征及找矿方向

在综合分析乌依铅锌矿床地质成果资料的基础上,结合近年在该区外围找矿中的一些认识,提出了乌依铅锌矿成矿模式,并对乌依铅锌矿找矿方向进行了分析预测。     

贵州纳雍水东铅锌矿矿床地球化学特征

对贵州纳雍水东乡洗米沟、坟山脚一带灯影组地层中铅锌矿石采样,进行镜下观察和全岩主量、微量元素、稀土元素以及硫同位素地球化学研究。微量元素研究表明,矿床中N i、Mo、As、Sb等成矿元素富集明显,Sr、Ba、V等元素强烈亏损,认为早寒武世热水对铅锌矿源层进行了淋滤和改造;稀土元素研究表明,铅锌矿石稀土配分曲线向右倾斜,...     

Statistical considerations for grain-size analyses of tills

Relative percentages of sand, silt, and clay from samples of the same till unit are not identical because of different lithologies in the source areas, sorting in transport, random variation, and experimental error. Random variation and experimental error can be isolated from the other two as follows. For each particle-size class of each till unit, a standard population is determined by using a normally distributed, representative group of data. New measurements are compared with the standard population and, if they compare satisfactorily, the experimental error is not significant and random variation is within the expected range for the population. The outcome of the comparison depends on numerical criteria derived from a graphical method rather than on a more commonly used one-way analysis of variance with two treatments. If the number of samples and the standard deviation of the standard population are substituted in at-test equation, a family of hyperbolas is generated, each of which corresponds to a specific number of subsamples taken from each new sample. The axes of the graphs of the hyperbolas are the standard deviation of new measurements (horizontal axis) and the difference between the means of the new measurements and the standard population (vertical axis). The area between the two branches of each hyperbola corresponds to a satisfactory comparison between the new measurements and the standard population. Measurements from a new sample can be tested by plotting their standard deviation vs. difference in means on axes containing a hyperbola corresponding to the specific number of subsamples used. If the point lies between the branches of the hyperbola, the measurements are considered reliable. But if the point lies outside this region, the measurements are repeated. Because the critical segment of the hyperbola is approximately a straight line parallel to the horizontal axis, the test is simplified to a comparison between the means of the standard population and the means of the subsample. The minimum number of subsamples required to prove significant variation between samples caused by different lithologies in the source areas and sorting in transport can be determined directly from the graphical method. The minimum number of subsamples required is the maximum number to be run for economy of effort.     

Stress-strain analysis of geogrid-supported liners over subsurface cavities

Summary Finite element analyses were conducted to investigate the magnitude of tensile strains imposed on landfill liners due to the formation of subsurface cavities. The study incorporated the significance of using geogrids to reduce the magnitude of strains and possibly the potential for collapse of landfill liners. Variations of key parameters included depth of overburden (D) and diameter of the cavity (B). Estimated stress distributions were compared to theoretical values obtained from a model reported in the literature. Results indicated that, contrary to conventional wisdom, the critical area based on the mechanics of arching was above the edge of the cavity where stress concentration occurred. Incorporation of geogrid reinforcement reduced the magnitude of tensile strains. The tensile force in the geogrid was dependent upon the size of the cavity, the depth of the overburden, and the applied pressure.     

Viscous effects on penetrating shafts in clays

The penetration of rigid objects such as piles and penetrometers into soils creates a zone of soil disturbance around them. The extent of this disturbed zone influences the resistance of the moving rigid body. This paper presents a theoretical framework to analyze the resistance in the disturbed zone created by a shaft penetrating a clay soil. The soil is modeled as a viscous material after it reaches failure [critical state (CS)]. The results of this analysis show that the viscous drag stress component on the shaft surface is influenced by the size of disturbed zone that has reached CS around the shaft, the shear viscosity of the soil and the velocity profile (or strain rate) in the CS zone around the shaft. The size of CS zone, the velocity profile and the viscosity of soil are interdependent. Large variation in viscous drag occurs when the size of the CS soil zone is less than four times the shaft’s radius. Limiting drag occurs when the size of the CS soil zone exceeds six times the shaft’s radius. The theoretical velocity distribution of the movement of soil in the CS zone shows that the soil is dragged along with shaft in the near field (close to the shaft surface) and moves upwards in the far field.     

具彩色斑纹颅形贝在广西桂林下石炭统黄金组中的发现:兼论颅形贝属的地质地理分布

文中描述了产自广西桂林地区下石炭统黄金组下部的颅形贝属一新种,桂林颅形贝(Cranaena guilinensis)。新种以平直的前结合缘和背壳上发育中槽为特征。在4枚标本上发现保存有放射状的彩色条带,表明该种当时生活在温暖海域的浅水环境。对该属70个种的地质地理分布和生物多样性变化的初步分析表明,该属可能起源于早泥盆世欧美大陆西北缘的老世界区,之后的地理分布和生物多样性发展以北美地区为中心,经历了中泥盆世—晚泥盆世早期和早石炭世2次比较明显的辐射演化、迁移扩散高峰和晚泥盆世晚期的1次严重衰退。第1次高峰是中泥盆世—晚泥盆世早期,该属的生物多样性达到巅峰,生物地理分布范围扩大到欧美大陆之外的西伯利亚板块、哈萨克斯坦板块和华南板块等;第2次高峰是早石炭世,该属的生物多样性虽不及前一次,但获得了最广泛的地理分布,不仅在北方大陆有分布,而且已进入到冈瓦纳大陆边缘。晚泥盆世晚期该属的1次严重衰退显然与F/F灭绝事件有关。早石炭世之后,该属进入衰退阶段,最终在二叠纪初灭绝。     

Lower Carboniferous (Dinantian) stratigraphy and structure of the Walterstown-Kentstown area,Co. Meath,Ireland

Stratigraphic units are defined and described for the Lower Carboniferous succession in the Walterstown-Kentstown area of Co. Meath, Ireland. A complete (unexposed) Courceyan succession from the terrestrial red bed facies of the Baronstown Formation to the Moathill Formation of the Navan Group has been penetrated in several boreholes. Although the lower part of the sequence is comparable with the Courceyan succession at Navan and Slane, the middle part of the sequence differs markedly in the Walterstown-Kentstown area and two new members, the Proudstown and Walterstown Members, are defined in the upper part of the Meath Formation. Syndepositional faulting was initiated during the Courceyan, probably in latest Pseudopolygnathus multistriatus or early Polygnathus mehli latus time. Movement on the ENE trending St. Patrick's Well Fault influenced the deposition of the Walterstown Member and the overlying Moathill Formation and was probably associated with the development of the East Midlands depocentre to the south of the area. A second episode of tectonism in the latest Courceyan or early Chadian resulted in uplift and erosion and the development of ‘block and basin’ sedimentation. Subsequent transgression of the uplifted block led to the establishment of the Kentstown Platform, bounded to the north, west and south by rocks of basinal facies. The Milverton Group (Chadian-Asbian), confined to this platform, unconformably overlies Courceyan or Lower Palaeozoic strata and is subdivided into three formations: Crufty Formation (late Chadian), Holmpatrick Formation (late Chadian-Arundian) and Mullaghfin Formation (late Arundian-Asbian). The Walterstown Fault controlled the western margin of the Kentstown Platform at this time. Contemporaneous basinal sediments of the Fingal Group (Lucan and Naul Formations) accumulated to the west of the Walterstown Fault and are much thicker than age-equivalent platform facies. Platform sedimentation ceased in latest Asbian to early Brigantian time with tectonically induced collapse and drowning of the platform; platform carbonates of the Mullaghfin Formation are onlapped northwards by coarse proximal basinal facies of the Loughshinny Formation. A distinct gravity anomaly in the Kentstown area suggests the presence of a granitoid body within the basement. The Kentstown Platform is therefore considered to have formed on a buoyant, granite-cored, footwall high analogous to the Askrigg and Alston Blocks of northern England.     

Controls on the evolution and demise of Lower Carboniferous carbonate platforms,northern margin of the Dublin Basin,Ireland

Shallow water platform limestones of the Chadian–Asbian Milverton Group are restricted to the north-eastern part of the Lower Carboniferous (Dinantian) Dublin Basin. Here, they are confined to two granite-cored fault blocks, the Kentstown and Balbriggan Blocks, known to have been active during the late Dinantian. Three areas of platform sedimentation are delimited (the Kentstown, Drogheda and Milverton areas), although in reality they probably formed part of a single carbonate platform. Resedimented submarine breccias and calciturbidites (Fingal Group) composed of shallow water allochems and intraclasts sourced from the platform accumulated, along with terrigenous muds, in the surrounding basinal areas. Sedimentological evidence suggests that the Kentstown and Balbriggan Blocks possessed tilt-block geometries and developed during an episode of basin-wide extensional faulting in late Chadian time. Rotation of the blocks during extension resulted in the erosion of previously deposited sequences in footwall areas and concomitant drowning of distal hangingwall sequences. Antithetic faults on the northern part of the Balbriggan Block aided the preferential subsidence of the Drogheda area and accounts for the anomously thick sequence of late Chadian platform sediments present there. Continued subsidence and/or sea-level rise in the late Chadian–early Arundian resulted in transgression of the Kentstown and Balbriggan Blocks; carbonate ramps developed on the hangingwall dip slopes and transgressed southward with time. Subsequent progradation and aggradation of shallow water sediments throughout the Arundian to Asbian led to the development of carbonate shelves. Several coarse conglomeratic intervals within the contemporaneous basinal sequences of the Fingal Group attest to periodic increases of sediment influx associated with the development of the shelves. Sedimentological processes controlled the development of the carbonate platforms on the hangingwall dip slopes of the Kentstown and Balbriggan Blocks, though periodic increases of sediment flux into the basinal areas may have been triggered by eustatic falls in sea level. In contrast, differential subsidence along the bounding faults of these blocks exerted a strong control on the margins of the late Dinantian shelves, maintaining relatively steep slopes and inhibiting the progradation of the shelves into the adjacent basins. Tectonically induced collapse and retreat of the platform margins occurred in the late Asbian–early Brigantian. Platform sediments are overlain by coarse-grained proximal basinal facies which fine upwards before passing into a thick shale sequence, indicating that by the late Brigantian carbonate production had almost stopped as the platforms were drowned.     

Nouvelle interprétation tectonique de la montagne Sainte-Victoire (Provence,France)

The explanation normally given for the tectonics of Sainte-Victoire Mountain, a dozen kilometres east of Aix-en-Provence, to the north of the limestone Provence, is incorrect. To the east, the morphology of the Sainte-Victoire is subdued, whereas to the west, before the mountain breaks savagely, the morphology is that of a young mountain as appears in Alpine landscapes. This unusual aspect in the region and the large subvertical faults with vertically striated surfaces that mark the massif to the south and to the west, induce the idea of strong vertical uplifts and caste doubt on the tectonic interpretation given in 1962 by Corroy et al. According to those authors, the Sainte-Victoire is a unit of Jurassic and Cretaceous formations overthrusting 1800 m to the south conglomerates of the Late Cretaceous or Palaeocene. New observations about the conglomerate transgression over the Jurassic and Cretaceous beds, and about the faults around and on the massif do not give evidence of an overthrusting but, on the contrary, induce the idea of a uplift, perhaps still active, in the form of a ‘piano key’ inclined to the northeast. To cite this article: J. Ricour et al., C. R. Geoscience 337 (2005).     

Evolution of the European Cenozoic Rift System: interaction of the Alpine and Pyrenean orogens with their foreland lithosphere

The evolution of the European Cenozoic Rift System (ECRIS) and the Alpine orogen is discussed on the base of a set of palaeotectonic maps and two retro-deformed lithospheric transects which extend across the Western and Central Alps and the Massif Central and the Rhenish Massif, respectively.During the Paleocene, compressional stresses exerted on continental Europe by the evolving Alps and Pyrenees caused lithospheric buckling and basin inversion up to 1700 km to the north of the Alpine and Pyrenean deformation fronts. This deformation was accompanied by the injection of melilite dykes, reflecting a plume-related increase in the temperature of the asthenosphere beneath the European foreland. At the Paleocene–Eocene transition, compressional stresses relaxed in the Alpine foreland, whereas collisional interaction of the Pyrenees with their foreland persisted. In the Alps, major Eocene north-directed lithospheric shortening was followed by mid-Eocene slab- and thrust-loaded subsidence of the Dauphinois and Helvetic shelves. During the late Eocene, north-directed compressional intraplate stresses originating in the Alpine and Pyrenean collision zones built up and activated ECRIS.At the Eocene–Oligocene transition, the subducted Central Alpine slab was detached, whereas the West-Alpine slab remained attached to the lithosphere. Subsequently, the Alpine orogenic wedge converged northwestward with its foreland. The Oligocene main rifting phase of ECRIS was controlled by north-directed compressional stresses originating in the Pyrenean and Alpine collision zones.Following early Miocene termination of crustal shortening in the Pyrenees and opening of the oceanic Provençal Basin, the evolution of ECRIS was exclusively controlled by west- and northwest-directed compressional stresses emanating from the Alps during imbrication of their external massifs. Whereas the grabens of the Massif Central and the Rhône Valley became inactive during the early Miocene, the Rhine Rift System remained active until the present. Lithospheric folding controlled mid-Miocene and Pliocene uplift of the Vosges-Black Forest Arch. Progressive uplift of the Rhenish Massif and Massif Central is mainly attributed to plume-related thermal thinning of the mantle-lithosphere.ECRIS evolved by passive rifting in response to the build-up of Pyrenean and Alpine collision-related compressional intraplate stresses. Mantle-plume-type upwelling of the asthenosphere caused thermal weakening of the foreland lithosphere, rendering it prone to deformation.     

青藏高原风火山流域坡面尺度活动层土壤水热时空变化特征

以风火山流域某阴坡坡顶、 坡底和阳坡坡底活动层土壤水热及气象资料为基础, 对青藏高原多年冻土区不同地形条件下的土壤水热时空变化特征进行了分析。结果表明： 在融化阶段, 除表层5 cm外, 阴坡坡底各深度土壤开始融化日期均比坡顶早, 比阳坡坡底晚; 阴坡坡脚各深度土壤含水量均大于坡顶和阳坡坡底。在冻结阶段, 开始冻结日期在阴坡坡底均比坡顶早, 但比阳坡坡底晚; 阴坡坡底各深度土壤含水量均高于坡顶相应土层的含水量, 在20 cm、 100 cm、 160 cm深处高于阳坡相应土层的含水量, 但在5 cm、 50 cm深处, 稳定冻结后两者的含水量差异较小。在整个冻融过程中, 阴坡坡底土壤温度对气温变化的响应弱于坡顶及阳坡坡底, 但其土壤水分对降水的响应强于坡顶及阳坡坡底。植被生长发育受水分和热量条件的制约, 不同地形条件下水热时空变化差异将影响植被空间分布特征。在未来气候变暖情况下, 上坡位植被可能因为水分胁迫而退化, 出现荒漠化现象, 而下坡位由于受侧向流的影响, 土壤水分对降水的响应强烈, 植被不会发生显著退化; 在不同坡向之间, 同一坡位阳坡植被退化程度可能大于阴坡。     

渭河中游宝鸡-扶风北岸斜坡结构及其对大型滑坡形成机理的指示意义

渭河中游宝鸡-扶风段北岸塬边集中发育大型黄土滑坡,体积超过1 000×10⁴ m³的滑坡达58处。在区域活动断裂调查、地球物理勘察、典型斜坡结构与构造调查基础上,研究了大型滑坡结构及其形成机理。研究表明：渭河北缘活动断裂以地堑式结构控制北坡塬边斜坡的地貌,主断裂面倾向南,倾角平均为68°,而次级断面结构组合控制斜坡结构,影响塬边大型黄土滑坡结构;塬边主断裂面与多个大型黄土滑坡后缘滑壁一致,断裂最大下挫距离7.1 m,影响大型滑坡的形态及发生过程;活动断裂呈地堑式结构,局部次级断面控制塬边多级滑动面的结构及其演化过程,如杨家村滑坡,局部滑坡剪出受断裂结构控制,剪出口角度可达72°,大部分剪出口未受到断裂面影响,角度平均为23°;三门组黏土岩黏粒体积分数超过35%,塑限平均值为23,是滑坡的层间剪切带;降雨诱发老滑坡复活是目前新滑坡发育的主要形式,大量的老滑坡形成于0.009 Ma BP二级阶地侵蚀期,而古滑坡形成于0.13 Ma BP三级阶地侵蚀期。