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1.
煤炭仍然是世界主要能源资料,煤田地质勘探必将向深部发展,绳索取心钻探技术是深部钻探优质高效的首选方法。目前煤田绳索取心钻探技术未能全面采用,存在若干不适应煤田地层的技术问题,但都能采取措施解决。煤田地质钻探钻遇地层普遍存在水敏现象,导致泥浆含砂、含泥量过高使性能变坏。煤田绳索取心钻探还存在与“水敏”、“砂害”伴随着的泵压高、泥浆流速快、冲刷严重、冲洗液动力学效应负作用大等问题,采用非煤地质勘探标准钻具(柱),强度低,能力弱,难以抵抗负面作用。为此,不仅需要优选适应地层抑制其水敏性的泥浆配比,更重要的是解决除砂除泥问题。同时要打破旧有思维,建立新体系,扩大钻孔直径,增大配套间隙,提升装备动力,用大功率去克服问题。 相似文献
2.
Stratabound massive sulfide deposits are widespread along the Middle-Lower Yangtze Metallogenic Belt (MLYMB) and serve as an important copper producer in China. Two contrasting genetic models have been proposed, interpreting the stratabound massive sulfide deposits as a Carboniferous SEDEX protore overprinted by Cretaceous magmatic-hydrothermal system or an Early Cretaceous carbonate replacement deposit. These two contrasting models have been applied to the Xinqiao stratabound Cu-Au sulfide deposit, which is dominated by massive sulfide ores hosted in marine carbonates of the Carboniferous Chuanshan and Huanglong Formations, with minor Cu-Au skarn ores localized in the contact zone between the Cretaceous diorite Jitou stock and the Carboniferous carbonate rocks. New SIMS zircon U-Pb dating suggests that the Jitou stock formed at 138.5 ± 1.1 Ma (2σ, MSWD = 0.6). Pyrite Re-Os dating yields an imprecise date of 142 ± 47 Ma (2σ, MSWD = 7.8). The geochronological data thus constrain the mineralization of the Xinqiao deposit at Early Cretaceous.Fluid inclusions in prograde skarn diopside have homogenization temperatures of 450–600 °C and calculated salinities of 13–58 wt.% NaCl equiv. Quartz from the stratabound ores and pyrite-quartz vein networks beneath the stratabound ores have homogenization temperatures of 290–360 and 200–300 °C, with calculated salinities of 5–12 and 2–10 wt.% NaCl equiv., respectively. Quartz from the skarn ores and veins beneath the stratabound ores have δ18O values of 12.32 ± 0.55 (2 SD, n = 22) and 15.57 ± 1.92‰ (2 SD, n = 60), respectively, corresponding to calculated δ18O values of 6.22 ± 1.59 (2σ) and 6.81 ± 2.76‰ (2σ) for the equilibrated ore-forming fluids. The fluid inclusion and oxygen isotope data thus support a magmatic-hydrothermal origin rather than a SEDEX system for the stratabound ores, with the hydrothermal fluids most likely being derived from the Jitou stock or associated concealed intrusion. Results from this study have broad implications for the genesis and exploration of other stratabound massive sulfide deposits along the MLYMB. 相似文献
3.
The Jinping terrane is situated in the southern segment of the Ailaoshan ore belt, Sanjiang Tethyan Orogen (SW China). The Paleogene intrusions in Jinping consist of syenite porphyry, fine-grained syenite and biotite granite stocks/dikes, and contain relatively low TiO2 (0.21–0.38 wt%), P2O5 (0.01–0.35 wt%), and high Na2O (2.00–4.62 wt%) and K2O (4.48–7.06 wt%), belonging to high-K alkaline series. Paleogene gold mineralization in Jinping comprises four genetic types, i.e., orogenic, alkali-rich intrusion-related, porphyry and supergene laterite. The NW–NNW-trending faults and their subsidiaries are the major ore-controlling structures. The orogenic Au mineralization, dominated by polymetallic sulfide-quartz veins, occurs in the diorite and minor in Silurian-Devonian sedimentary rocks. It contains a CO2-rich mesothermal fluid system generated from the mixing of mantle-derived fluids with crustal-derived metamorphic fluids, and the ore-forming materials were upper crustal- or orogenic-derived. The alkali-rich intrusion-related Au mineralization is hosted in the Ordovician-Silurian sedimentary rocks and minor in the Paleogene alkaline intrusions, and the Au orebodies occur predominantly in the alteration halos. It contains a CO2-bearing, largely metamorphic-sourced mesothermal fluid system, and the ore-forming materials were derived from the ore-hosting rocks and minor from the alkali-rich intrusions. The porphyry Cu-Mo-Au mineralization occurs in the granite/syenite porphyries and/or along their contact skarn, with the mineralizing fluids being magmatic-hydrothermal in origin. The former two hypogene Au mineralization types in Jinping were mainly formed in the late Eocene (ca. 34–33 Ma) and slightly after the porphyry Cu-Mo-Au mineralization (ca. 35–34 Ma), which is coeval with the regional Himalayan orogenic event. Subsequent weathering produced the laterite Au mineralization above or near the hypogene Au orebodies. 相似文献
4.
安徽铜陵胡村南铜钼矿床流体成矿过程 总被引:1,自引:0,他引:1
胡村南铜钼矿床是在安徽铜陵铜(金)矿集区中发现的第一个矽卡岩-斑岩复合型铜钼矿床,在长江中下游成矿带具有特殊性和典型性。文章对该矿床进行了矿床地质和流体包裹体研究,旨在查明该矿床的流体成矿过程。胡村南铜钼矿床流体成矿过程可以划分为高温气成热液期、中高温热液期和低温热液期3个成矿期。高温气成热液期发育钾长石化和矽卡岩化,中高温热液期发育绿泥石化、绿帘石化和绢云母化,而低温热液期主要发育碳酸盐化。其中,中高温热液期为主要矿化期,形成辉钼矿和黄铜矿等多种硫化物网脉。高温气成热液期矿物中发育富液相和含子晶多相包裹体,中高温热液期矿物中也主要发育富液相包裹体和含子晶多相包裹体,但可见少量的富气相包裹体,低温热液期矿物中只发育富液相包裹体。从高温气成热液期经中高温热液期到低温热液期,成矿流体均一温度从435℃以上,经203~458℃,降低到156~276℃;盐度w(NaCleq)从14.0%~64.9%,经4.6%~47.5%,降低到1.0%~15.5%。成矿流体在其演化过程中发生过不混溶作用和沸腾作用。不混溶作用发生在气成热液期,使成矿流体中的成矿元素大量富集。沸腾作用发生在中高温热液期,导致成矿流体中的成矿元素卸载而沉淀出大量金属硫化物。 相似文献
5.
西格拉花岗岩体位于祁连东部的米屈花岗岩带上,空间上呈NW-NWW向展布,岩体由花岗闪长岩-花岗岩-正长岩组成,主要岩性为花岗闪长岩。LA-ICP-MS锆石U-Pb定年结果表明,西格拉花岗闪长岩存在两期岩浆作用,年龄分别为465.6±6.5Ma、443.2±4.8Ma,其中,前者与祁连洋俯冲极性发生转变的时限(~463Ma)相近,而后者与祁连洋闭合的时间(~445Ma)相似。早期淡色花岗闪长岩具正铕异常(δEu=2.44),晚期暗色花岗闪长岩则为弱负/正铕异常(δEu=0.94~1.32),两者均显示出高Si、Al,富Na贫K,富集Ba、Sr、LREE,高Sr/Y值,低Y、HREE含量,亏损HFSE(Nb、Ta、Ti、P)的特征,与Martin et al.(2005)划分的高硅埃达克岩(HSA)相似。其源区可能均残留石榴子石、普通角闪石及少量金红石,而斜长石则大量参与部分熔融过程,推测早期花岗闪长岩的源区深度可能超过50km;整体上,由早期→晚期反映出加厚地壳减薄、地幔组分贡献增强的趋势;两者可能均为加厚下地壳物质部分熔融的产物。 相似文献
6.
凤凰山花岗闪长岩是铜陵地区出露面积最大的岩体,约10 km2,属高钾钙碱性系列.位于该岩体西北角的朱家山附近ZK66钻孔揭示,岩体超覆于三叠纪碳酸盐岩地层之上.除在浅部见到花岗闪长岩之外,深部主要见到晚泥盆世-二叠纪地层.特别是在石炭纪大理岩中见到辉绿岩和花岗斑岩,其锆石LA-ICP-MS U-Pb年龄分别为304 Ma和132 Ma,证明本区存在晚古生代岩浆活动,而中生代花岗质岩浆活动可能持续到132 Ma.晚石炭世辉绿岩的发现,说明该时期海底是一种拉张环境,海底喷流作用可能与岩浆活动有密切的成因关系,为该时期形成大型矿床奠定了基础. 相似文献
7.
水银洞金矿床是黔西南地区著名的特大型微细浸染型金矿床.对矿石品位统计分布特征的分析表明,水银洞金矿床为多次成矿作用叠加的产物.通过矿石品位进行混合总体筛分获得两个单一总体,分别对应两次成矿作用,即沉积成岩期的金预富集和构造-热液期的叠加成矿,其中后者成矿强度大但不均匀,前者成矿强度小但较均匀.对矿体自相关特征的变异函数模拟结果表明,对该矿床进行勘探时可采用沿矿体走向和倾向方向布置的矩形勘探网,提出今后矿山和外围的勘探可以使用比目前网矩更宽的网距,即75 m×190 m网距来控制矿体,这将大大降低勘探成本.矿石品位的趋势面分析结果表明,随着标高的降低,即往深部方向矿石品位的平均值和变化系数均呈现明显的下降趋势,说明往深部矿化强度减小,而矿化变得较均匀.结合矿区目前的勘探情况和趋势面分析结果,认为灰家堡背斜的北翼是矿区及其外围进一步找矿的重点区域. 相似文献
8.
The textural characteristics and trace element geochemistry of hematite with U-W-Sn-Mo signatures from the Cu-U-Au-Ag orebody at Olympic Dam, South Australia, are documented. Olympic Dam is the archetype for iron-oxide copper–gold (IOCG) deposits where hematite is by far the most abundant mineral in the orebody. The deposit is located within hematite-bearing breccias (>5% Fe) hosted by the ∼1.6 Ga Roxby Downs Granite (RDG). Although such breccias are mostly derived from RDG, they also include volcanic clasts and sedimentary rocks. Samples cover the ∼6 km strike length and ∼2 km vertical extent of mineralisation, including hematite from the aforementioned lithologies. Hematite with U-W-Sn-Mo (‘granitophile’ elements) signatures is recognised throughout all lithologies and parts of the deposit. Hematite enriched in granitophile elements is represented by a variety of textures, of which zoned hematite, defined by oscillatory zonation patterns, is the most prominent and can be tied to the age of the RDG, and thus initiation of the IOCG system as confirmed by published U-Pb geochronology. Other categories of hematite with granitophile signatures include hematite resulting from replacement of pre-existing minerals (e.g., carbonates and feldspars), as well as replacement of previous oscillatory-zoned hematites. Matrix and vacuole filling hematite from volcanoclastic-dominated intervals also carry ‘granitophile’ signatures. In addition, some colloform types which likely post-date primary IOCG mineralisation are also rich in ‘granitophile’ elements. Trace element mapping and spot analysis by laser ablation inductively coupled plasma mass spectrometry (LA-ICP-MS) defines complex trace element signatures of hematite, which, in addition to the ‘granitophile’ elements, also comprise rare earth elements, high field strength elements, chalcogens and transition metals.The distinct geochemical signature, characterised by enrichment in the ‘granitophile’ elements (up to wt% levels of U and W within individual zones, and up to thousands of ppm Mo and Sn) prevails throughout the hematite in the deposit irrespective of textures. Iron-oxides have been repeatedly formed, reworked and overprinted by subsequent cycles of brecciation, fluid-mineral reaction, remobilization, element redistribution and recrystallisation. Coupled dissolution-replacement reactions are discussed as having played a major role in the modification of textural and geochemical patterns in hematite, but also allow for widespread preservation of primary geochemical signatures. Despite its simple chemistry, the crystal-structural modularity of hematite can adapt and retain evolving fluid signatures. The reported trace element signatures are fully concordant with conceptual frameworks for the genesis of IOCG systems, and may be an inherent, albeit hitherto under-reported characteristic of other IOCG systems. Hematite is probably by far the most important W-, Sn- and Mo-bearing phase in the deposit by mass. 相似文献
9.
铜陵地区成岩成矿背景探讨 总被引:2,自引:0,他引:2
铜陵地区是长江中下游多金属成矿带重要矿集区之一,也是我国重要的有色金属基地之一,以盛产铜、金等矿产而闻名于世,尤其是铜矿资源十分丰富,享有中国古铜都之称.铜陵地区内的矿床类型主要为夕卡岩型、层控夕卡岩型,其次为规模小、位于一些矿床深部的斑岩型(铜官山、新桥等),成矿作用与晚中生代(120~140Ma)大规模的岩浆活动有关[1,2].矿床与侵入岩岩体在空间上密切相关,在时间上与岩体的侵入时间相接近.侵入岩体可划分为碱性系列及钙碱性系列,不是从碱性玄武岩浆直接分异演化而成的,而是底侵的碱性玄武质岩浆与下地壳闪长质岩浆混合、发生AFC过程的产物.构造环境为岩石圈伸展作用下的拉张环境.尽管铜陵地区研究程度很高,但在该区仍有找寻到新的隐伏矿床的可能,本文旨在通过总结前人对该区的研究,为铜陵地区下一步的勘探工作提供科学依据. 相似文献
10.
大别山北缘主要由佛子岭群和庐镇关群组成,其处于华北和扬子板块结合处,是探究两大板块耦合过程的关键部位。相对于大别造山带高压-超高压单元的丰硕研究成果,大别山北缘相关的研究较为薄弱,迟滞了对大别造山带演化过程的深入探究。本次研究通过对佛子岭群和庐镇关群详细的野外调查、岩相学、热力学评价和年代学研究,较为详细地阐释了大别山北缘基本变质属性和演化过程。研究表明,佛子岭群主要由各类片岩和部分大理岩构成,并展现了一个巨大的宽缓的"背形"。庐镇关群主体为花岗片麻岩,少部分为斜长角闪岩和石榴黑云母二长片麻岩,其与佛子岭群呈构造并置关系。区域性的峰期变质PT条件估算显示,并结合前人资料,佛子岭群变质温压为T=524~621℃和P=0.59~0.96GPa,庐镇关群变质温压为T=575~625℃和P=0.87~0.96GPa,两者均落入中高压角闪岩相范畴。在空间分布上,自南至北,佛子岭群的温度压力显示了一个逐渐变化趋势,反映了一个由浅至深的俯冲状态型式。锆石U-Pb定年显示,庐镇关群的石榴黑云母二长片麻岩、花岗片麻岩和斜长角闪岩的原岩结晶年龄分别为756±6Ma、758±7Ma、764±6Ma,属于扬子板块北缘产物。佛子岭群的石榴二云母片岩则显示了四个峰值为2.50Ga、0.93Ga、0.85Ga和0.45Ga碎屑锆石年龄,佛子岭群具有华北、扬子板块和古生代岛弧混合物源性,并推测其为一个形成于晚古生代的独立微陆块。综合已有的变质年龄资料分析,佛子岭群记录了345~355Ma晚古生代增生造山和260~270Ma印支期碰撞造山两期事件,这意味着大别造山带可能为一个增生型和碰撞型复合造山带,且该造山带可与西侧的桐柏-红安造山带充分对应。 相似文献