新疆阔尔真阔腊金矿床成矿流体包裹体研究

新疆西北部阔尔真阔腊金矿床是产于海西期岛弧型钙碱性火山岩中的火山晚期热液型金矿床。流体包裹体研究表明,成矿阶段(Ⅰ)包裹体为气相包裹体,均一温度为308～396℃,盐度为5．86～8．41wt％NaCl;主成矿阶段(Ⅱ、Ⅲ)为气液包裹体,均一温度分别为209～276℃(Ⅱ)、119～198℃(Ⅲ),盐度分别为5．11～7．86wt％NaCl(Ⅱ)、2．74～6．17wt％NaCl(Ⅲ)。石英流体包裹体成分测定采用分阶段法,有效地排除了不同成矿阶段包裹体成分的影响,准确地测出了成矿阶段(Ⅰ)和主成矿阶段(Ⅱ、Ⅲ)包裹体的成分,结果表明成矿流体具Na^ -H^--Cl^--H2O型中低温、低盐特征,金主要以金硫络合物的形式迁移,金矿化是在还原条件下进行。主成矿阶段包裹体中水的氢同位素组成为-83．97～-89．07‰,氧同位素组成为1．8～3．2‰,成矿流体是岩浆热液与古大气降水混合而成。流体混合及水-岩反应是造成本区金沉淀成矿的主要因素。     

基于GIS的个旧花岗岩凹陷带空间信息成矿预测模型

基于GIS技术,对云南个旧花岗岩凹陷带进行数字矿床空间信息成矿预测模型的研究。在了解个旧矿田地质的基础上,通过工作区信息统计单元的划分、预测区地质信息(包括地层、构造、岩浆岩、矿化蚀变以及物、化、遥异常等)变量的确定以及编码和赋值,采用特征分析法确定空间网格单元成矿异常有利度模型,从成矿预测单元中最终圈定了找矿优选靶区。结果表明了信息统计单元结合特征分析数学方法是可行的。     

Cyclicity in the Main and Upper Zones of the Bushveld Complex, South Africa: Crystallization from a Zoned Magma Sheet

The major element composition of plagioclase, pyroxene, olivine,and magnetite, and whole-rock ⁸⁷Sr/⁸⁶Sr data are presented forthe uppermost 2·1 km of the layered mafic rocks (upperMain Zone and Upper Zone) at Bierkraal in the western BushveldComplex. Initial ⁸⁷Sr/⁸⁶Sr ratios are near-constant (0·7073± 0·0001) for 24 samples and imply crystallizationfrom a homogeneous magma sheet without major magma rechargeor assimilation. The 2125 m thick section investigated in drillcore comprises 26 magnetitite and six nelsonite (magnetite–ilmenite–apatite)layers and changes up-section from gabbronorite (An₇₂ plagioclase;Mg# 74 clinopyroxene) to magnetite–ilmenite–apatite–fayaliteferrodiorite (An₄₃; Mg# 5 clinopyroxene; Fo₁ olivine). The overallfractionation trend is, however, interrupted by reversals characterizedby higher An% of plagioclase, higher Mg# of pyroxene and olivine,and higher V₂O₅ of magnetite. In the upper half of the successionthere is also the intermittent presence of cumulus olivine andapatite. These reversals in normal fractionation trends definethe bases of at least nine major cycles. We have calculateda plausible composition for the magma from which this entiresuccession formed. Forward fractional crystallization modelingof this composition predicts an initial increase in total iron,near-constant SiO₂ and an increasing density of the residualmagma before magnetite crystallizes. After magnetite beginsto crystallize the residual magma shows a near-constant totaliron, an increase in SiO₂ and decrease in density. We explainthe observed cyclicity by bottom crystallization. Initiallymagma stratification developed during crystallization of thebasal gabbronorites. Once magnetite began to crystallize, periodicdensity inversion led to mixing with the overlying magma layer,producing mineralogical breaks between fractionation cycles.The magnetitite and nelsonite layers mainly occur within fractionationcycles, not at their bases. In at least two cases, crystallizationof thick magnetitite layers may have lowered the density ofthe basal layer of melt dramatically, and triggered the proposeddensity inversion, resulting in close, but not perfect, coincidenceof mineralogical breaks and packages of magnetitite layers. KEY WORDS: layered intrusion; mineral chemistry; isotopes; magma; convection; differentiation     

东平县矿产资源管理探讨

从东平县矿产资源的勘查开发历史、资源保有现状、勘查开发及矿政管理中存在的问题入手,进一步探讨了加强矿产资源储量管理的问题。矿产资源的有限性和分布不均匀性,决定了矿产资源的开发利用是有限的。如果不合理开发利用,必然会造成矿产资源衰竭和矿山生态环境恶化,使矿产资源与经济发展及环境保护之间的矛盾加剧。     

中国钨矿成矿地质特征与资源潜力分析

钨矿是中国传统优势矿种,前人在钨矿成矿理论方面积累了非常丰富的研究成果。然而,随着近年来在江西、云南和新疆等地取得的多项钨矿重大找矿突破,对原有的钨成矿带地质认识提出了挑战,急需进一步分析和总结其地质特征、成矿规律和资源潜力,为今后地质找矿工作提供理论指导。文中采用矿床模型综合地质信息预测方法,在各省区钨矿资源潜力预测成果的基础上,以MapGIS为平台,进行数据库汇总与综合分析研究。首先,基于全国1 538处钨矿产地数据的统计分析,初步总结了中国钨矿时空分布特征,以及岩浆岩、构造和地层等控矿因素。其次,根据钨矿床及预测区的空间分布和大地构造单元,划分了56个钨矿成矿区带。再次,将钨矿的预测类型划分为石英脉型、夕卡岩型、斑岩型、云英岩型、陆相火山岩型、沉积变质型、层控夕卡岩型和砂矿型,并建立了主要钨矿类型的预测模型。最后,在全国范围累计圈定的1 357个最小预测,累计预测资源量(WO3)2 973×104 t。根据钨矿区域成矿特征,将最小预测区归并为461个二级预测区,并进一步合并为118个钨矿三级预测区,其中,找矿潜力大的河南卢氏-栾川、新疆白干湖、湖南香花岭-瑶岗仙、甘肃野马滩-干巴河脑、江西坪背山-八仙脑和大湖塘等6个三级预测区可优先部署钨矿勘查工作。     

胶东英格庄金矿床地质地球化学特征

英格庄金矿床是胶东牟平-乳山金矿成矿带重要的石英脉型金矿床之一,其产出和分布严格受NNE向断裂控制,围岩以古老变质岩和昆嵛山花岗岩为主,金矿物主要以晶隙金形式赋存于黄铁矿-脉石晶体之间。通过成矿流体包裹体地球化学研究可知:均一温度变化有3个峰值(155℃～165℃、205℃～215℃和245℃～265℃);该矿床包裹体盐度w(NaCl)较低(17.17(),在1.05(～17.17(之间变化,应属于低盐度流体;据其成矿压力21.3～58.8MPa,进一步求得的该矿床主要成矿深度为0.83～2.31km,为中浅成矿床;依据包裹体成分测试结果可知,矿床流体属K+-Na+-SO24-Cl-型。氢氧同位素显示其成矿流体主要来源于岩浆水和变质水,并有一定的大气降水混入。     

油气和含油气包裹体及其在油气地质地球化学研究中的意义

本文在综合前人研究的基础上，结合笔者的工作经验，提出了一个实用的油气和含油气包裹体分类方案，详细论述了各类油气和含油气包裹体的相态、组成和均一温度特征。在同一油气藏，均一温度越高，油相包裹体中的气态烃和挥发份的含量也越高。依据油相包裹体的均一温度的变化及其与同生水溶液包裹体的均一温度的关系可以研究油气藏在充填过程中油气组成，特别是气态烃和挥发份含量的演变。进而可以研究油气藏的油源--生油岩的类型和热演化程度。本文评述了依据油相包裹体和同生水溶液包裹体ＰＶＴ相图推断其捕获温度和压力范围的有效性和局限性。最后讨论了各类油气和含油气包裹体的成因机制及其在油气地质和地球化学研究中的意义。     

利用测井资料分析成岩作用对储集层的影响

应用测井资料进行压实作用、孔隙演化、裂缝、矿物成分详尽分析基础上 ,结合成岩作用各个阶段对储集层性能影响的研究 ,讨论了应用测井资料分析成岩作用对储集层影响的物理基础 ,进而指出应用测井资料分析成岩作用不同阶段对储集层影响的可行性。方法为 :(1 )成岩作用早期 :应用孔隙度测井和岩性测井资料 ,通过压实曲线分析压实作用区间 ;(2 )成岩作用中期 :首先根据孔隙度测井资料分析声波孔隙度、密度 -中子测井孔隙度 ,分析次生孔隙 ,并应用交会图技术 ,确定矿物成分 ,分析胶结、交代作用形式和强度 ,然后根据泥质指示测井确定泥质含量 ,进一步利用自然伽玛能谱测井 ,尤其是Th、K含量分析粘土矿物 ;(3)成岩作用晚期 :进行次生孔隙、裂缝、颗粒成分与含量、粘土矿物分布规律研究。以上分析方法经吐哈盆地实际资料验证 ,效果良好     

Evaporites,brines and base metals: Low‐temperature ore emplacement controlled by evaporite diagenesis

Salt beds and salt allochthons are transient features in most sedimentary basins, which through their dissolution can carry, focus and fix base metals. The mineralisation can be subsalt, intrasalt or suprasalt, and the salt body or its breccia can be bedded or halokinetic. In all these evaporite‐associated low‐temperature diagenetic ore deposits there are four common factors that can be used to recognise suitably prepared ground for mineralisation: (i) a dissolving evaporite bed acts either as a supplier of chloride‐rich basinal brines capable of leaching metals, or as a supplier of sulfur and organics that can fix metals; (ii) where the dissolving bed is acting as a supplier of chloride‐rich brines, there is a suitable nearby source of metals that can be leached by these basinal brines (redbeds, thick shales, volcaniclastics, basalts); (iii) there is a stable redox interface where these metalliferous chloride‐rich waters mix with anoxic waters within a pore‐fluid environment that is rich in organics and sulfate/sulfide/H₂S; and (iv) there is a salt‐induced focusing mechanism that allows for a stable, long‐term maintenance of the redox front, e.g. the underbelly of the salt bed or allochthon (subsalt deposits), dissolution or halokinetically maintained fault activity in the overburden (suprasalt deposits), or a stratabound intrabed evaporite dissolution front (intrasalt deposits). The diagenetic evaporite ‐ base‐metal association includes world‐class Cu deposits, such as the Kupferschiefer‐style Lubin deposits of Poland and the large accumulations in the Dzhezkazgan region of Kazakhstan. The Lubin deposits are subsalt and occur where long‐term dissolution of salt, in conjunction with upwelling metalliferous basin brines, created a stable redox front, now indicated by the facies of the Rote Faule. The Dzhezkazgan deposits (as well as smaller scale Lisbon Valley style deposits) are suprasalt halokinetic features and formed where a dissolving halite‐dominated salt dome maintained a structural focus to a regional redox interface. Halokinesis and dissolution of the salt bed also drove the subsalt circulation system whereby metalliferous saline brines convectively leached underlying sediments. In both scenarios, the resulting redox‐precipitated sulfides are zoned and arranged in the order Cu, Pb, Zn as one moves away from the zone of salt‐solution supplied brines. This redox zonation can be used as a regional pointer to both mineralisation and, more academically, to the position of a former salt bed. In the fault‐fed suprasalt accumulations the feeder faults were typically created and maintained by the jiggling of brittle overburden blocks atop a moving and dissolving salt unit. A similar mechanism localises many of the caprock replacement haloes seen in the diapiric provinces of the Gulf of Mexico and Northern Africa. Evaporite‐associated Pb–Zn deposits, like Cu deposits, are focused by brine flows associated with both bedded and halokinetic salt units or their residues. Stratabound deposits, such as Gays River and Cadjebut, have formed immediately adjacent to or within the bedded salt body, with the bedded sulfate acting as a sulfur source. In allochthon/diapir deposits the Pb–Zn mineralisation can occur both within a caprock or adjacent to the salt structure as replacements of peridiapiric organic‐rich pyritic sediments. In the latter case the conditions of bottom anoxia that allowed the preservation of pyrite were created by the presence of brine springs and seeps fed from the dissolution of nearby salt sheets and diapirs. The deposits in the peridiapiric group tend to be widespread, but individual deposits tend to be relatively small and many are subeconomic. However, their occurrence indicates an active metal‐cycling mechanism in the basin. Given the right association of salt allochthon, tectonics, source substrate and brine ponding, the system can form much less common but world‐class deposits where base‐metal sulfides replaced pyritic laminites at burial depths ranging from centimetres to kilometres. This set of diagenetic brine‐focusing mechanisms are active today beneath the floor of the Atlantis II Deep and are thought to have their ancient counterparts in some Proterozoic sedex deposits. The position of the allochthon, its lateral continuity, and the type of sediment it overlies controls the size of the accumulation and whether it is Cu or Pb–Zn dominated.     

SILLS软件在单个萤石流体包裹体LA-ICP-MS微量元素分析数据处理中的应用

近年来激光剥蚀电感耦合等离子体质谱(LA-ICP-MS)应用于单个流体包裹体成分定量分析已成为研究流体包裹体的最佳手段之一。该实验过程和数据处理比较复杂,目前国内外采用的数据分析软件为一款基于MATLAB的SILLS软件,该软件主要是对矿物(锆石)、流体包裹体以及熔体包裹体LA-ICP-MS分析结果进行处理。本文以萤石流体包裹体LA-ICP-MS分析为例,阐述了样品制备与流体包裹体的优选方法,对流体包裹体片厚度以及单个流体包裹体的选取要求作了详细描述,对仪器参数设置、内外标样选取和剥蚀方法等进行了说明。基于SILLS软件采用尖峰消除的方法对待处理数据进行校正,对不同种类型的波峰进行峰宽的选取。在元素比值校正和等效盐度计算过程中,由于被测样品是萤石,Ca元素具有较高的背景值,选择以Na作为流体包裹体的内标元素,以Ca作为寄主矿物的内标元素对寄主矿物浓度进行计算,同时提出以电价平衡代替质量平衡进行等效盐度计算。以上方案提高了LA-ICP-MS分析单个萤石流体包裹体的准确性,有助于解释成矿流体来源和矿床成因等问题。