八庙-青山金红石矿床地球化学特征

金红石矿床含矿岩石常量元素总体上与玄武岩接近,但以低硅,高钛,高ＣＯ２,高碱度为特征。矿床微量元素与地壳的差别显著,稀土元素较高,分布模式呈轻稀土富集型,Ｅｕ一般为正常型与碧玄岩最接近,Ｔｉ与Ｂａ,Ｃｏ,Ｐｂ,Ｓｒ,Ｔｈ,Ｖ,Ｙ及稀土元素呈正相关与Ｃｒ和Ｎｉ呈负相关,δ＾３４Ｓ多数与（超）铁镁质岩石接近,最大值小于且靠近现代海水。     

江西银山铜多金属矿床成因再认识

从矿体形态、蚀变、矿化分带、稳定同位素和矿物包裹体等方面论述了矿床与本区岩浆活动在时间、空间和成矿物质来源等方面的关系,提出了银山铜多金属矿床是与燕山早期岩浆活动有关的火山—次火山热液矿床的新认识。     

新疆哈密卡拉塔格铜(锌)矿红石幅1∶50 000矿产地质图数据库

新疆哈密卡拉塔格铜(锌)矿红石幅(K46E009008)1∶50 000矿产地质图数据库是根据《固体矿产地质调查技术要求(1∶50 000)》(DD2019-02)和行业其他标准及要求,在充分利用1∶200 000、1∶50 000等区域地质调查工作成果资料的基础上,采用数字填图系统进行野外地质专项填图,并应用室内与室外填编图相结合的方法完成。本数据库将中-上奥陶统荒草坡群大柳沟组、下志留统红柳峡组和卡拉塔格组的建造类型进行了重新划分,把图幅内侵入岩时代划分为志留纪、泥盆纪、二叠纪等3期,建立了岩浆岩演化序列。图幅区内有大中小型矿床和矿点共8个,成矿时代集中分布在志留纪、石炭纪,赋矿围岩为火山碎屑岩和次火山岩,该区优势矿产以铜锌金为主,矿床类型以VMS型和次火山热液脉型矿床为主,分布在图幅东南一带。除金属矿产外,尚有膨润土矿床产出,具有较好的找矿潜力。本数据库包含5个地层单位和3期岩浆岩资料,数据量约为 15.1 MB。这些数据充分反映了该图幅 1∶50 000 矿产地质调查示范性成果,对该区矿产资源研究和勘查等具有参考意义。     

云南广南县老寨湾金矿地质特征及找矿标志

广南县老寨湾金矿位于滇、黔、桂“金三角”重要成矿区带上,金矿体矿体呈似层状赋存于断层构造破碎带或层间构造破碎带中,构造控矿明显。矿体围岩均为下泥盆统坡松冲组第一段(D1ps1)硅化石英砂岩;矿床成因属中-低温热液叠加改造型金矿床,断层构造、硅化等矿化蚀变及地球化学异常是重要的找矿标志。     

贵州省松桃县木耳溪锰矿地质特征及找矿方向

贵州松桃县木耳溪锰矿为典型的层控型锰矿床,矿体呈层状赋存于南华系下统大塘坡组第一段(Pt2b3d 1)底部的炭质页岩中,产出层位稳定,矿体产状与围岩产状一致。通过统计对比,锰矿层的矿化程度与含锰岩系的厚度呈正比,即当南华系大塘坡组地层厚度大于15m时,有可能成为锰矿的主要找矿方向。     

大兴安岭南东段龙头山银铅锌多金属矿床成矿地质特征与远景评价

文章阐述了龙头山银铅锌多金属矿床的地质特征,初步确定了矿床的成矿期与成矿阶段、蚀变作用与蚀变分带,以及控矿构造系统与空间变化等;通过合理的探矿工程并借助于先进的地球物理探测手段,基本探明了Ⅰ、Ⅱ号矿带内矿体的空间产出形态、规模和产状,大致查明了矿石的类型、结构构造以及矿化特征,并合理地圈定了矿体;通过综合取样分析,估算并预测了远景资源储量.     

河南省商城县汤家坪钼矿床地质和流体包裹体研究

河南省商城县汤家坪钼矿床产于大别造山带,属于陆-陆碰撞体制的斑岩型矿床。其流体成矿过程可以分为早、中、晚3个阶段,分别以石英-钾长石-磁铁矿-辉钼矿-黄铁矿、石英-多金属硫化物和石英-碳酸盐±黄铁矿组合为标志。石英中可见水溶液包裹体、CO₂-H₂O型包裹体、纯CO₂包裹体和含子晶多相包裹体,但晚阶段石英中只有水溶液包裹体。早阶段和中阶段还发育特殊的含子晶的CO₂包裹体,这在以往的斑岩型矿床中鲜有报道。早阶段流体包裹体均一温度>375℃,盐度最高可达62.10％NaCl_eqv,包裹体内含大量指示氧化条件的赤铁矿子晶以及一些石盐、钾盐、黄铜矿、脆硫锑铅矿子晶。中阶段包裹体均一温度集中在235~335℃,盐度为1.06％~45.87％NaCl_eqv。除石盐、钾盐子晶外,还含大量黄铜矿、脆硫锑铅矿子晶,表明中阶段还原性较强。晚阶段流体包裹体均一温度集中在115~195℃,盐度较低,介于1.91％~9.98％NaCl_eqv。中阶段强烈的流体沸腾作用是导致成矿物质快速沉淀的重要机制。总之,初始成矿流体为岩浆热液,以高温、高盐度、高氧化性、富CO₂、高金属元素含量为特征;中阶段流体发生沸腾,导致CO₂逃逸,氧化性降低,成矿物质快速沉淀;晚阶段流体以低温、低盐度、无子晶、贫CO₂为特征,属于大气降水热液。汤家坪钼矿床发育特殊的含子晶的CO₂包裹体,可作为大陆碰撞造山带产出富含CO₂的斑岩成矿系统的典型实例。     

下刚果—刚果扇盆地断裂特征及其对油气成藏的影响

下刚果—刚果扇盆地油气资源丰富、油气成藏条件优越。但由于受到盐岩的活动及区域构造应力场的作用,形成了复杂的断裂系统。此文系统分析了下刚果—刚果扇盆地的断裂特征及其对油气成藏的影响,研究认为该区平面上主要发育5个断裂带,纵向上主要发育上下两套断裂系统。断裂的形成和演化可分为三个期次,相对应可将断层分为三个级别的断层。断层的形成机制主要有盐活动及盐构造、重力滑脱作用以及古地貌格局。烃源岩的排烃时间与第三期断层活动时间相匹配,非常有利于油气沿断层进行垂向和斜侧向运移。分析认为研究区主要发育沿断阶带—碳酸盐岩运聚成藏模式、沿断层垂向运聚成藏模式以及沿盐下砂体—盐窗和Focus点运聚成藏模式共三种成藏模式。断层封堵较好,油源断层高度决定了油气运移高度和油气田规模,直接控制着油气的分布层系及规模。研究成果可指导研究区或类似地区的油气勘探。     

准噶尔西北缘玛北地区扇三角洲砂砾岩岩相分类及储集意义

准噶尔盆地西北缘三叠系处于大型逆冲推覆断裂带,盆地边缘同生断裂构造活动强烈,发育砂砾岩为主的扇三角洲沉积体系。通过对玛北地区三叠系百口泉组砂砾岩储层取芯段岩芯观察和描述、岩石薄片、扫描电镜、测井以及储层物性数据的分析,结合砂砾岩岩石构成、层理类型、沉积层序和测井曲线响应特征,对准噶尔盆地西北缘砂砾岩体岩性进行精细刻画,建立岩相模式,划分出同沉积相(微相)相符的11种岩相:其中扇三角洲前缘水下河道砂砾岩相、扇三角洲平原辫状河道砂砾岩相叠置连片展布,是最有利的储集体;扇三角洲前缘水下主河道砾岩相、水下河道末端砂岩相及河口坝—远砂坝砂岩相分布局限,储集性良好,为有利"甜点"区;水上泥石流砾岩相和水下泥石流砂砾岩相与扇三角洲平原和前缘分流河道间储集性较差的细粒砂泥岩相组成百口泉组油藏致密的顶底板;前扇三角洲粉砂岩相和泥岩相可作为良好的区域性盖层。不同的岩相类型及沉积条件提供了准噶尔西北缘百口泉组大规模低渗透岩性油气藏优良的储盖组合及顶底板条件。     

Relative contribution of magmatic and post-magmatic processes in the genesis of the Thompson Mine Ni-Co sulfide ores,Manitoba, Canada

The Ni-Co-(PGE) sulfide deposits of the Thompson Nickel Belt (TNB) in Northern Manitoba, Canada are part of the fifth largest nickel camp in the world based on contained nickel; past production from the TNB deposits is 2500 kt Ni. The Thompson Deposit is located on the eastern and southern flanks of the Thompson Dome structure, which is a re-folded nappe structure formed during collision of the Trans-Hudson Orogen with the Canadian Shield at 1.9–1.7 Ga. The Thompson Deposit is almost entirely hosted by P2 member sulfidic metasedimentary rocks of the Paleoproterozoic Ospwagan Group. Variably serpentinised and altered dunites, peridotites and pyroxenites contain disseminated sulfides and have a spatial association with sediment-hosted Ni sulfides which comprise the bulk of the ore types. These rocks formed from rift-related komatiitic magmas that were emplaced at 1.88 Ga, and subsequently deformed by boudinage, thinning, folding, and stacking.Disseminated sulfide mineralization in the large serpentinised peridotite and dunite intrusions that host the Birchtree and Pipe Ni-Co sulfide deposits typically has 4–6 wt% Ni in 100% sulfide. The disseminated sulfides in the less abundant and much smaller boudinaged serpentinised peridotite and dunite bodies associated with the Thompson Deposit have 7–10 wt% Ni in 100% sulfide. The majority of Thompson Mine sulfides are hosted in the P2 member of the Pipe Formation which is a sulfidic schist developed from a shale prololith; the mineralization in the schist includes both low Ni tenor (<1 wt% Ni in sulfide) and barren sulfide (<200 ppm Ni) and a Ni-enriched sulfide with 1–18 wt% Ni in 100% sulfide. The semi-massive and massive sulfide ores show a similar range in Ni tenor to the metasediment-hosted mineralization, but there are discrete populations with maximum Ni tenors of ∼8, 11 and 13 wt% Ni in 100% sulfide. The variations in Ni tenor are related to the Ni/Co ratio (high Ni/Co correlates with high Ni tenor sulfide) and this relationship is produced by the different Ni/Co ratios in sulfides with a range in proportions of pyrrhotite and pentlandite. Geological models of the ore deposit, host rocks, and sulfide geochemical data in three dimensions reveal that the Thompson Deposit forms an anastomosing domain on the south and east flanks of a first order D3 structure which is the Thompson Dome. In detail, a series of second order doubly-plunging folds on the eastern and southern flank control the geometry of the mineral zones. The position of these folds on the flank of the Thompson Dome is a response to the anisotropy of the host rocks during deformation; ultramafic boudins and layers of massive quartzite in ductile metasedimentary rocks control the geometry of the doubly-plunging F3 structures. The envelope of mineralization is almost entirely contained within the P2 member of the Pipe formation, so the deposit is clearly folded by the first order and second order D3 structures. The sulfides with highest Ni tenor (typically >13 wt% Ni in sulfide) define a systematic trend that mirrors the configuration of the second order doubly-plunging F3 structures on the flanks of the Dome. Although moderate to high Ni tenor mineralization is sometimes localized in fold hinges, more typically the highest Ni tenor mineralization is located on the flanks of the fold structures.There is no indication of the mineralogical and geochemical signatures of sedimentary exhalative or hydrothermal processes in the genesis of the Thompson ores. The primary origin of the mineralization is undoubtedly magmatic and this was a critical stage in the development of economic mineralization. Variations in metal tenor in disseminated sulfides contained in ultramafic rock indicate a higher magma/sulfide ratio in the Thompson parental magma relative to Birchtree and Pipe. The variation in Ni tenor of the semi-massive and massive sulfide broadly supports this conclusion, but the variations in metal tenor in the Thompson ores was likely created partly during deformation. The sequence of rocks was modified by burial and loading of the crust (D2 events) to a peak temperature of 750 °C and pressure of 7.5 kbar. The third major phase of deformation (D3) was a sinistral transpression (D3 event) which generated the dome and basin configuration of the TNB. These conditions allowed for progressive deformation and reformation of pyrrhotite and pentlandite into monosulfide solid solution as pressure and temperature increased; this process is termed sulfide kinesis. Separation of the ductile monosulfide solid solution from granular pentlandite would result in an effective separation of Ni during metamorphism, and the monosulfide solid solution would likely be spread out in the stratigraphy to form a broad halo around the main deposit to produce the low Ni tenor sulfide. Reformation of pentlandite and pyrrhotite after the peak D2 event would explain the broad footprint of the mineral system. The effect of the D3 event at lower pressure and temperature would have been to locally redistribute, deform, and repeat the lenses of sulfide.The understanding of the relationships between petrology, stratigraphy, structure, and geochemistry has assisted in formulating a predictive exploration model that has triggered new discoveries to the north and south of the mine, and provides a framework for understanding ore genesis in deformed terrains and the future exploration of the Thompson Nickel Belt.