河北省宣龙式铁矿的地球化学特征及其地质意义   总被引：7，自引：4，他引：3  

李志红  朱祥坤 《岩石学报》2012,28(9):2903-2911

本文报道了宣龙式铁矿的主量元素、微量元素、稀土元素、Fe同位素和Nd同位素的分析结果。结果显示:主量元素的化学成分中Fe2O3T的含量最高,并且具有较高的Al2O3、TiO2和P2O5含量;微量元素含量总体与平均地壳相似,并显示氧化-还原敏感元素V、U、Mo的相对富集;稀土总量高、轻稀土元素亏损重稀土元素富集、无Ce、Eu正异常、Y/Ho比值与地壳平均值相似;同时,铁矿具有较低的εNd值,这些特征表明宣龙式铁矿的成矿物质来源为陆源。相对于标准物质IRMM-014,宣龙式铁矿中赤铁矿的Fe同位素组成均为正值,这与由现代蓝细菌氧化而成的赤铁矿Fe同位素组成应小于或等于0不同,因此,宣龙铁矿是由铁细菌氧化为主的生物粘结矿床。此外,铁矿无Ce的负异常;V、U、Mo的相对富集;Fe同位素比值为正值的这些特征均说明当时铁矿沉淀的环境为低氧状态。  相似文献   

对宣化烟筒山铁矿矿下白色石英砂岩之交错层理的初步分类          下载免费PDF全文

金秀媛  陈丽蓉  汪本善  陈友明 《地质科学》1959,2(4):116-118

1957年6月我們在烟筒山进行宣龙鉄矿研究时,曾根据苏联的經驗对矿层下岩系中之一层厚12米的白色石英砂岩进行了斜层理测量及交錯层理野外分类。  相似文献   

一种猛攻硬岩层的好方法——三边速续投砂法          下载免费PDF全文

孙振源 《探矿工程》1959,(9)

我队勘探的鞍山式铁矿及宣龙式铁矿,绝大部分岩石都是7—11级的石英岩、花岗片麻岩、安山岩等。岩性致密坚硬,因而如何解决钻粒钻进问题是提高钻探生产效率的关键。  相似文献   

河北宣化姜家寨铁矿床串岭沟组底部碎屑锆石LA-MC-ICP-MS U-Pb年龄及其地质意义   总被引：1，自引：0，他引：1  

段超  李延河  魏明辉  杨云  侯可军  陈小丹  邹斌 《岩石学报》2014,30(1):35-48

宣龙式铁矿是我国北方最重要的沉积型铁矿床。华北克拉通长城系串岭沟组底部砂页岩是宣龙式铁矿床的赋存层位,对该地层的年代学研究有助于深入完善长城系地层年代框架、认识区域成岩成矿过程并反演克拉通的演化历史。本文对河北宣化姜家寨铁矿床串岭沟组底部铁矿体顶板砂页岩中碎屑锆石进行了LA-MC-ICP-MS锆石U-Pb年代学研究,获得了三组主要的峰值年龄,加权平均年龄分别为1774.1±7.9Ma、1849.0±7.8Ma和2453.0±7.8Ma。揭示出华北克拉通中部带经历了三期较为重要的地质构造、岩浆作用和变质作用事件。在串岭沟组下部砂岩中我们获得了4颗较年轻的岩浆碎屑锆石,年龄为1657.4～1694.4Ma,代表了串岭沟组底部形成的时间下限,制约了姜家寨宣龙式铁矿床的形成时代不早于1657Ma。对比研究得出,1774.1Ma的峰值年龄数据与华北克拉通内18亿年后广泛发育的基性岩墙群的形成时代一致,代表了华北克拉通的在拼合后的抬升事件时间。在1.8～1.6Ga华北克拉通拉张期间形成了大庙式等钒钛磁铁矿-磷灰石铁矿(1720Ma左右)。基于时间和区域的一致性,我们推断,遭受抬升剥蚀的富铁基性岩墙群不仅是串岭沟组的物源之一,极有可能也是宣龙式铁矿床中铁质的主要物源之一。  相似文献   

谈谈岩相古地理     

柳淮之 《地质与勘探》1978,(1)

众所周知,沉积矿产在各类矿产中占有很大比例。沉积铁矿(包括沉积变质铁矿)在世界铁矿总储量中约占80％,特别是大型富铁矿——前寒武纪铁硅建造富矿,全是沉积形成的。我国北方著名的宣龙式铁矿,南方的綦江式和宁乡式铁矿,也都是沉积生成的。在普查和群众报矿中,这类矿点所占比  相似文献   

有机质在宣龙地区菱铁矿形成中的作用   总被引：2，自引：0，他引：2  

刘敏  陈志明 《沉积学报》1997,15(3):96-102

本文通过对宣龙铁矿中菱铁矿的分布和产状，化学成分，组构特征，碳氧同位素特征及与赤铁矿的生成关系等的分析，对区内菱铁矿进行了较深入细致的研究，进而提出宣龙铁矿中菱铁矿的形成是成岩期有机质对先成赤铁矿还原的结果，沉积物中高铁与低铁的关系直接取决于起还原作用并能把高铁转化为低铁的有机质数量。上述结论又得到了有机地球化学方面资料的证实。  相似文献   

河北省一个铁矿钠质交代岩石的多元统计研究   总被引：1，自引：0，他引：1       下载免费PDF全文

刘承祚  张彦波 《地质科学》1976,11(2):169-183

河北省的一个接触交代型铁矿是一个富铁矿床。铁矿与燕山期中性岩浆侵入杂岩有成因联系,中性岩浆侵入杂岩包括角闪闪长岩-闪长岩和二长岩-闪长岩两个岩石系列。与铁矿关系最密切的岩体侵入在中奥陶统马家沟碳酸岩地层中。  相似文献   

冀西北宣龙地区菱铁矿的成因          下载免费PDF全文

陈志明  于洁  侯奎 《地质科学》1982,(4):395-402

本文以中晚元古代宣龙式铁岩中的菱铁矿为例,讨论碎屑岩中菱铁矿的成因。 宣龙式铁岩产于中晚元古代串岭沟组。成层状,层位稳定,分布较广,西起怀安龙泉寺,东至承德小平台一线均有出露,其中尤以宣龙地区发育最好。 宣龙地区的菱铁矿矿层薄,数量少,往往与赤铁矿构成混合矿体。该区菱铁矿分布规律性明显。横向上,由西往东逐渐增多;纵向上,由下至上由分散状变成层状,与赤铁矿间互产出。  相似文献   

河北宣龙地区微生物铁岩有机地球化学特征及成因意义   总被引：1，自引：0，他引：1  

刘敏  叶连俊  许世远  陈志明  陈其英 《沉积学报》1999,17(1):24-29

通过对宣龙铁矿生物结构类型铁质叠层石、核形石和微生物鲕石所作的有机碳、正烷烃、生物标志物及干酪根红外扫描、元素组成和碳同位素分析,结合地质背景资料、微生物化石等地质标志探讨有机质在铁矿形成中的作用。研究表明,从有机地球化学的角度也可提供生物参与铁质沉淀的证据。  相似文献   

冀西北宣龙式铁矿的Fe同位素特征及其地质意义     

李志红  朱祥坤 《矿物学报》2011,(Z1)

随着多接收器等离子体质谱仪(MC-ICPMS)的诞生,非传统稳定同位素(Fe、Cu、Zn等)研究成为重要的国际地学前沿之一,其中,Fe同位素研究的发展尤其令人关注。宣龙式铁矿是我国大型浅海生物成因的沉积型铁矿床,尤以独特的肾状、鲕状矿石类型和组构为地质学家所瞩目,主要分布于冀西北张家  相似文献   

内蒙白云鄂博铁矿床中磁铁矿和赤铁矿的氧同位素组成   总被引：4，自引：0，他引：4       下载免费PDF全文

魏菊英  上官志冠 《地质科学》1983,(3):217-224

白云鄂博矿床分布在内蒙地轴北部边缘的过渡带。含矿岩系为元古代海相沉积碳酸盐、碎屑岩建造,主要由石英岩、白云岩和板岩组成,其中白云岩是矿体围岩。 矿床受东西向向斜构造控制。向斜以北为一大背斜构造,沿轴部被断层破坏,出露有古老的片麻岩和片岩。向斜以南的背斜构造轴部有海西期黑云母花岗岩侵入,使背斜构造轴部遭受破坏。  相似文献   

中国铁矿资源现状与铁矿实物地质资料筛选   总被引：6，自引：0，他引：6  

崔立伟  夏浩东  王聪  易锦俊  孔令湖  陈佳 《地质与勘探》2012,48(5):894-905

依据我国铁矿资源的类型、成矿区（带）和赋存特点,概述了当前我国铁资源的状况,提出了铁矿资源进行实物地质资料筛选要考虑的因素。结果表明：中国铁矿床类型齐全,以沉积-变质型为主,岩浆型、接触交代-热液型次之;我国铁矿床成矿条件复杂,大型、超大型矿床少,贫矿多、富矿少,且伴（共）生有益组分多,但呈现相对集中分布的特点,主要包括鞍山-本溪、攀西-滇中、冀东-密云、长江中下游、鄂西-湘西北、邯郸-邢台等6个成矿区（带）,新疆地区铁矿资源潜力巨大,是未来找矿的重点;铁矿资源实物地质资料筛选应考虑铁矿床成矿规模、成因类型、成矿时代、成矿区（带）等因素,兼顾具有典型、潜力巨大的铁矿床作为筛选对象。  相似文献   

云南铁矿资源现状及扩大铁矿资源的途径     

薛步高 《化工矿产地质》2005,27(3):157-162

为保证云南钢铁工业可持续发展,解决矿石资源的不足,从分析截止2002年底保有资源量数据入手,研究尚未上表的铁矿资源现状,发现全省上表98处产地保有的35.52亿t储量中,仅有7.91亿t为当前可应用储量。应从补勘升级上表D级储量(3亿t)、择优勘查未上表的矿区(2亿t)、试验-研究3类矿石的选矿回收(菱铁矿石1亿t,鲕状高磷赤铁矿石1亿t,高磷非鲕状赤铁矿石0.5亿t),合计可新增可应用矿石7.5亿t,加上已有的7.91亿t,可应用矿石最终达15.41亿t。再加上第二轮国土资源大调查铁矿的新发现,立足省内,扩大进口,必将缓解云南铁矿资源紧缺的现状。  相似文献   

BIF-hosted iron mineral system: A review     

《Ore Geology Reviews》2016

The BIF-hosted iron ore system represents the world's largest and highest grade iron ore districts and deposits. BIF, the precursor to low- and high-grade BIF hosted iron ore, consists of Archean and Paleoproterozoic Algoma-type BIF (e.g., Serra Norte iron ore district in the Carajás Mineral Province), Proterozoic Lake Superior-type BIF (e.g., deposits in the Hamersley Province and craton), and Neoproterozoic Rapitan-type BIF (e.g., the Urucum iron ore district).The BIF-hosted iron ore system is structurally controlled, mostly via km-scale normal and strike-slips fault systems, which allow large volumes of ascending and descending hydrothermal fluids to circulate during Archean or Proterozoic deformation or early extensional events. Structures are also (passively) accessed via downward flowing supergene fluids during Cenozoic times.At the depositional site the transformation of BIF to low- and high-grade iron ore is controlled by: (1) structural permeability, (2) hypogene alteration caused by ascending deep fluids (largely magmatic or basinal brines), and descending ancient meteoric water, and (3) supergene enrichment via weathering processes. Hematite- and magnetite-based iron ores include a combination of microplaty hematite–martite, microplaty hematite with little or no goethite, martite–goethite, granoblastic hematite, specular hematite and magnetite, magnetite–martite, magnetite-specular hematite and magnetite–amphibole, respectively. Goethite ores with variable amounts of hematite and magnetite are mainly encountered in the weathering zone.In most large deposits, three major hypogene and one supergene ore stages are observed: (1) silica leaching and formation of magnetite and locally carbonate, (2) oxidation of magnetite to hematite (martitisation), further dissolution of quartz and formation of carbonate, (3) further martitisation, replacement of Fe silicates by hematite, new microplaty hematite and specular hematite formation and dissolution of carbonates, and (4) replacement of magnetite and any remaining carbonate by goethite and magnetite and formation of fibrous quartz and clay minerals.Hypogene alteration of BIF and surrounding country rocks is characterised by: (1) changes in the oxide mineralogy and textures, (2) development of distinct vertical and lateral distal, intermediate and proximal alteration zones defined by distinct oxide–silicate–carbonate assemblages, and (3) mass negative reactions such as de-silicification and de-carbonatisation, which significantly increase the porosity of high-grade iron ore, or lead to volume reduction by textural collapse or layer-compaction. Supergene alteration, up to depths of 200 m, is characterised by leaching of hypogene silica and carbonates, and dissolution precipitation of the iron oxyhydroxides.Carbonates in ore stages 2 and 3 are sourced from external fluids with respect to BIF. In the case of basin-related deposits, carbon is interpreted to be derived from deposits underlying carbonate sequences, whereas in the case of greenstone belt deposits carbonate is interpreted to be of magmatic origin. There is only limited mass balance analyses conducted, but those provide evidence for variable mobilization of Fe and depletion of SiO₂. In the high-grade ore zone a volume reduction of up to 25% is observed.Mass balance calculations for proximal alteration zones in mafic wall rocks relative to least altered examples at Beebyn display enrichment in LOI, F, MgO, Ni, Fe₂O_3total, C, Zn, Cr and P₂O₅ and depletions of CaO, S, K₂O, Rb, Ba, Sr and Na₂O. The Y/Ho and Sm/Yb ratios of mineralised BIF at Windarling and Koolyanobbing reflect distinct carbonate generations derived from substantial fluid–rock reactions between hydrothermal fluids and igneous country rocks, and a chemical carbonate-inheritance preserved in supergene goethite.Hypogene and supergene fluids are paramount for the formation of high-grade BIF-hosted iron ore because of the enormous amount of: (1) warm (100–200 °C) silica-undersaturated alkaline fluids necessary to dissolve quartz in BIF, (2) oxidized fluids that cause the oxidation of magnetite to hematite, (3) weakly acid (with moderate CO₂ content) to alkaline fluids that are necessary to form widespread metasomatic carbonate, (4) carbonate-undersaturated fluids that dissolve the diagenetic and metasomatic carbonates, and (5) oxidized fluids to form hematite species in the hypogene- and supergene-enriched zone and hydroxides in the supergene zone.Four discrete end-member models for Archean and Proterozoic hypogene and supergene-only BIF hosted iron ore are proposed: (1) granite–greenstone belt hosted, strike-slip fault zone controlled Carajás-type model, sourced by early magmatic (± metamorphic) fluids and ancient “warm” meteoric water; (2) sedimentary basin, normal fault zone controlled Hamersley-type model, sourced by early basinal (± evaporitic) brines and ancient “warm” meteoric water. A variation of the latter is the metamorphosed basin model, where BIF (ore) is significantly metamorphosed and deformed during distinct orogenic events (e.g., deposits in the Quadrilátero Ferrífero and Simandou Range). It is during the orogenic event that the upgrade of BIF to medium- and high-grade hypogene iron took place; (3) sedimentary basin hosted, early graben structure controlled Urucum-type model, where glaciomarine BIF and subsequent diagenesis to very low-grade metamorphism is responsible for variable gangue leaching and hematite mineralisation. All of these hypogene iron ore models do not preclude a stage of supergene modification, including iron hydroxide mineralisation, phosphorous, and additional gangue leaching during substantial weathering in ancient or Recent times; and (4) supergene enriched BIF Capanema-type model, which comprises goethitic iron ore deposits with no evidence for deep hypogene roots. A variation of this model is ancient supergene iron ores of the Sishen-type, where blocks of BIF slumped into underlying karstic carbonate units and subsequently experienced Fe upgrade during deep lateritic weathering.  相似文献   

贵州三都丰乐铁矿床地质特征及成因初探     

游家贵  宋普红  徐春生 《贵州地质》2011,28(3):211-214,226

贵州省三都县丰乐铁矿位于都匀以南,矿体呈层状、似层状产状,含矿岩系产于泥盆系大河口组,岩性为铁质砂岩、含铁砂岩、泥质砂岩等,脉石矿物主要为石英、白云石等,矿石品位较低,属贫铁酸性铁矿石。认为其属于＂宁乡式＂铁矿床,赤铁矿鲕粒以胶体化学方式沉积,成因类型系同生沉积成因。  相似文献   

湘西北宁乡式铁矿的成因与质量     

龚银杰  秦元奎  张鲲  胡俊良  刘阿睢 《化工矿产地质》2010,32(3):143-148

宁乡式铁矿在湘西北主要分布在三个层位,存在两类矿石结构,这两类矿石结构的铁矿是由不同的成矿方式形成,因而矿石质量也是不同的,具体表现在两类矿石中P、SiO2的含量存在明显差异。通过分析对比,Fe0、Fe22层砾状、豆状类赤铁矿的质量优于鲕状赤铁矿,其中位于二户溪至西界地区的FeO层砾状、豆状赤铁矿矿石质量全区最佳,应为该区的赤铁矿下一步工作的主要方向。  相似文献   

一个与超基性岩有关的矽卡岩铁矿          下载免费PDF全文

解广轟 《地质科学》1965,6(3):278-283

超基性岩同围岩接触,一般都很少见到明显的接触变质和接触交代现象,特別是后者更为少见。造成这一情况的原因可能有二:首先,超基性岩浆本身“活动组分”较少,如果沒有特殊有利的条件(包括岩体大小、侵入深度、接触面的形状产状、围岩成分以及构造条件等),这些组分不易集中,也就很难同围岩产生接触交代反应。  相似文献   

几内亚福雷卡里亚YML铁矿区的富铁矿床地质特征及找矿前景探讨          下载免费PDF全文

江胜国  李宏臣  付方建  王志刚  曹健 《地质找矿论丛》2018,33(1):142-148

YML铁矿区位于几内亚福雷卡里亚省,富铁矿以条带状赤铁矿和铁角砾岩矿为主。矿区内共发育7条矿体,条带状赤铁矿体6条,铁角砾岩矿体1条。条带状赤铁矿体赋存部位多为向形地段,次级紧密褶皱发育,沿走向和倾向有逐渐变薄和尖灭的趋势;铁角砾岩矿体覆盖于地表,以风化壳的形式出现。矿床类型属复合类型,即海底热液喷气沉积叠加后期构造变质型+风化淋滤型。该区具备铁矿形成和保存的地质条件,且已发现具一定储量、品位较高的条带状赤铁矿和大面积的铁角砾岩分布区,区内铁矿找矿远景较好。  相似文献   

High-grade iron ore at Windarling, Yilgarn Craton: a product of syn-orogenic deformation, hypogene hydrothermal alteration and supergene modification in an Archean BIF-basalt lithostratigraphy   总被引：2，自引：0，他引：2  

Thomas Angerer  Steffen G. Hagemann  Leonid Danyushevsky 《Mineralium Deposita》2013,48(6):697-728

Banded iron formation (BIF)-hosted iron ore deposits in the Windarling Range are located in the lower greenstone succession of the Marda–Diemals greenstone belt, Southern Cross domain, Yilgarn Craton and constitute a total hematite–martite–goethite ore resource of minimum 52 Mt at 60 wt.% Fe (0.07 P). Banded iron formation is interlayered with high-Mg basalts at Windarling and precipitated during episodes of volcanic quiescence. Trace element content and the rare earth element (REE) ratios Y/Ho (42 to 45), Sm/Yb (1.5), together with positive La and Gd anomalies in ‘least-altered’ hematite–magnetite–metachert–BIF indicate the precipitation from Archean seawater that was fertilised by hydrothermal vent fluids with a basaltic HREE-Y signature. Hypogene iron ore in sub-greenschist facies metamorphosed BIF formed during three distinct stages: ore stage 1 was a syn- to post-metamorphic, syn-D₁, Fe–Ca–Mg–Ni–Co–P–REE metasomatism that produced local Ni–REE-rich Fe–dolomite–magnetite alteration in BIF. Hydrothermal alteration was induced by hot fluid flow controlled by brittle–ductile reactivation of BIF-basalt margins and crosscutting D₁ faults. The Ni–Co-rich content of dolomite and a shift in REE ratios in carbonate-altered BIF towards Archean mafic rock signature (Y/Ho to 31 to 40, Sm/Yb to 1 to 2 and Gd/Gd* to 1.2 to 1.4) suggest that high-Mg basalts in the Windarling Range were the primary source of introduced metals. During ore stage 2, a syn-deformational and likely acidic and oxidised fluid flow along BIF-basalt margins and within D₁ faults leached carbonate and precipitated lepidoblastic and anhedral/granoblastic hematite. High-grade magnetite–hematite ore is formed during this stage. Ore stage 3 hydrothermal specular hematite (spcH)–Fe–dolomite–quartz alteration was controlled by a late-orogenic, brittle, compressional/transpressional stage (D₄; the regional-scale shear-zone-related D₃ is not preserved in Windarling). This minor event remobilised iron oxides, carbonate and quartz to form veins and breccia but did not generate significant volumes of iron ore. Ore stage 4 involved Mesozoic(?) to recent supergene oxidation and hydration in a weathering environment reaching down to depths of ～100 to maximum 200 m below surface. Supergene ore formation involved goethite replacement of dolomite and quartz as well as martitisation. Important ‘ground preparation’ for supergene modification and upgrade were mainly the formation of steep D₁ to D₄ structures, steep BIF/basalt margins and particularly the syn-D₁ to syn-D₂ carbonate alteration of BIF that is most susceptible to supergene dissolution. The Windarling deposits are structurally controlled, supergene-modified hydrothermal iron ore systems that share comparable physical, chemical and ore-forming characteristics to other iron ore deposits in the Yilgarn Craton (e.g. Koolyanobbing, Beebyn in the Weld Range, Mt. Gibson). However, the remarkable variety in pre-, syn- and post-deformational ore textures (relative to D₁ and D₂) has not been described elsewhere in the Yilgarn and are similar to the ore deposits in high-strain zones, such as of Brazil (Quadrilátero Ferrífero or Iron Quadrangle) and Nigeria. The overall similarity of alteration stages, i.e. the sequence of hydrothermal carbonate introduction and hypogene leaching, with other greenstone belt-hosted iron ore deposits supports the interpretation that syn-orogenic BIF alteration and upgrade was crucial in the formation of hypogene–supergene iron ore deposits in the Yilgarn Craton and possibly in other Archean/Paleoproterozoic greenstone belt settings worldwide.  相似文献   

滇西北衙多金属矿田矿床成因类型及其与富碱斑岩关系初探   总被引：16，自引：11，他引：5  

和文言  喻学惠  莫宣学  和中华  李勇  黄行凯  苏纲生 《岩石学报》2012,28(5):1401-1412

北衙金多金属矿田是与金沙江-哀牢山新生代富碱斑岩有关的成矿作用的典型代表之一,近年来在矿产勘查方面又有重大突破,金已达到超大型矿床,伴生铁、铜、银、铅、锌也达到了大-中型矿床规模。本文基于野外观察与室内研究,结合前人研究成果,对北衙多金属矿的成因类型,富碱斑岩与成矿作用的关系及成矿机制进行了系统总结,对与成矿相关的富碱斑岩进行了主量元素及锆石LA-ICP-MS的测试,探讨了铁矿的成因。研究表明,矿田原生金属矿床可分为:斑岩型铜金矿化,夕卡岩型铁、金、铜、铅、锌矿化,爆破角砾岩筒中的铁、金、铅、锌矿化以及热液型金、银、铅、锌矿化。其中夕卡岩型和热液型矿床是该区最主要的成矿类型。新生代富碱斑岩(石英正长斑岩)的年龄分别34.92±0.66Ma和36.24±0.63Ma。属于钾质碱性岩系列。它不仅为含矿流体的上升提供了动力和热能,而且还是成矿物质和成矿流体的主要来源,因此形成以斑岩体为中心,由斑岩型、夕卡岩型、热液型等矿床构成的一个连续的成矿系统。钾质碱性岩及矿床是在碰撞造山走滑构造系统深部壳幔相互作用的产物。本区岩体接触带中发育大量由菱铁矿和磁铁矿组成的铁矿体,其中大部分的磁铁矿是一种具有赤铁矿的板状晶或聚片双晶假象的穆磁铁矿。对磁铁矿和菱铁矿形成条件的分析表明,磁铁矿和菱铁矿主要是在碱性环境下交代含铁夕卡岩矿物形成的。当热液中H+的浓度降低时,赤铁矿被还原为磁铁矿,但仍保留了赤铁矿的晶形,于是成为穆磁铁矿。由此推测,本区成矿作用是在成矿流体及夕卡岩化交代作用长时间反复持续进行的条件下发生的,这可能是本区得以形成巨量金属堆积的重要原因之一。  相似文献