Composition and assemblage characteristics of magnetic minerals in layer S<Subscript>5-1</Subscript> of Xifeng and Duanjiapo sections

Relatively strongly magnetic fine components (< 30μm, XS-4J and DS-4J) which are most environmentally sensitive were separated from layer S_5-1 in the Xifeng and Duanjiapo loess sections and analyzed by MPV-3 for their morphometric characteristics and reflectance, SEM-ESD for their element contents and XRD for their mineral phases, respectively. The results showed that minerals in both samples are dominated by detrial Fe-Ti oxides of aeolian origin. In sample XS-4J the reflectance and iron contents of magnetic minerals are usually high. In addition to magnetite (Fe₃O₄), maghemite (γFe₂O₃) and hematite (Fe₂O₃), some Fe-high oxide (72.25 wt%–86.67 wt%), ilmenite (FeTiO₃), and magnetite-ulvöspinel [Fe(FeCr)O₄, Fe (FeNi)O₄] were also detected. In sample DS-4J obvious negative linear correlations were found between Ti and Fe, and the contents of Mn, Si, Al and Ca are usually high and the minerals are dominated by magnetite (maghemite), goethite (FeOOH) and limonite (containing Si and OH). In addition, the signs of corrosion of magnetic minerals and newly crystallized magnetite (maghemite) were recognized. Differences in the composition and assemblage characteristics of magnetite minerals between XS and DS reflect significant differences in source rocks and preserving conditions.     

Geochemistry of magnetite and maghemite in soils in European Russia

A method is proposed for determining the proportions of soluble Fe oxides (magnetite, FeOFe₂O₃, and maghemite, γ-Fe₂O₃) based on the measured magnetic susceptibility before and after treatment of soil with the Tamm or Mehra-Jackson (DCB) reagents. The development of hydromorphism in steppe soils in Ciscausiaia is associated with an increase in the magnetite fraction and, consequently, the average magnetite: maghemite ratio increases from 0.8–0.9 to 1.1. In these soils, smectites facilitate magnetite oxidation to maghemite. Soddy-podzolic and dark humic soils in the Cis-Ural region are noted for low values of the magnetite: maghemite ratio (0.5 on average) due to maghemite predominance. Soils in the Cis-Ural region on cover red-earth clays inherit lithogenic Fe oxides: hematite and maghemite. Hydromorphism in humid environments in northern taiga is accompanied by a significant increase in the magnetite: maghemite ratio to 4–9. Some issues of Fe geochemistry in magnetite and maghemite are considered.     

洛川黄土-红粘土序列铁氧化物组成及其古气候指示

对洛川黄土、古土壤和红粘土中磁性矿物组成、成因和相关系进行了研究。结果表明:黄土磁性矿物以风尘磁铁矿为主,少量的成土赤铁矿和成土磁赤铁矿;古土壤磁性矿物以成土磁赤铁矿为主,成土赤铁矿次之,少量的风尘磁铁矿和赤铁矿;红粘土磁性矿物以成土赤铁矿为主,风尘磁铁矿和成土磁赤铁矿次之,少量风尘赤铁矿。黄土、古土壤和红粘土磁性矿物组成差异,反映了其形成期不同的古气候特性以及不同气候条件下生物地球化学作用强度的差异。干冷的冰期,黄土弱成土作用形成了以粗颗粒的风尘磁铁矿核 赤铁矿边的磁化率载体。间冰期的温暖湿润的古气候最有利于生物活动,强烈生物活动导致古土壤中大量纳米超细磁赤铁矿/磁铁矿产生,形成以磁赤铁矿为主,风尘磁铁矿核 赤铁矿边为辅的磁化率载体。红粘土成壤期,强降雨强蒸发的长干短湿的高温炎热的古气候使得红粘土化学风化强烈,生物地球化学活动较弱,形成以磁铁矿核 赤铁矿边和磁赤铁矿核 赤铁矿边的磁化率载体。黄土、古土壤和红粘土磁性矿物组成、磁性矿物相关系是其形成期独特的古气候指示。     

Evidence for a simple pathway to maghemite in Earth and Mars soils

Soil magnetism is greatly influenced by maghemite (γ-Fe₂O₃), the presence of which is usually attributed to the following: (1) heating of goethite in the presence of organic matter; (2) oxidation of magnetite (Fe₃O₄); or (3) dehydroxylation of lepidocrocite (γ-FeOOH). Formation of the latter two minerals in turn requires the presence of Fe(II) in the system. No laboratory experiment or soil study to date has shown whether maghemite can form from ferrihydrite, a poorly crystalline Fe(III) oxide [∼Fe_4.5(O,OH,H₂O)_13.5], below 250°C. However, ferrihydrite is the usual precursor of goethite (α-FeOOH) and hematite (α-Fe₂O₃), the most frequently occurring crystalline Fe(III) oxides in soils. Here is presented in vitro evidence that ferryhidrite can partly transform into maghemite at 150°C. This transformation occurs upon aging of ferrihydrite precipitated in the presence of phosphate or other ligands capable of ligand exchange with Fe-OH surface groups. This maghemite coexists with hematite and is a transient phase in the transformation of ferrihydrite to hematite, which is apparently stabilized by the adsorbed ligands. Its particle size is small (10 to 30 nm), and its X-ray diffraction pattern exhibits superstructure reflections. The possible formation of maghemite in Mars and in different Earth soils can partly be explained in the light of this pathway with minimal ad hoc assumptions.     

安徽凤阳石英岩的铁含量与磁化率的关系

利用电子探针检测安徽凤阳石英岩中的含铁矿物,测量由相同矿区的石英岩加工而成的不同粒度石英砂的Fe2O3质量分数(w(Fe2O3))与磁化率。结果表明:石英岩中有磁铁矿、黄铁矿、黑云母与白云母等多种含铁矿物。这些含铁矿物主要充填在石英颗粒孔隙中,粒度大多小于0.1 mm。而石英砂中的w(Fe2O3)普遍很低(小于0.1%),其磁化率主要受磁铁矿控制。并且不同粒度的石英砂中w(Fe2O3)与磁化率存在较大差异,当石英砂中的w(Fe2O3)大于0.01%时,由Fe2+、Fe3+磁性离子含量决定磁化率大小,两者存在强正相关关系。这也反映出了石英岩的铁含量与磁化率之间的关系。因此,磁化率可作为石英岩铁含量的替代性指标。     

辽宁弓长岭铁矿二矿区条带状铁建造地球化学特征及成因探讨

本文以弓长岭铁矿二矿区磁铁石英岩、磁铁富矿和蚀变围岩样品为研究对象,进行了主量元素、微量元素、稀土元素和Fe同位素的测试。结果表明:磁铁石英岩主要由TFe2O3和SiO2组成,Al2O3和TiO2质量分数较低,微量元素质量分数和稀土元素质量分数均较低;经澳大利亚后太古界平均页岩(PAAS)标准化的稀土配分模式呈现出轻稀土亏损和重稀土富集,La、Eu和Y的正异常明显,Ce的异常不明显,Y/Ho值较高;富集Fe的重同位素,且与海底喷发热液经过氧化沉淀后的Fe同位素特征一致。磁铁富矿与磁铁石英岩的地球化学特征有很好的一致性和继承性,但磁铁富矿的REE和Eu质量分数较高,且较磁铁石英岩富集Fe的轻同位素,范围更大,与蚀变岩的Fe同位素组成相近。弓长岭铁矿的磁铁石英岩是陆源物质加入很少的古海洋化学沉积岩,为喷出的海底热液与海水的混合条件下氧化沉淀形成的。磁铁富矿推测为富Fe的轻同位素热液对磁铁石英岩进行改造,经过去硅富铁作用形成的。     

西昆仑山黄土的岩石磁学特征及其磁化率增强机制

成壤过程中形成的细颗粒的软磁性矿物被认为是导致古土壤磁化率增加的主要原因。但近来的研究表明,在一些地区,尤其是靠近沙漠边缘的黄土-古土壤序列,源区对黄土磁化率的影响要远大于成壤作用。因此,有必要对不同地区、不同环境条件下的典型黄土堆积进行详细的岩石磁学研究。日前,我们在西昆仑山北侧钻取了一根长达671m的岩芯,这为研究极端干旱区黄土的岩石磁学性质提供了难得的契机。本文对第一期黄土钻探得到的207m岩芯进行了详细的岩石磁学研究,结果表明: 昆仑山黄土的主要载磁矿物为磁铁矿和磁赤铁矿,同时还含有少量的针铁矿、赤铁矿;  该地区磁化率的变化主要受源区粗颗粒的软磁性矿物含量的影响,成壤作用形成的细颗粒磁性矿物对磁化率的贡献极小;  磁化率、粒度在0.5Ma左右急剧升高和变粗,主要与气候干旱化加剧有关。     

磷灰石对湖泊沉积物中水铁矿稳定性的制约

通过在滇池开展原位实验,研究探讨了湖泊沉积物中磷灰石制约水铁矿分解和转化的机制,以及二者共存时的环境效应。结果表明:将水铁矿放置到沉积物中1个月,矿物保持稳定;放置时间达到3个月时,添加磷灰石实验中水铁矿发生了显著物相转变。冬天(12—2月)实验中,转化产物随深度的变化趋势为针铁矿+磁(赤)铁矿→针铁矿+纤铁矿→针铁矿;夏天(6—9月)实验中,转化产物随深度的变化趋势为针铁矿+纤铁矿+磁(赤)铁矿→针铁矿+纤铁矿→未转化。透射电镜分析结果显示冬天实验中生成的磁性铁氧化物为纳米磁铁矿和磁赤铁矿,夏天实验中产生的则主要为纳米磁铁矿。X射线光电子能谱分析结果显示冬天表层实验样品具有较高P含量。分析表明的湖泊沉积物中磷灰石促进水铁矿转化的过程为:(1)微生物促进磷灰石溶解;(2)磷灰石溶解释放的P促进铁还原菌生长;(3)铁还原菌促进水铁矿还原;(4)水铁矿还原产生的溶解态Fe²⁺催化水铁矿向针铁矿、纤铁矿和磁铁矿转化。冬天及沉积氧化-还原界面最适宜磷灰石分解菌和铁还原菌生长,水铁矿的转化和P释放能力也更强,相应地内源磷释放的风险也更大。     

马兰黄土和离石黄土的磁学性质

中国黄土-古土壤系列的磁学性质,如磁化率等被广泛用于古气候和古环境研究,这必须建立在对黄土-古土壤的剩磁的性质和获得剩磁的机制以及古土壤磁性增强的原因有深入了解的基础之上。作者通过对洛川和吉县剖面马兰黄土和离石黄土的磁学性质的深入研究,对黄土与古土壤磁学性质差异的各种表现,对它们剩磁的性质,对古土壤磁性增强的原因以及磁性变化对古气候、古环境研究的意义进行了讨论,并对利用某些磁学性质建立的黄土-古土壤形成的时间模式提出了质疑。     

钛磁铁矿的制备及其异相Fenton反应催化性能

在水相中合成了钛磁铁矿（Fe3-xTixO4）,并用XRD、MSssbauer、TG-DSC和SEM等手段对合成的Fe3-xTixO4进行了表征。结果表明,合成的Fe3-xTixO4为立方晶系尖晶石结构,样品中的钛离子都已经进入其晶格中;钛掺杂有抑制钛磁铁矿进一步向钛磁赤铁矿转化和稳定尖晶石结构的作用。此外,以亚甲基蓝降解为探针反应,考察了钛磁铁矿异相Fenton反应的催化性能。实验表明,钛含量较高的钛磁铁矿是一种性能优越的异相Fenton反应催化剂。     

铁矿石物相分析标准物质的研制

介绍了研制铁矿石物相分析标准物质的研制工艺及技术关键，列出了磁性铁中铁、碳酸铁中铁、赤（褐）铁矿中铁、硫化铁中铁、硅酸铁中铁和全铁的原始数据和定值数据。所研制的６个标准物质已于１９９５年被国家技术监督局批准为一级标准物质，编号为ＧＢＷ０７２７１～０７２７６。     

东太平洋海盆内多金属结核中的铁矿物

东太平洋海盆内多金属结核中的铁矿物萧绪琦郭立鹤（中国地质科学院矿床地质研究所，北京１０００３７）１前言早在五十年代人们就已注意到，大洋多金属结核含铁量较高，由于结核中矿物颗粒细小，结晶程度低，使得铁矿物的确定很困难，通常称之为铁的氧化物和氢氧化物。在...     

星叶石族矿物的晶体化学

星叶石是碱性岩中分布较广泛的副矿物,成分富含碱金属K、Na及Ti,随其产出的地球化学条件,类质同象代换情况较复杂,形成许多成分异种。本工作之前对其组成和性质都不十分清楚,前人虽进行了一般矿物学研究,但未能确定所属晶系,B.C.索波列夫曾推断星叶石中Ti呈四面体配位,并与硅氧四面体组成复杂构造。     

川西高原理县黄土磁学特征及其影响因素

川西高原河谷阶地和断陷盆地广泛分布厚层风成黄土-古土壤序列,目前对其磁学性质变化机制及古气候意义研究还很薄弱。文章对该区理县黄土-古土壤剖面进行了系统的岩石磁学研究,确定了其磁性矿物种类、含量和颗粒大小的特征及其变化规律。通过结合粒度、色度与地球化学参数,进一步探讨了理县黄土-古土壤磁性的主控因素。结果表明:1)理县剖面同时含有强磁性矿物(为磁铁矿和磁赤铁矿)以及弱磁性矿物(为赤铁矿和针铁矿);2)相对黄土层,古土壤层含有更高比例的亚铁磁性矿物;3)成土过程中生成的大量细小强磁性矿物颗粒,是古土壤层S1磁化率增加的主导因素,该模式与黄土高原相似;4)结合色度以及磁学性质,可以较为明确地区分成壤强度;(5)理县黄土剖面物源复杂,磁学特征受到沉积物来源、后期流水和气候的共同作用,利用单一磁学性质(比如磁化率)进行古气候研究会造成多解性。     

硫酸盐对磁赤铁矿—磁铁矿厌氧转化过程的影响

磁赤铁矿可以在厌氧微生物作用下固相转化为磁铁矿，这种转化过程具有重要的矿物学及环境磁学意义。文章通过开展硫酸盐还原菌（SRB） —磁赤铁矿交互作用实验，重点探讨了SRB 活性对磁赤铁矿—磁铁矿固相转化速率的影响。在31 d 培养期内，SO₄^2-+SRB+磁赤铁矿体系中SRB 的生长导致16.7%的SO₄^2-转化为酸可挥发性硫（AVS），部分还原释放的Fe（II） 与AVS 反应生成单硫化物、双硫化物和多硫化物，同时铁氧化物因溶解作用粒径减小；在无SO₄^2-的SRB+磁赤铁矿体系中， SRB 还原产生的Fe （II） 主要存在于铁氧化物中，没有次生沉淀产生。X 射线衍射和穆斯堡尔谱分析结果表明在SRB 作用下纳米磁赤铁矿逐渐向磁铁矿转化，加入SO₄^2-时转化速率加快，与矿物接触的SRB 菌体的数量及其向磁赤铁矿传递电子的能力均得到了增强。在天然或人工厌氧条件下，SO₄^2-是制约磁赤铁矿向磁铁矿转化的重要因素。     

Magnetic properties of the Bled El Hadba phosphate-bearing formation (Djebel Onk,Algeria): Consequences of the enrichment of the phosphate ore deposit

To improve the enrichment of the Thanetian marine phosphate ore deposit from the quarry of Bled El Hadba (Djebel Onk, Algeria) before its exploitation, we first conducted a joint study using different techniques for comparison. These studies reveal that magnetic minerals play a significant role within the matrix of the central productive unit which is squeezed between two other units. Magnetic separation procedures show that there are some positive correlations between magnetic susceptibility and grain size fraction (80–250 μm). These dolomite-rich fractions are more clearly separated. Different tools were used to characterize the magnetic minerals (X-ray, microprobe, differential scanning calorimetry, thermogravimetric and thermomagnetic analyses). They show correlations between magnetic phases and the presence of associated magnetic minerals within the matrix or included in the phosphate ore deposit. They enabled us to distinguish a series of magnetic minerals (magnetite, hematite, maghemite, goethite, ilmenite, pyrite, iron–titanium oxide and titanium oxide sulphate) and to determine that Fe and Ti are prevalent in the separated fractions, following the same variation as Mg. The phosphorous (phosphate) rate is higher in the non-magnetic material, especially in the layers that are rich in dolomitic carbonates (upper and lower units), which could be trapped within the dolomitic matrix, while Magnesium (dolomite) is more important in the magnetic fraction. The separation of phosphate elements and dolomite carbonates is effective and therefore the ore can be enriched through magnetic procedures. Comparison between products enriched by magnetic separation, flotation and calcination showed important differences, chemically, economically and technically speaking.     

Rock Magnetism Study on Loess-Paleosol Sequence at Huixinggou Section of Sanmenxia Basin

Rock magnetism is the foundation of paleomagnetism and environmental magnetism study, and is effective in identifying the components, grain size and content of magnetic minerals in rocks and sediments. A systematic rock magnetism investigation has been conducted on the Huixinggou loess-paleosol sequence at Shuigou-Huixinggou Paleolithic site of Sanmenxia Basin in the southeastern Loess Plateau. Results show that the magnetic assemblage of the section is dominated by magnetite and maghemite, as well as hematite, exhibiting the average grain size of magnetic minerals is attributed to Pseudo-Single Domain (PSD). The variation curves of magnetic parameters are consistent and well comparable to marine oxygen isotope curves, with low values corresponding to the loess deposition during glacial periods, and high values corresponding to the paleosol development during interglacial periods, jointly demonstrating the glacial-interglacial cyclicities of magnetic mineral types, composition, and grain size of Chinese loess-paleosol sequences under the influence of alternating strengthening and weakening of Eastern Asian paleomonsoon over the Quaternary period. Comprehensive analysis reveals that the relative content of high-coercivity antiferromagnetic minerals is higher in loess than in paleosol, whilst the absolute content of high-coercivity antiferromagnetic minerals in paleosol is generally higher than that in loess accompanying increasing intensity of pedogenesis. The mass-specific magnetic susceptibility (χ) shows distinctly positive correlations with anhysteretic susceptibility (χ_ARM), Saturation Isothermal Remanent Magnetization (SIRM) and magnetic grain size dependent parameters (χ_ARM/SIRM and χ_ARM/χ), indicating that the pedogenic producing Single Domain (SD) and small PSD ferrimagnetic particles contribute significantly to the magnetic susceptibility enhancement.     

钻孔岩心磁化率及PXRF 测量在智利 月亮山铁铜矿区应用与找矿预测

[摘 要]以智利月亮山铁氧化物铜金型矿床为例,利用磁化率K 对铁磁性矿物及蚀变岩的现场识别能力和X 射线荧光分析仪(PXRF)快速分析元素含量功能,结合矿床地质以闪长岩(5.5×10^-3SI< K <17.9×10-3 SI)、角砾岩(0.35×10^-3SI< K <0.7×10^-3SI)、磁铁矿(K>753. 4×10^-3SI)、磁赤铁矿(313.3×10^-3SI < K <753.4×10^-3SI)、赤铁矿(0.78×10^-3SI< K <1.62×10^-3SI)、镜铁矿(0.67×10^-3SI< K <0.78×10^-3SI)等划分闪长岩亚相、角砾岩亚相、磁铁矿微相、磁赤铁矿微相、赤铁矿微相、镜铁矿微相;以PXRF现场测量铁含量>30%,铜含量>0.5%为含矿(化)界限,确定磁化率-铁铜含量对应关系:高磁化率-高铁含量-磁铁矿型、低磁化率-高铁含量-赤铁矿型(镜铁矿)、低磁化率-低铁含量-蚀变岩型,及岩相学找矿标志-矿物标志、构造标志、闪长岩标志、蚀变分带标志和矿物蚀变标志等,对月亮山矿区进行深部找矿预测。     

磁铁矿显微结构及化学成分对铜绿山矽卡岩型铜铁矿床成矿过程的指示

铜绿山矽卡岩型铜铁多金属矿床是长江中下游鄂东南矿集区的一个典型矿床，矿体产于铜绿山岩体与三叠系碳酸盐岩地层的接触带.磁铁矿是铜绿山铜铁矿床中广泛发育的矿石矿物，选取内矽卡岩和外矽卡岩中的热液磁铁矿以及岩体中副矿物磁铁矿为研究对象，对其开展系统的显微结构观察和电子探针分析.热液磁铁矿中普遍发育有钛尖晶石出溶结构和富硅环带结构，且没有明显的后期热液交代改造现象.钛尖晶石出溶结构指示铜绿山矿床的早期热液磁铁矿具有较高的Ti含量，磁铁矿结晶后经历了降温和氧逸度降低过程导致钛尖晶石出溶.热液磁铁矿中还普遍含有较高含量的Si、Al、Cr、V、Mn、Mg、Co和Ni等元素，Si4+、Al3+、Mg2+、Mn2+等以类质同象方式进入磁铁矿晶格；但在不同产状的磁铁矿中，替代强度和机制略有不同，说明流体成分、温度、压力等物理化学条件影响元素替代强度和方式.外矽卡岩中磁铁矿的Al₂O₃/MgO比值小于4，内矽卡岩中磁铁矿的Al₂O₃/MgO比值为5~8，而副矿物磁铁矿的Al₂O₃/MgO比值约为13.岩体副矿物磁铁矿具有最高的V₂O₃含量（平均值为0.31%），与岩体接触的内矽卡岩中的磁铁矿次之（平均值为0.14%），外矽卡岩中磁铁矿的V₂O₃含量最低（平均值为0.01%~0.03%）.Al₂O₃/MgO比值和V₂O₃含量说明磁铁矿生长环境（熔体/热液）、围岩的成分及水-岩反应等对磁铁矿的化学组成均有影响.铜绿山矿床从岩体到内矽卡岩、再到外矽卡岩，磁铁矿的形成温度逐步下降，其成分的变化指示了磁铁矿可以作为矽卡岩矿床成矿过程的重要指示矿物.      

镇江下蜀土的岩石磁学特征及磁化率变化机制

对镇江59.4m厚的下蜀土剖面的磁化率、χ-T曲线、等温剩磁获得曲线和磁滞回线等岩石磁学性质进行了研究,结 果表明：1）全剖面磁化率变幅较大,变化于（6.4~186.3）×10-8m3·kg-1之间;其中,剖面下段（24~59.4m）平均值为 34.7×10-8m3·kg-1,远低于上段（0~24m）的平均值126.1×10-8m3·kg-1;2）代表性样品的岩石磁学特征大致可以分为两类： 一类具有较高的磁化率,χ-T曲线呈明显的磁铁矿的居里点特征,IRM获得曲线在300mT时接近饱和,反向场退磁曲线显 示具有较低的剩磁矫顽力（25~40mT）,磁滞回线表现出细高的形状,在600~800mT之间闭合,显示含有较多的亚铁磁性 矿物（如磁铁矿和磁赤铁矿）;另一类样品则具有较低的磁化率,χ-T曲线初始磁化率较低,IRM获得曲线在300mT时达到 饱和剩磁的69%~82%,具有较高的剩磁矫顽力（70~135mT）,磁滞回线呈蜂腰状,提示含有较少的亚铁磁性矿物和较多的 高矫顽力矿物（如赤铁矿和针铁矿）,且可能含有铁的硫化物;3）岩石磁学特征表明下蜀土堆积的不同时段可能受到不同 环境的控制,中更新世中期之前曾出现多期过度湿润的气候条件,导致成土环境偏向还原条件,磁铁矿和磁赤铁矿逐渐转 化为弱磁性矿物,使得磁化率异常降低,与西伯利亚黄土变化模式类似;中更新世中晚期以来则以较干燥的氧化环境为 主,主要受成壤作用控制,有利于细小磁铁矿和磁赤铁矿的生成,与中国黄土高原的成土模式相似。