磁铁矿中磁性物成分的测定及可选性评价   总被引：3，自引：3，他引：0  

班俊生  任金鑫  刘桂珍  臧苗苗  杨莹雪  王烨 《岩矿测试》2013,32(3):469-473

对磁铁矿样品分别用磁选管和手工内磁选法进行磁选,并对原矿样品和样品的磁性物中TFe、P、S、V2O5、TiO2、SiO2、Al2O3、CaO、MgO、Sn、Cu、Pb、Zn的含量进行测定.分析结果表明,采用手工内磁选和磁选管对磁铁矿进行磁选所得的结果一致,为了简便操作,本文均采用手工内磁选法选出磁性物.A矿区磁性铁(mFe)含量(22.42％)比B矿区mFe含量(22.59％)低,但A矿区样品的磁性物中TFe含量(磁铁精矿品位)大于66％,比B矿区样品的磁性物中TFe含量(小于57％)高,A矿区的磁铁矿选矿效果明显好于B矿区,说明对磁性物中TFe含量的测定能够更好地反映矿石的可选性.原矿样品中P、S的含量分别为0.328％、0.271％,而样品的磁性物中P、S的含量为0.021％、＜0.005％,均达到铁矿石冶炼标准;原矿样品中V2O5、TiO2的含量分别为0.156％、1.37％,而样品的磁性物中V2O5、TiO2含量分别为0.823％、13.62％,达到了铁矿石冶炼标准.原矿样品的(CaO+MgO)/(SiO2 +Al2O3)值为0.876,为自熔性矿石,而其磁性物的(CaO+ MgO)/(SiO2+Al2O3)值为0.453,为酸性矿石.由此说明,单纯测定原矿样品中的各成分尚不能对磁铁矿的可选性进行科学性评价,只有进一步测定磁铁矿的磁性物中各成分的含量,才能够对磁铁矿进行可靠的评价.本文通过对磁铁矿中磁性物成分的测定,为磁铁矿的选冶性能提供了新的评价方法.  相似文献   

新型磁选装置的研制及其应用于分离超贫磁铁矿中的磁性铁   总被引：1，自引：1，他引：0  

黄瑞成  肖洁  魏灵巧  罗磊  付胜波 《岩矿测试》2015,34(2):213-217

磁性铁是超贫磁铁矿勘查中的基本分析项目之一,为准确测定磁性铁的含量,首先需要实现磁性铁的定量分离。目前常用的手工内磁选法由于所用磁铁的有效磁场强度难以保证,而且受人为操作的影响较大,导致分析结果的重现性差。本文应用50 m L滴定管、电磁铁和三相异步电动机,研制了一种新型磁选装置——电磁式磁性铁分选装置,实现了超贫磁铁矿中磁性铁与非磁性铁的定量分离,结合重铬酸钾容量法建立了超贫磁铁矿中磁性铁的分析方法。在选定的磁选条件下(电流2.5 A,磁选管运动频率40 r/min,磁选时间5 min)分析铁矿石标准物质,磁性铁的测定值与标准值的相对误差小于1.0%;分析采自实际矿区的超贫磁铁矿样品,磁性铁的测定结果与手工内磁选法一致,且相对标准偏差(RSD,n=5)小于1.0%,优于手工内磁选法的精密度。本方法采用的电磁式磁性铁分选装置有效地控制了磁场强度的强弱,避免永磁铁出现磁损失,同时可以量化磁性铁分离的参数,提高了磁性铁的分析精度。  相似文献   

秦王山基性岩型含稀土、钴、磷磁铁矿体特征及找矿思路     

李六权 《陕西地质》2018,(1)

对老资料再研究,发现商丹对接带中的秦王山基性岩体含磷、稀土、钴等有益组分并可回收。矿石可选性好,选矿试验结果:铁精矿品位TFe 60.10%,回收率52.65%;磷精矿P_2O_5品位37.86%,回收率86.96%。稀土赋存于磷灰石中,钴赋存于含钴黄铁矿中。在地表圈出3个矿化地段,23个含磷钴稀土磁铁矿体。按超贫磁铁矿工业指标,估算地下400m以上,铁(磷)矿石资源量4.24亿吨,REO资源量为4.7万吨,Co资源量6.10万吨。  相似文献   

某镍矿渣中磁铁矿工艺矿物学及磁选试验研究     

《矿物岩石》2017,(3)

某冶炼镍矿渣中全铁品位为37.82%,为了研究该镍渣中铁矿物综合回收的可能性,在对镍渣进行粒度组成分析、化学全分析、矿物组成分析及铁物相分析的基础之上进行了不同细度和不同磁场强度下的弱磁选实验,研究发现,镍矿渣中的铁主要赋存在+200目以上的粒级中,该粒级中铁分布率为84.74%。镍矿渣中主要金属矿物为磁铁矿和铁镁氧化物类矿物,其含量分别为11.07%和2.09%,杂质矿物铁(镁)橄榄石的含量高达86.58%;镍矿渣中磁性铁含量为36.09%,其占有率为95.43%,将镍矿渣磨矿至-325目97.86%,在不同的磁场强度下进行弱磁选,选矿指标仍不理想,原矿、精矿、尾矿铁品位比较接近,分布在36%~38.5%,通过弱磁选无法对磁铁矿进行有效回收;对镍矿渣进行的MLA磁铁矿嵌布粒度分析结果表明,镍矿渣颗粒中的磁铁矿大多以薄壳的形式存在于镍矿渣颗粒边缘,薄壳厚度大多在10μm以下,通过常规磨矿的方式难以使其从脉石矿物铁(镁)橄榄石及其他伴生杂质矿物中解离出来,磁铁矿解离度达不到分选要求,因此无法采用弱磁选的方式对其进行有效回收,镍矿渣中的磁铁矿无法分离生产铁精粉,建议整体利用,用来生产建筑微晶玻璃、建筑砌块或水泥铁质校正原料。  相似文献   

应注意找低钛基性岩型铁矿          下载免费PDF全文

汪国栋 《地质与勘探》1988,(11)

我国富铁矿很少,需大量利用“易采、易选、好用”的贫磁铁矿。我国南、北方均有大规模基性超基性岩分布,有的岩带找到了大量的岩浆晚期分异型钒钛磁铁矿床,但均属高Ti类型(TiO_2>12％),不适于普通高炉冶炼。在我国某些基性、超基性岩带上,曾找到过一些含Ti较低的辉长岩型(或辉石岩型)钒钛磁铁矿。如中西部某岩带的辉长岩型铁矿,一般TFe22～  相似文献   

超贫微细粒难选磁铁矿的磁选试验研究   总被引：1，自引：0，他引：1  

吴蓬  吕宪俊  邱俊 《矿物岩石》2015,35(1)

针对某难选磁铁矿在系统研究其矿石性质的基础上,采用单一磁选的工艺进行分选试验,结果表明,该矿石为超贫微细粒磁铁矿矿石,全铁品位为26.19%,磁性铁含量为18.18%;矿石中嵌布粒度在30μm以下的磁铁矿含量约占23%,10μm以下的磁铁矿含量约占5%;采用湿式预选-三段磨矿三段选别的单一磁选流程,控制最终磨矿细度为-400目97.40%,可以分选出品位为65.05%的铁精矿,其产率为28.06%,回收率为69.70%的铁精矿,从而为这类铁矿石的选别提供技术支持。  相似文献   

承德市超贫（钒钛）磁铁矿特征   总被引：4，自引：0，他引：4  

谢承祥  张晓华  王少波  肖克炎  李厚民 《矿床地质》2006,25(Z3):487-490

超贫磁铁矿，是一个全新的概念，即达不到现行铁矿地质勘查规范边界品位要求，在当前技术经济条件下可以进行开发利用的含铁岩石的统称。承德市超贫（钒钛）磁铁矿，成矿母岩为超基性岩体和基性岩体。矿石品位一般为TFe l4%~18%，mFe 6%~12%。该类型超贫磁铁矿床一般规模均较大，延长可达数公里至数十公里，宽可达几百米，多为大中型矿床，具有品位相对稳定的特点。矿石以半自形粗粒结构，海绵陨铁结构为主。经调查全市超贫磁铁矿资源储量为45.37亿吨，其中普查、详查和勘探的资源储量约6亿吨。  相似文献   

烧锅营子金矿黄铁矿的化学成分标型特征     

黄菲  王建国  郑超  赵纯福  马民涛  郝辉 《地质与资源》1997,6(2):132-139

烧锅营子金矿床的黄铁矿形成于早、中、晚3期,是主要的矿石矿物和载金矿物,其中以中期黄铁矿为最主要的载金者.黄铁矿的化学成分为:TFe43.34%~45.52%,S46.58%~48.86%,与标准黄铁矿相比显示亏铁、亏硫特点.黄铁矿内含丰富的微量元素,有Au、Ag、As、Sb、Bi、Cu、Zn、Pb、Co、Ni、W、Mo、Se等.其中Au、Ag、Cu、Pb、Zn、Bi含量较高,而As、Sb低,Se极低.其Au/Ag(多大于0.5)、(Cu+Pb+Zn)/(Co+Ni+As)(4.26)、Co/Ni(>> 1)比值表明其属中温岩浆热液矿床.  相似文献   

基于形态学分析铅锌矿不同功能区土壤重金属元素的分布特征及污染评价   总被引：1，自引：1，他引：0  

郭世鸿  侯晓龙  邱海源  刘爱琴  马祥庆  王友生 《地质通报》2015,34(11):2047-2053

为掌握尤溪铅锌矿区土壤重金属元素分布特征和污染现状,通过采集尤溪铅锌矿不同功能区0~20cm表层土壤样品,测定土壤中Pb、Zn、Cd、Cu、Cr 5种重金属元素的总量及其化学形态,分析不同功能区土壤重金属污染及分布特征,同时采用次生相与原生相比值法(RSP)进行污染评价。结果表明,尤溪铅锌矿不同功能区土壤中Pb、Zn、Cd含量均超过国家土壤环境质量三级标准,废弃冶炼区土壤Cd、Cu、Pb、Zn含量均最高,分别为标准值的14.78、1.13、3.73、1.34倍,采矿区Cr含量最高,但未超过标准限值。重金属形态结果表明,相比其他元素,Cd弱酸提取态所占比例最高,Cu可交换态比例最高,Pb、Zn、Cr以残渣态为主。RSP法评价表明,不同重金属的污染程度表现为:Cu(1.15)Cd(0.80)Pb(0.59)Zn(0.57)Cr(0.54);不同功能区土壤重金属污染表现为:尾矿库区冶炼区废弃冶炼区采矿区。SPEF法评价表明,尤溪铅锌矿区受人为污染明显,采矿区和尾矿库区Zn污染最为严重,冶炼区和废弃冶炼区Pb污染最为严重,功能区污染顺序为:尾矿库区冶炼区废弃冶炼区采矿区。  相似文献   

大洋多金属结核成因的地球化学标志   总被引：2，自引：0，他引：2  

梁宏锋  姚德 《地质科技情报》1991,10(1):55-58

本文通过对取自太平洋不同地区的近百个多金属结核样品研究表明,不同成矿介质中形成的结核,地球化学特征明显不同,水成型结核矿物成分上富含σ—MnO_2,化学成分上富含Fe、Co、Pb,而贫Mn、Cu、Ni、Zn,TiO_2>1%,ΣREE>1000ppm,σCe>1.5;早期成岩型结核矿物成分上相对富含钡镁锰矿,化学成分上富含Mn、Cu、Ni、Zn,而贫Fe、Co、Pb,TiO_2<1%,ΣREE<1000ppm,σCe≤1.在此基础上通过对Bonatti图解的实际应用和理论分析,证明Mn-Fe-(Cu+Co+Ni)x10图解不具判别意义,并提出Mn/Fe-TiO_2,Mn-Fe-TiO_2×10,Mn-Fe-ΣREE×100和Mn-Fe-σCe×10成因判别图解.  相似文献   

西天山敦德铁矿床磁铁矿原位LA-ICP-MS元素分析及意义   总被引：5，自引：3，他引：2  

段士刚  董满华  张作衡  蒋宗胜  李凤鸣 《矿床地质》2014,33(6):1325-1337

敦德铁矿床是天山成矿带内新近发现并勘查的一处大型海相火山岩型铁矿床。该矿床的矿石可划分为浸染状、稠密浸染状、条带状和块状4种主要类型。其中的条带状矿石包括磁铁矿_矽卡岩条带和磁铁矿_方解石条带2种亚类型。块状矿石内出现围岩或矽卡岩角砾时则构成角砾状矿石,其磁铁矿的成因无甚差异。根据野外观察和矿相显微研究,认为磁铁矿形成于早期矽卡岩阶段后的退化蚀变阶段,之后又被更晚的硫化物阶段和绿泥石_碳酸盐阶段的矿物叠加。敦德磁铁矿内主要发生了Al、Mn、Mg和Zn的类质同象置换,此外,也含有Ti、Si、Ca等次要元素以及Na、K、V、Cr、Ni、Co等多种可检测到的微量元素。磁铁矿内元素含量在空间上显示出直观的差异,由深部到浅部,Mn、Zn含量升高,Si、Ca、Na、K、Pb、Ba、Sr、Sb、Cu等含量降低。在Ti O2_Al2O3_Mg O图解、Ti O2_Al2O3_(Mg O+Mn O)图解和Ca+Al+Mn_Ti+V图解上,敦德磁铁矿的分析数据均投影于热液交代(矽卡岩)成因区域。综上认为,该矿床的磁铁矿可能为热液充填交代成因。  相似文献   

Soil metal pollution from former Zn–Pb mining assessed by geochemical and magnetic investigations: case study of the Bou Caid area (Tissemsilt,Algeria)     

Lynda Attoucheik  Neli Jordanova  Boualem Bayou  France Lagroix  Diana Jordanova  Said Maouche  Bernard Henry  Abdelhak Boutaleb 《Environmental Earth Sciences》2017,76(7):298

Former zinc and lead mines that have been operating for half a century are located in the massif of Bou Caid (Tissemsilt, Algeria). Hazardous heavy metals emitted from the mines are abundant in the surrounding soil and cause strong metal pollution in the region. This paper investigates the extent of lead and zinc mine activity derived pollution by characterizing both magnetic and geochemical properties of samples collected in the vicinity of the mines. The results of the magnetic study show the coexistence of magnetic minerals such as magnetite, hematite and goethite. Analyses on surface soils and weathered rocks suggest that hematite and goethite have ore-related lithogenic origins. Magnetic susceptibility shows a positive correlation with lead content when present in low-to-medium concentrations (< ~500 mg/kg). At higher lead concentrations, there is no correlation with magnetic susceptibility. The relationship between magnetic susceptibility and zinc content is not straightforward. These observations are explained by the higher affinity of Pb to iron oxides at lower pollution levels and their preferential bonding to carbonates when Pb and Zn contents are extremely high, as demonstrated by Iavazzo et al. (J Geochem Explor 113:56–67, 2012) in a study of former Zn–Pb mine in Morocco. Based on the general features of the spatial maps of field-measured magnetic susceptibility, mass-specific magnetic susceptibility, Pb and Zn contents, it is concluded that field magnetic measurements provide a good qualitative proxy of pollution spread out of the mining galleries, while laboratory measurements afford a more detailed investigation of the links between iron oxides and the main heavy metals in the ore.  相似文献   

Zinc,Copper, and Lead Geochemistry of Oceanic Igneous Rocks—Ridges,Islands, and Arcs     

《International Geology Review》2012,54(5):379-420

Variations in the abundances of Zn, Cu, and Pb are found to be useful in identifying tectonic regimes and separating oceanisland basalts into enriched- and depleted-source categories. The average Zn, Cu, and Pb contents of normal mid-ocean ridge basalts (N-MORB) are 84, 70, and 0.35 ppm, respectively. Differences in average Zn contents for various ridges reflect more the varying degrees of differentiation than variations of Zn content in the source rocks. At a Mg# of 70, or Mg#₇₀, which is taken to represent primitive MORB, many MORB sequences converge at a Zn content of 58 ± 6 ppm, which is close to the value for primitive mantle (50 ppm) and ordinary chondrites (～55 ppm). Values of 0.1 to 0.15 ppm Pb in MORB at Mg#₇₀, best defined at the superfast-spreading Southern East Pacific Rise, are similar to estimates of Pb in the primitive mantle (0.12 to 0.18 ppm). They also are near the lower end of the range for ordinary chondrites. The very slow spreading Southwest Indian Ocean Ridge has a sequence with higher Pb contents, in addition to a more normal sequence, which has a visual best value of 0.4 ppm Pb at Mg#₇₀. With the exception of the Walvis Ridge, Zn and Cu appear to be little affected by proximity to hotspots (i.e., E-MORB); however, Pb contents are higher and average about 0.6 ppm.

Both Zn and Pb in MORB are incompatible elements (i.e., favor the melt), but Cu is a compatible element. At Mg#₇₀, there is the suggestion of a value of 100 ppm for Cu, with lower values possibly representing partial removal of sulfides and their associated Cu from the source. Nonetheless, Cu contents of primitive MORB tend to be much higher than even high estimates for the primitive mantle (28 ppm), and are closer to ordinary chondrites (～90 ppm). Therefore, Zn, Cu, and Pb all approximate chondritic values in the primitive MORB melt.

Average contents of Zn, Cu, and Pb in oceanic island basalts (OIB) are 115, 62, and 3.2 ppm, respectively. At Mg#₇₀, values of Zn and Cu are similar to the respective averages for OIB, with Zn higher and Cu lower than MORB. At a Mg# of ～40, however, OIB and MORB tend to have similar Zn contents. With further differentiation, OIB trachytes can contain >200 ppm Zn. Unlike MORB, OIB can differentiate to high Cu contents of 200 ppm at Mg#s of 40 to 60. In contrast to Zn and Cu, Pb regresses to a value of 0.83 ppm at Mg#₇₀ for Hawaiian and Reunion volcanics, which is much less than the average value for Pb in OIB volcanics, but higher than for MORB.

Average Zn, Cu, and Pb contents of magmatic-arc basalts are 77, 108, and 1.9 ppm, respectively. In basalts, Zn tends to be incompatible, but a dual incompatible and compatible behavior can occur at high SiO₂ contents. Dacites may average near 55 ppm Zn, but peralkalic rhyolite can contain >300 ppm Zn. A dual compatible and incompatible nature occurs for Cu. Most common, particularly in submarine volcanics, is a compatible trend, with a Cu content of around 80 ppm at a Mg# of 60, which decreases to less than 40 ppm at a Mg# of 30. The incompatible trend of increasing Cu can achieve >200 ppm at a Mg# of 30, leaving a gap approaching 100 ppm at that Mg#. The gap is less obvious on a plot of Cu vs. SiO₂, but is still there. The compatible trend is proposed to result from sulfur-saturated magmas, whereas the incompatible trend is believed to result from sulfur-deficient magmas. Support for this hypothesis is found in sparse sulfur-isotope data. Zn and Cu both can be incompatible over an extended range of Mg#s or silica content. When Zn and Cu are both compatible, Cu decreases more than twice as rapidly as Zn.

Primitive magmas at Mg#₇₀ average about 50 ppm Zn for submarine Mariana arc basalts and 58 ppm for forearc boninites, contents close to MORB values. Mariana arc basalts have a Zn content of ～45 ppm estimated at Mg#₇₀. Cu varies more widely than Zn in primitive magmas, being about 50 ppm Cu for Mariana Islands volcanics and 120 ppm for Kermadec Islands volcanics, a range broadly around MORB values. Average Pb contents are 1.9 ppm for island-arc tholeiites, 5.6 ppm for high-Al basalt, and 3.2 ppm for alkali basalt with average boninite of approximately 1.8 ppm. Back-arc-basin basalts in the deepest parts of the Mariana trough have Pb contents of 0.45 ppm, but more shallow parts may exceed 1.0 ppm Pb. Although the lower contents are similar to MORB values, the ²⁰⁸Pb/²⁰⁴Pb values are greater than Pacific Ocean MORB. At Mg#₇₀ for rocks from the Tonga and Kermadec island arcs, the Pb content is about 0.1 ppm, similar to MORB.  相似文献   

Analysis of a weathered profile on sulfide mineralization at Mugga Mugga, Western Australia     

G. F. Taylor  G. C. Sylvester   《Journal of Geochemical Exploration》1982,16(2):105-134

The mineralogy and geochemistry of the massive pyrite-pyrrhotite mineralization, which contains minor magnetite, sphalerite and galena, the weathered profile and surface gossan at Mugga Mugga in Western Australia have been examined. Reactions between amphibolite wall rocks and acid waters from the oxidation of the iron sulfides have resulted in distinct mineralogical zonation of the weathered profile which is further modified near the surface by lateritization. At the base of the weathered zone an opaline chert (Opal-CT) has been precipitated from fluctuations of the water table. A gossanous zone from 25.14–68.80 m with boxworks after massive pyrite is modified by abundant kaolinite, dickite and an alunite-type mineral derived from amphibolite wall rocks, while above 25.14 m both plinthite and mottled clay zones of a laterite profile are evident. Some characteristics of a mature gossan profile – sulfate-phosphate-arsenate near the base, a carbonate zone higher in the profile, and an oxide zone near the surface – overprint the gross zonation.At the interface between sulfide and weathered rock Mg, Ca, K, S, Zn, Cd, Hg, Ba are depleted, As, Sb, Mo, Cr and V contents increase and in the weathered zone, SiO₂, TiO₂, P₂O₅, SO₃, Pb, Zn, Hg, Sb, Co, Ni, W, Ba, Sr and Zr decrease up the profile whilst Al₂O₃, Fe₂O₃, CO₂, Cu and As increase. Of the elements associated with the massive pyrite (Pb, Zn, Cu, Ag, As, Cd, Hg, Sb, Co, Ni) anomalous concentrations of Pb, Cu, Ag, As and Sb occur in the surface gossan despite the possibility of complete leaching by highly acidic solutions. These anomalies are similar to those found in gossans over pyrite mineralization elsewhere in the Yilgarn Block.  相似文献   

Magnetic,chemical and x-ray studies of magnetites from Tamil Nadu,India     

N Subba Reddy  C xxxV R K Prasad 《Journal of Earth System Science》1981,90(1):91-103

Natural intensity, susceptibility, and Koenigsberger ratio were determined and studies of Rayleigh loops, and high field hysteresis, and variation of susceptibility with temperature from ?196° C to Curie temperature were made on a number of magnetite-quartzite and pyroxene, granulite samples from Tamil Nadu. FeO, Fe₂O₃, and TiO₂ proportions were estimated and cell dimensions were determined. From the magnetic studies it is inferred that in general the samples contain predominantly multidomain grains. In a few cases single-domain particles are detected, while in a few other samples a mixture of superparamagnetic particles and single domain states could be inferred. The relative remanence ratio is found to increase with coercive force. The ferromagnetic mineral in magnetite-quartzites is pure magnetite with a little alteration to hematite while in pyroxene granulites it is a titaniferous magnetite with a small percentage of TiO₂. It is probable that the cell dimensions are dependent on oxidation in magnetites, and on the content of TiO₂ in titaniferous magnetites.  相似文献   

河南舞阳铁山庙式BIF铁矿的矿物学与地球化学特征及对矿床成因的指示   总被引：4，自引：2，他引：2  

兰彩云  张连昌  赵太平  王长乐  李红中  周艳艳 《岩石学报》2013,29(7):2567-2582

河南舞阳铁矿位于华北克拉通南缘.铁山庙式铁矿是舞阳铁矿的一部分,赋存于新太古界太华杂岩铁山庙组表壳岩中.本文根据铁山庙式铁矿中三种不同类型矿石(条带状石英-辉石-磁铁矿、块状辉石-磁铁矿、块状石英-磁铁矿)中磁铁矿的矿物成分、全岩/矿的主量元素及微量元素特征,探讨铁山庙式铁矿床的成因.磁铁矿单矿物成分分析表明,条带状石英-辉石-磁铁矿矿石中磁铁矿的FeOT含量90.6％ ～93.1％,平均91.8％;块状辉石-磁铁矿矿石中磁铁矿的FeOT含量90.7％～91.2％,平均91.0％;块状石英-磁铁矿矿石中磁铁矿的FeOT含量92.0％～93.0％,平均92.4％.上述平均值均与磁铁矿FeOT的理论值(93.1％)接近.三种类型矿石的其它元素如TiO2、MgO、MnO、CaO、Al2O3 Cr2O3 NiO等含量均＜0.1％,无明显区别,表明该区磁铁矿为含杂质极少的纯磁铁矿,表现出沉积变质成因磁铁矿的特征.矿石中斜方辉石-单斜辉石及近矿围岩紫苏辉石-长石-石英矿物组合,表明铁山庙式矿床经受了高级变质作用,石英、磁铁矿等矿物普遍发生变质重结晶,颗粒粗大,但仍保存原有的地球化学组成.元素地球化学分析显示,三种类型矿石中SiO2 、TiO2 Al2O3、P2O5的含量相近;块状辉石-磁铁矿较其它二者相对贫铁、富钙、镁,这是由于块状辉石-磁铁矿石中富含铁普通辉石和铁次透辉石所致;矿石中TiO2、Al2O3含量都极低,说明该区成岩成矿过程中未受到碎屑物质的混染.三种不同类型矿石的主量元素含量总体上都与世界典型BIF的相近.对于稀土元素,三种类型矿石均具有轻稀土亏损、重稀土富集((La/Yb)PAAS=0.29～0.995＜1),La、Eu、Y的正异常(La/La*=1.10～1.89;Eu/Eu* =1.30～2.23;Y/Y* =1.47～1.84),较高的Y/Ho比值(39.7 ～51.3),具有现代海水及高温热液混合特征.因此,我们认为铁山庙式铁矿三种不同类型的矿石是极少受到陆源碎屑混染的化学沉积成因,虽遭受后期变质作用,但仍属BIF型铁矿.  相似文献   

OUTLINE OF THE GEOLOGY OF KOREA     

《International Geology Review》2012,54(12):1053-1070

A database on a number of elements in oceanic volcanic rocks is presented, including the principal major-element oxides-SiO₂, TiO₂, Al₂O₃, Fe₂O₃(T), MnO, MgO, CaO, Na₂O, K₂O, and P₂O₅ (where T refers to total iron)–and the trace elements–Ba, Ce, Cr, Cu, Ni, Sc, Sr, V, Pb (mainly by isotope dilution), Yb, Zn, and Zr. Interpretations are given for transition metals, with emphasis on Mn, Sc, and V, in order to determine the concentration of the elements in primitive melts and assess their trends in magmatic differentiation. Transition metals are not enriched in plagioclase, so all are incompatible with pure plagioclase removal–that is, they become enriched in the melt. Both Cr and Ni are known to be highly compatible with olivine separation-i.e., they are depleted in the melt early in differentiation. Also, Sc is compatible with clinopyroxene (Cpx) removal from the melt and is depleted by separation of Cpx. Copper does not fit well in any of the principal silicates, but Cu, like Ni, is greatly enriched in sulfides that may remain in the source or separate from the magma. Decreasing Ni abundances and increasing Cu contents during differentiation are a sign of olivine separation. In the analysis presented herein, V–in the absence of Cpx separation–is found to behave remarkably like the moderately incompatible element Zn, and these two elements add to the list of element pairs of similar incompatibility whose ratios are insensitive to differentiation and to submarine weathering as well. Both are enhanced in titanomagnetite, so both would be compatible during titanomagnetite separation. When Cpx separates, however, V becomes compatible like Sc, but Zn remains incompatible. Thus, decreasing V (and Sc) contents and increasing Zn contents during differentiation are a sign of Cpx separation. Manganese often behaves much like Zn and therefore is moderately incompatible, but Mn is less compatible than Zn and V in titanomagnetite. Thus, decreasing Zn and V with increasing Mn is an indication of titanomagnetite removal. Dual compatible and incompatible trends with differentiation are found chiefly for Cu, Sc, and Sr. Distinguishing mid-ocean ridge basalts (MORB), oceanic-island volcanic rocks (OIV), and island-arc volcanic rocks (IAV) may be accomplished by plots of Ce/Yb versus Ba/Ce, where OIV plot to higher values of Ce/Yb than do MORB, and IAV data plot to higher values of Ba/Ce than do those of MORB. These ratios do not seem to be significantly affected by submarine weathering.  相似文献   

磁铁矿和钛铁矿成分对四川太和富磷灰石钒钛磁铁矿床成因的约束     

佘宇伟  宋谢炎  于宋月  陈列锰  魏宇  郑文勤 《岩石学报》2014,30(5):1443-1456

产于层状镁铁质-超镁铁质岩体中的太和岩浆型Fe-Ti氧化物矿床是峨眉山大火成岩省内带几个超大型Fe-Ti氧化物矿床之一。太和岩体长超过3km,宽2km,厚约1.2km。根据矿物含量和结构等特征,整个岩体从下向上可划分为下部岩相带、中部岩相带、上部岩相带。下部岩相带主要以(橄榄)辉长岩和厚层不含磷灰石的块状Fe-Ti氧化物矿层组成。中部岩相带韵律旋回发育,(磷灰石)磁铁辉石岩主要位于旋回的底部,旋回上部为(磷灰石)辉长岩。上部岩相带主要是贫Fe-Ti氧化物的磷灰石辉长岩。太和中部岩相带磷灰石磁铁辉石岩含有5%~12%磷灰石、20%~35%Fe-Ti氧化物、50%~60%硅酸盐矿物,且硅酸盐矿物与磷灰石呈堆积结构。磷灰石磁铁辉石岩中磁铁矿显示高TiO2、FeO、MnO、MgO,且变化范围与趋势接近于攀枝花岩体。钛铁矿FeO分别与TiO2、MgO显示负相关,而FeO分别与Fe2O3、MnO显示正的相关,且TiO2、FeO、MnO、MgO含量变化较大,这些特征都暗示磁铁矿和钛铁矿是从富Fe-Ti-P岩浆中分离结晶。因此,可以推断太和磷灰石磁铁矿辉石岩形成于矿物重力分选和堆积。太和下部岩相带包裹在橄榄石中磁铁矿含有相对较高Cr2O3(0.07%~0.21%),而中部岩相带包裹在橄榄石中磁铁矿Cr2O3(0.00%~0.03%)显著降低,且这些磁铁矿Cr2O3含量变化与单斜辉石Cr含量和斜长石An牌号呈正相关。这些特征印证了形成中部岩相带的相对演化的富Fe-Ti-P母岩浆可能是源自中部岩浆房的混合岩浆。上部岩相带磁铁矿和中部岩相带顶部少量磁铁矿显示较低Ti+V可能是由于岩浆房中累积的岩浆热液对磁铁矿成分进行了改造。  相似文献