Studies on a New Material for Hydrogen Storage and Supply by Modified Fe and Fe2O3 Powder

Modified iron oxide, a new material for hydrogen storage and supply to polymer electrolyte fuel cell （PEFC）, was prepared by impregnating Fe or Fe2O3 powder with an aqueous solution containing metal cation additives （Al, Cr, Ni, Co, Zr and Mo）. Hydrogen storage properties of the samples were investigated. The results show that both Fe and Fe2O3 powder with additive Mo presented excellent catalytic activity and cyclic stability, and their hydrogen producing temperature could be surprisingly decreased. The temperature of forming hydrogen for the Fe2O3-Mo at the rate of 250 μmol·min^-1·Fe-g^-1 could be dramatically decreased from 527 ℃ before addition of Mo to 283 ℃ after addition of Mo in the fourth cycle. The cause for it was probably related to preventing the sinter of the sample particles. In addition, hydrogen storage capacity of the Fe2O3-Mo can reach w=4.5% （72 kg H2/m^3）, close to International Energy Agency （IEA） criterion. These show the value of practical application of the Fe2O3-Mo as the promising hydrogen storage material.

不同形貌纳米α-Fe2O3粉体水热合成及其催化高氯酸铵热分解研究

以Fe2(SO4)3为原料,在不同温度和时间进行水热反应,产物经过600℃下热处理6 h,得到了不同形貌的纳米α-氧化铁。通过XRD、SEM、TEM对α-Fe2O3的物相组成、形貌和微观结构进行表征。结果表明,花片状、海胆状、草莓状和哑铃状等多种形貌的产物均由纳米α-Fe2O3颗粒组装而成,纳米颗粒大小为10～50 nm。采用DTA分析了赤铁矿α-Fe2O3对高氯酸铵(AP)的催化性能。结果表明水热反应条件140℃保温4 h获得的花片状α-Fe2O3,使得高氯酸铵(AP)热分解温度提前了67.2℃,较其它形貌,催化效果明显。

不同粒度的Fe2O3对堇青石蜂窝陶瓷性能的影响

以高岭土、滑石粉、工业氧化铝和不同粒度的Fe_2O_3粉为原料,研究了Fe_2O_3粉的粒度对堇青石蜂窝陶瓷相组成、微观形貌和孔径分布的影响。实验结果表明:随着外加Fe_2O_3粉粒度的减小,加快了离子扩散速率,固溶量增加,堇青石的固相反应速率增加。当Fe_2O_3粉粒度为5μm和50μm时试样的微观结构中有微裂纹产生,为降低材料的热膨胀系数打下了基础。随着加入Fe_2O_3粉粒度的逐渐增大,产生液相,填充了试样中微孔,使孔径尺寸减小,孔径数量减少。

Effects of Rare Earth Doping on the Properties of γ-Fe_2O_3 Magnetic Powder

The effects of rare earth doping on the formation process of α-FeOOH crystallite and the properties of γ-Fe2O3 magnetic powder were investigated. The growth of needle α FeOOH crystallite was completed by the basic process. The experimental results show that the rare earth doping can increase the aspect axial ratio of needle α-FeOOH grains. its anti-sintering capability during the heat-treatment and the thermostability of γ-Fe2O3 magnetic properties. The magnetic properties of γ-Fe2O3 doping with rare earth are as follows: the coercivity Hc=36.3 kA/m (445 Oe), the ratio saturation magnetization σs=90.4μWbm/kg (72 emu/g), the ratio remanent magnetization σr=54 μWbm/kg (43 emu/g), and the temperature coefficient of remanent magnetization of γ-Fe2O3 doping with 0.1 mol% Dy can reach -5 ×10-4℃-1.

SYNTHESIS AND X-RAY POWDER DIFFRACTION DATA OF A NEW COMPOUND:K_6FeNb_(15)O_(42)

A new compound K6FeNb15O42 u(?) prepared for the first time by solid state reaction in K2O-Fe2O3-Nb2O5 ternary system. The XRD data of the title compound was determined. K6FeNb15O42 crystallizes the hexagonal system with unit cell parameters a=9. 1320(4) A,c=12. 0670(9) A, and space group P63/mcm(193) , 2=1. The calculated and measured densities are 4. 489 g/ cm3 and 4. 485 g. cm3, respectively.

SYNTHESIS AND X-RAY POWDER DIFFRACTION DATA OF A NEW COMPOUND:K_6FeNb_(15)O_(42)

A new compound K6FeNb15O42 was prepared for the first time by solid state reaction in K2O-Fe2O3-Nb2O5 ternary system. The X-ray powder diffraction data of the title compound was measured. K6FeNb15 O42 crystallizes in the hexagonal system with unit cell parameters, a = 9. 1320(4) A ,c = 12. 0670(9) A , and space group P63/mcm (193) , z = 1. The calculated and measured densities are 4. 489 g/cm3 and 4. 485 g. cm3, respectively.

Noisy-power dissipation and efficiency in NiO/Fe_2O_3 wet grinding by planetary ball mill

The relationship between the efficiency of NiO/Fe2O3 wet grinding and noisy-power dissipation was studied. The optimal grinding parameters were found as: a slurry water content of 64.10%-85.47%, ball number ratio of 360/20, revolution speed of 300.9 r/min, powder-filling ratio of 10.88%, ball-filling ratio of 20.53%-23.88%, and grinding time of approximately 6 h. The discrete element method(DEM) was employed to analyze relationship between the noisy-power dissipation and the grinding efficiency, and equations describing the relationship were derived. The mean particle size of the ground powder decreased with a decrease in the degree of noisy-power dissipation, while the grinding efficiency and the amount of specific impact power used decreased with an increase in the degree of noisy-power dissipation.

球磨时间对Fe_2O_3/Al纳米复合材料性能的影响

采用高能球磨法制备了Fe2O3/Al纳米复合粉末,并利用X射线衍射(XRD)、场发射扫描电镜(SEM)以及热分析仪(TGA/DSC)等分析测试手段,系统研究了球磨时间对复合粉末相结构、组织形貌以及热性能的影响。结果表明,随着球磨时间的增加,微米Fe2O3团聚体逐渐进入Al颗粒中,呈均匀弥散分布,且Al晶粒尺寸不断细化。当球磨时间为20 h时,Al粉已均匀分布到微米Fe2O3颗粒表面,球磨引起的晶粒长大与晶粒尺寸减小处于动态平衡,此时铝热反应热焓达到最高。球磨时间大于20 h时,所制备得到的复合粉末热焓反而降低,且易团聚。

有机膦复合添加剂应用在碱法制备α-FeOOH过程中

合成了一种以有机磷化合物为主的复合添加剂，应用到碱法制备α-ＦｅＯＯＨ过程中，发现反应的氧化速度有明显的提高、对α－ＦｅＯＯＨ形貌有明显的影响．实验发现，在Ｒ＝５．０时，复合添加剂用量为１．０×１０－３ｇ／Ｌ其晶形较佳．α－ＦｅＯＯＨ经脱水、还原、氧化制得γ－Ｆｅ２Ｏ３磁粉其性能优良，主要指标完全达到高性能磁记录材料的要求．

纳米化Fe_2O_3粉体的制备与表征

采用分析纯FeCl3.6H2O和NH3.H2O为主要原料,以均匀沉淀法制备了Fe2O3纳米粉体。通过X射线衍射(XRD)、红外光谱(IR)、扫描电子显微镜(SEM)及差热分析(DTA)等手段研究了热处理温度、分散剂、反应pH值对Fe2O3相变、结构、形貌及纳米属性的影响。结果表明:纳米化增大了Fe2O3的表面能,γ-Fe2O3转变为α-Fe2O3的温度仅为238.2℃,比常规粉体降低了约312℃;由于量子尺寸效应和表面效应,使用分散剂后α-Fe2O3纳米粉体的分散性、均匀性得到改善,粒径下降,Fe—O键伸缩及弯曲振动IR吸收频率发生蓝移;尤其是硬脂酸钠分散后α-Fe2O3的Fe—O伸缩、弯曲振动吸收频率分别蓝移11.57、10.93cm-1;获得了液相均匀沉淀法制备Fe(OH)3纳米粉体的最佳工艺条件。

MgFe_2O_4/Fe_2O_3纳米粉的溶胶-凝胶法合成及电磁波吸收特性

用热分解柠檬酸盐凝胶的方法制备了Mg-Fe2O4/Fe2O3复合纳米粉体,用综合热分析仪、X射线衍射仪、透射电镜、纳米粒度测量仪、电磁测量仪对所制备样品的结构、粒径分布、电磁波吸收特性等进行表征。结果表明,产物为平均粒径44nm的MgFe2O4和Fe2O3的混合物,在0.1、1.0和1.8GHz处tgδ(=ε″/ε′+μ″/μ′)分别为0.206、0.265及0.614。

核壳结构Ni(Cu,Co)/Al微纳米复合粒子的制备及其与Fe_2O_3的热反应性能表征

采用置换法通过对溶液中各种参数的控制,实现了在弱酸性条件下Ni(Cu,Co)3种纳米金属粒子在微米Al粉表面定量、快速地化学沉积,分别制备出核壳结构的Ni(Cu,Co)/Al3种微纳米复合粒子,并用SEM和XRD方法进行了相应表征。在此基础上,利用DSC分析研究了不同包覆物和升温速率对热反应性能的影响,用Kissinger法求解了热反应的表观活化能Ea,对比了传统微米级Al-Fe2O3混合物与Ni(Cu,Co)/Al-Fe2O3复合材料的热反应性能,同时分别提出了其相应的热反应机制。结果表明,通过对Al粉进行表面改性,其热反应性能明显增强,不同试样与Fe2O3的热反应活性依次为Ni/Al>Cu/Al>Co/Al>Al。同时,降低升温速率不利于热反应的进行。

微细Fe_2O_3粉在Fe-2%Ni-1%Cu-0.6%C粉末冶金材料中的助烧结特性

在Fe-2%Ni-1%Cu-0.6%C混合料中加入了少量微细Fe2O3粉末作为烧结助剂,研究Fe2O3粉末的添加量对混合料的压缩性、烧结合金的密度和强度以及氧和碳含量等的影响,研究微细Fe2O3粉末对合金的助烧结行为。结果表明:混合料中Fe2O3含量大于0.3%(质量分数)时,会导致成形生坯密度下降;当Fe2O3添加量为0.3%时,烧结合金的密度最高,经1120℃烧结0.5和1 h后,合金的抗弯强度比同等烧结条件下未添加Fe2O3样品的分别提高6.5%和4.2%。少量Fe2O3粉在材料烧结时对碳含量损失率的影响较小,然而可以降低烧结体中的氧含量。在压坯的烧结过程中,Fe2O3还原后于750℃左右开始加速基体颗粒间的连结,虽然在1050℃以上时微细粉的助烧结作用减弱,但烧结体中孔隙更趋于球化。

程序升温还原技术研究针形超微粒α-Fe_2O_3还原过程动力学

在针形γ-Fe_2O_3磁粉制备过程中,还原过程是关键步骤之一,本文利用程序升温还原技术研究了针形超微粒a-Fe_2O_3还原过程机理,建立了还原过程动力学研究方法,得到了a-Fe_2O_3在氮氢混合气体中还原动力学方程,并进一步研究了该还原过程动力学特征,给出了还原过程的优化操作条件.

利用氧化铁皮制备还原铁粉磁流变液

将轧钢留下的氧化铁皮用硫酸溶解并经过提纯净化得到硫酸亚铁溶液,以(NH4)2CO3为沉淀剂制备-αFe2O3,再经氢气还原后得到还原铁粉,将还原铁粉与适量硅油混合并添加少量纳米Fe3O4粉制备还原铁粉磁流变液,对还原铁粉进行了表征,对还原铁粉和磁流变液性能进行了研究。结果表明:还原铁粉粒径约为1μm,其比饱和磁化强度与羰基铁粉相当;还原铁粉磁流变液属于Binham流体,添加质量分数0.8%纳米Fe3O4粉能有效提高其剪切应力;还原铁粉磁流变液不但具有较好的抗沉降稳定性,而且在低磁场下具有良好的磁流变特性。

溶胶-凝胶法制备超细氧化铁的工艺研究

文中以柠檬酸为络合剂,用溶胶-凝胶法制备超细Fe_2O_3粉,并用TG/TA对干凝胶进行了热分析,用XRD、SEM对产物的粒度及分散性进行了表征;考察了无水乙醇,乙二醇及金属离子与柠檬酸摩尔比对产物粒度、形貌及分散性的影响.结果表明:柠檬酸溶胶-凝胶法制备的Fe_2O_3的粒度比醇盐法的要细,乙二醇的加入能够减轻产物的团聚现象,当金属离子与柠檬酸的摩尔比为1:1时,产物的粒度和分散性最佳,XRD测出原始晶粒的精确尺寸为18.3 nm,SEM所测团粒的平均粒径为200 nm左右,且颗粒近似球形.

萃取Fe^(3+)和氨水-乙醇反萃沉淀法制备α-Fe_2O_3

以磷酸二异辛基酯(P204)为萃取剂,CCl4为溶剂,从Fe(NO3)2水溶液中萃取铁离子,以氨的乙醇溶液反萃含铁的有机相,通过优化控制相间传质过程,获得了Fe(OH)3前驱体,经煅烧后得α-Fe2O3粉体,采用TEM、FTIR、XRD等测试技术对α-Fe2O3进行表征。研究表明,在油水相比为1∶1,水相c(Fe3+)=0.10 mol/L(pH=3.0)、油相P204为V(P204)∶V(CCl4)=1∶3、平衡时间为20 min,Fe3+萃取率达98.44%;反萃取溶液V(氨水)∶V(乙醇)=1∶7、陈化温度约10.0℃,制备纳米α-Fe2O3的煅烧温度为600℃较宜。

MgFe_2O_4-Fe_2O_3纳米粉体的软化学合成及电磁学特性

Nano-MgFe2O4-Fe2O3 magnetic powders were synthesized by citrate gel under microwave irradiation. The structure,particle size distribution,electromagnetic characteristics of nano-MgFe2O4-Fe2O3 were characterized by using TG-DTA, X-ray, electronic microscope, nano-size measurement and electromagnetism measurement apparatus?The results show that the product is a mixture of MgFe2O4 and Fe2O3 with average size of 44 nm, tanδ for the product is 0.265 and 0.610 at frequency of 1.0 GHz and 1.8 GHz respectively.

超微细高密度铁磁记录材料的合成研究——(Ⅰ)α-FeOOH和α-Fe_2O_3的合成

介绍了α－ＦｅＯＯＨ和α－Ｆｅ２Ｏ３的合成途径。采用ＦｅＳＯ４、ＮａＯＨ作基础原料，通过选择适宜的合成条件，先合成具有针状结构的α－ＦｅＯＯＨ，然后将α－ＦｅＯＯＨ热处理成α－Ｆｅ２Ｏ３，最后将α－Ｆｅ２Ｏ３制成γ－Ｆｅ２Ｏ３。合成的α－Ｆｅ２Ｏ３呈均匀的针状结构，晶体的长轴和短轴之比在８．４∶１～９．５∶１之间，晶体的平均粒子长度在０．１５１～０．１５７μｍ之间。

α-Fe_2O_3纳米粉体的低温燃烧合成与表征

以硝酸铁-聚乙烯醇为反应体系,采用低温燃烧合成法制备了-αFe2O3粉体。通过X射线衍射、扫描电镜、透射电镜和能谱分析等测试手段,对产物进行了表征。结果表明,硝酸铁和聚乙烯醇的摩尔比为1∶0.5,150℃时制备的干凝胶加热至400℃可发生燃烧合成反应,此温度下保温煅烧1 h后可得到纳米-αFe2O3粉体(含少量的-γFe2O3),反应产物颗粒边缘光滑,粒度分布均匀,呈褐红色。XRD结果表明,有机物已完全分解,经XRD计算、TEM及纳米粒子分析仪测定,晶粒尺寸在20 nm^50 nm之间。