Fe2P/NPC催化剂的制备及电解水制氢性能研究

为了量化分析Fe2P/NPC催化剂的电解水制氢性能,分析了制备原理,对水溶液中催化剂进行氧化反应,建立了Fe2P/NPC催化剂在不对称羰基烯条件下的光谱和热力学分析,采用光谱特征分析的方法,进行离子间耦合反应,在丙基化催化作用条件下,构建Fe2P/NPC催化剂制备的化学降解模型,结合基化反应特性,测试Fe2P/NPC催化剂的成核速率和制备速率,根据电阻性能和伏安特性曲线分析,进行电解水制氢性能分析。测试得知,设计的Fe2P/NPC催化剂制备方法具有很好的萃取能力,几种催化剂的加氢活性较好,电解水制氢性能较强,具有很好的化工应用价值。

热压烧结提高Mn-Fe-P-Si巨磁热材料的力学性能

研究了三种不同工艺制备过程对巨磁热材料Mn1.25Fe0.65P0.50Si0.50化合物的结构、力学及磁热性能的影响。XRD结果表明,两种工艺样品的晶体结构均为Fe2P型六角结构,空间群为P-62m。磁性结果及分析表明,热压烧结样品的磁性和磁热效应降低,但其相对制冷能力得到提升。热压烧结技术样品内部更加致密,力学性能显著提升,最大抗压强度和应变分别提升了约557%和167%。

Fe_(2)P化合物磁弹性耦合相变过程中的声子演化行为

通过第一性原理计算方法,研究Fe_(2)P化合物分别在铁磁、反铁磁状态下的声子模式、电荷密度随c/a演化的规律。铁磁状态下,随着c/a增大声子逐渐软化,直到c/a=61.947×10^(-2)时,声子声学模式出现虚频;反铁磁状态下,该c/a值的声子模式没有虚频出现。对比铁磁状态下基态和c/a=61.947×10^(-2)的电荷密度发现,晶胞c/a增加过程中3g面内的共价键增强,在晶胞[001]方向上出现部分成键态向反键态转变的现象,当c/a接近临界值时,成键与反键之间达到平衡,导致晶格失稳(声子虚频)而出现结构的突变。这会导致铁磁有序被破坏、铁磁序失稳,最终使Fe_(2)P化合物磁性转变为反铁磁性。

Fe_2P弹性常数的理论计算

基于密度泛函理论,运用第一原理赝势平面波方法,计算了六方晶系和正交晶系Fe2P的弹性常数,对两种结构Fe2P的形成焓、电子态密度、晶格参数、体弹性模量、剪切模量和泊松比等进行了预测,除体弹性模量外,计算结果与已有的实验和其他计算结果相符。结果表明:六方晶系的Fe2P比正交晶系的Fe2P稳定,两种结构的Fe2P化合物均表现为延性,正交晶系Fe2P的延性比六方晶系的Fe2P的延性要好。

Fe_2P型磁致冷材料研究进展

MnFe(P,As,Ge,Si)合金是一类原料丰富、价格低廉、磁热性能优异的磁致冷材料.介绍了MnFe(P,As,Ge,Si)磁致冷材料的晶体结构、磁结构、磁相变、制备工艺及磁热性能优化方法等方面的研究进展.MnFe(P,As,Ge,Si)合金具有六方Fe2P型晶体结构;合金的居里温度在室温区附近随其成分变化连续可调;合金在磁相变过程中呈现巨磁热效应,磁热效应的物理本质是一级磁弹性相变;合金的制备工艺和成分对其综合磁热性能具有较大影响,经成分和工艺优化的MnFe(P,As,Ge,Si)合金是一种极具实用化潜能的新型室温区磁致冷材料.

分步碳包覆合成高密度LiFePO4/C复合材料

采用分步碳包覆法合成LiFePO4/C复合材料。首先,将原料Fe2O3、NH4H2PO4和葡萄糖经过固相反应合成Fe2P2O7/C复合材料,再将Fe2P2O7/C与前驱体Li2CO3、葡萄糖混合,通过二次碳包覆工艺合成LiFePO4/C复合材料,并考察合成温度对LiFePO4/C复合材料电化学性能的影响。采用X射线衍射、扫描电镜、差热-热重分析、电化学阻抗谱(EIS)和充放电测试对材料的性能进行表征。结果表明:以制取的Fe2P2O7/C为前驱体合成的LiFePO4/C复合材料具有较好的物理和电化学性能,材料的振实密度达1.26 g/m3,0.1C放电容量为158.3 mA.h/g,1C初次放电比容量达到140 mA.h/g。

Fe_2P化合物的一种新制备方法及其磁性研究

采用机械合金化方法制备了非晶态Fe2P化合物.在1273K下晶化处理5h,得到晶态Fe2P二元化合物,通过X射线衍射和磁性测量分析了样品的晶体结构和磁性能.X射线衍射结果表明:随着球磨时间的增加,Fe、P粉末混合物的颗粒度逐渐减小,当球磨时间增加到100h时,衍射峰基本消失;经过退火的样品形成单一的Fe2P六角结构,空间群为P-62m.磁性测量结果表明:随着温度的升高,Fe2P化合物经历了由铁磁到顺磁的转变过程,居里温度为290K;在1.5T的磁场变化下,Fe2P化合物的最大磁熵变为0.74J/(kg.K),并且具有较大的半峰宽.

(Mn,Fe)_(2)(P,Si)化合物的单晶生长及其磁性

Fe_(2)P型一级相变材料因其巨磁热效应和原材料丰富且低廉等特点,在室温磁制冷和磁热泵等新兴绿色环保技术领域具有良好的应用前景。在高能球磨和固相烧结法制备(Mn,Fe)_(2)(P,Si)多晶样品的基础上,通过助溶剂法生长(Mn,Fe)_(2)(P,Si)单晶,研究Fe_(2)P型(Mn,Fe)_(2)(P,Si)系列化合物的单晶生长工艺。利用扫描电镜(SEM)观察单晶微观形貌,用电子能谱(EDS)对单晶的化学成分进行定量分析,研究其化学成分对经过一级磁相变之后的微观组织结构的影响。结果表明,通过优化初始成分和制备工艺,可生长具有不同Mn∶Fe和P∶Si成分比例的单晶;发现Mn_(0.7)Fe_(1.31)P_(0.72)Si_(0.30)单晶在发生一级相变时的内应力最小,经过三次一级磁相变后仍保留原有形状。磁性测量结果表明,通过改变Si和Fe含量,可将一级相变引起的热滞从60 K降到10K左右,成功调控了(Mn,Fe)_(2)(P,Si)单晶的一级相变和微观组织结构。

Mn_(1.27)Fe_(0.68)P_(1-x)Si_x合金的批量制备与磁热效应

采用机械合金化工艺,通过改变成型和退火条件,批量制备了Mn1.27Fe0.68P1-xSix(x=0.50,0.52,0.54,0.56)系列合金,并研究了合金的物相结构和磁热效应.室温(293K)XRD表明,该合金均为Fe2P型六角结构,空间群为P62 m.当x=0.50,0.52,0.54,0.56时,由M-T曲线可知,居里温度TC分别为231,260,277,310K,热滞ΔThys分别为4.7,3.4,2.9,2.4K;在变化的外磁场(0～1.5T)下,由M-B曲线求得合金的最大磁熵变ΔSmax分别为12.0,14.2,7.8,8.1J/(kg.K).

以Fe_2P_2O_7为前驱体制备LiFePO_4及其电化学性能（英文）

以磷铁废渣(Fe1.5P)和温室效应气体CO_2为原料,以磷酸为补充磷源合成磷酸铁锂(LiFePO_4)的前驱体Fe_2P_2O_7,并研究了其合成过程对LiFePO_4正极材料储能性能的影响。采用SEM观察了LiFePO_4的表面形貌,采用XRD分析了LiFePO_4和Fe_2P_2O_7的晶体结构。进一步对该方法进行优化,发现Fe1.5P与磷酸混合物(nFe1.5P∶nH3PO4=1∶1)在800℃热处理6 h合成的Fe_2P_2O_7对应的LiFePO_4/C电化学性能最好,在0.1C,0.2C,0.5C和1C倍率下的容量分别可达130,126,117和108 m Ah·g^(-1)。

中国大陆科学钻探(CCSD)主孔石榴石橄榄岩中发现Fe_2P合金矿物

在东海大陆超深钻(CCSD)的钻孔橄榄岩岩屑(孔深603-683米深部)中,分离出的矿物有硅酸盐、氧化物、硫化物、碳化物、自然元素、金属互化物和合金,计50-60种矿物。多种特征表明其中有一些不寻常矿物,并且有些矿物具有球状外形,如自然铁、镍纹石、铁镍合金、磁铁矿等。本文报道通过成分和结构分析鉴定出的铁磷合金矿物(Fe,P),成分中含少量Cr,Ni和Co,成分均一,分子式为(Fe1.80Ni0.05Cr0.02)P。EDXD数据表明该矿物的晶系属六方晶系;格子类型为P;空间群为P62m;晶胞参数a=b=5.877Ac=3.437A,a:c=1:0.5848。通过ICDDPDF-2x射线粉晶衍射数据库2004年公布的最新版本搜索查询,发现与人工合成的同种矿物Fe2P(ICDD83-2337,Barringerite.syn)十分接近,类似的矿物已在陨石中发现(FeNi)P,故确定本文报道的铁磷合金(Fe2P)为地球上首次发现的天然合金矿物。其成因和形成条件的研究正在进行中。

Fe_2P_2O_7制备锂离子电池正极材料LiFePO_4的碳包覆优化研究

利用Fe_2P_2O_7和碳酸锂为原材料,并通过不同的碳包覆合成LiFePO_4/C复合材料.利用XRD、SEM、碳硫分析仪、恒流充放电法和循环伏安对产物的组成、结构、形貌和电化学性能进行测试,确定含碳量为2.45wt%的LiFePO_4/C复合材料具有更好的电化学性能.实验结果表明,在0.1C倍率下,锂离子电池的放电比容量为130.49 m Ah/g,在1C倍率下,锂离子电池的放电比容量为108.58 m Ah/g.

Effect of Fe_2P in LiFePO_4/Fe_2P composite on electrochemical properties synthesized by MA and control of heat condition

In order to control the size and distribution of the high conductive Fe2P in LiFePO4/Fe2P composite, two different cooling rates (Fast: 15 ℃·min-1, Slow: 2 ℃·min-1) were employed after mechanical alloying. The discharge capacity of the fast cooled was 83 mAh·g-1 and the slow cooled 121 mAh·g-1. The particle size of the synthesized powder was examined by transmission electron microscopy and distribution of Fe2P was characterized using scanning electron microscopy (SEM). In addition, two-step heat treatment was carried out for better distribution of Fe2P. X-ray diffraction (XRD) and Rietveld refinement reveal that LiFePO4/Fe2P composite consists of 95.77% LiFePO4 and 4.33% of Fe2P.

磷酸铁锂烧结工艺对磷化铁生成的影响

通过XRD分析,研究预烧、煅烧环境对制备磷酸铁锂（LiFePO4）时磷化铁（Fe2P）杂质的影响。预烧中生成大量的还原性气体及煅烧温度,对Fe2P的生成有重要影响。在预烧和煅烧过程中,对LiFePO4的深度还原是Fe2P形成的唯一原因。含有Fe2P的LiFePO4的动力学特性更高。4 kg/批下制备的LiFePO4前驱体在箱式炉中预烧,再在管式炉中800℃下煅烧20 h,产物在2.0--4.2 V循环,0.1 C首次放电比容量为152 m Ah/g,2.0 C放电比容量可达133 m Ah/g。

Preparation of Fe_2P/Al_2O_3 and FeP/Al_2O_3 catalysts for the hydrotreating reactions

A 60%Fe/Al_2O_3 catalyst was prepared by the co-precipitation method.It was reduced by H_2 to produce metallic Fe,which was then sulfided by CS_2 to Fe_(0.96) S and Fe_3S_4 or phosphided by triphenylphosphine(PPh3) in liquid phases to Fe2 P and Fe P.It was found that the iron sulfides(Fe0.96 S and Fe_3S_4) exhibited the low activity for the hydrodesulfurization(HDS) reactions.The HDS activity was also low on the Fe(metal)/Al_2O_3 and Fe_2 P/Al_2O_3 catalysts since they were converted into Fe0.96 S and Fe_3S_4 during the HDS reactions.In contrast,the FeP/Al_2O_3 was found to be stable and active for the HDS reactions.In particular,Fe P/Al_2O_3 possessed significantly smaller Fe P particles than Fe P/C,leading to the significant higher HDS activity of FeP/Al_2O_3 than Fe P/C.

原位TiB_(2(p))/Fe复合材料的制备及其显微组织

利用Fe Ti B熔体反应制备了TiB2颗粒增强铁基复合材料,研究了该材料的显微组织。热力学分析表明,Fe Ti B熔体具有反应生成TiB2的可能性。试验结果表明,TiB2颗粒均匀分布于α Fe晶粒中,晶内TiB2粒子平均间距大于晶界。TiB2粒子尺寸大多为1～6μm,形状大多为接近等轴的多面体。

Electrochemical performance of LiFePO_4/(C+Fe_2P) composite cathode material synthesized by sol-gel method

A LiFePO4/（C＋Fe2P） composite cathode material was prepared by a sol-gel method using Fe（NO3）3.9H20, LiAc·H2O）, NHaH2PO4 and citric acid as raw materials, and the physical properties and electrochemical performance of the composite cathode material were investigated by X-ray diffractometry （XRD）, scanning electron microscopy （SEM）, transmission electron microscopy （TEM） and electrochemical tests. The Fe2P content, morphology and electrochemical performance of LiFePOa/（C＋Fe2P） composite depend on the calcination temperature. The optimized LiFePO4/（C＋FeeP） composite is prepared at 650 ~C and the optimized composite exhibits sphere-like morphology with porous structure and Fe2P content of about 3.2% （mass fraction）. The discharge capacity of the optimized LiFePO4/（C＋FeRP） at 0.1C is 156 and 161 mA.h/g at 25 and 55 ℃, respectively, and the corresponding capacity retentions are 96% after 30 cycles; while the capacity at 1C is 142 and 149 mA.h/g at 25 and 55 ℃, respectively, and the capacity still remains 135 and 142 mA-h/g after 30 cycles at 25 and 55℃, respectively.

含钙锶钡Fe_2P中间合金中高磷的测定

金属及合金中高磷的测定方法,有的使用了硫酸盐及硫酸,甚至有的使用了剧毒的硫酸铍,它们将样品溶解并形成钙锶钡的硫酸盐沉淀,这就严重地影响了磷的测定,为此,本文采用稀王水溶样,在2M硝酸介质中形成磷钼酸铵沉淀,过滤分离后,用酸碱滴定法进行测定,避免了钙锶钡的严重干扰,既简化了分析手续,节省试剂,又获得了较好的结果。

Phase transitions and magnetocaloric effects in intermetallic compounds MnFeX(X=P,As,Si,Ge)

Since the discovery of giant magnetocaloric effect in MnFeP1-x As x compounds,much valuable work has been performed to develop and improve Fe2P-type transition-metal-based magnetic refrigerants.In this article,the recent progress of our studies on fundamental aspects of theoretical considerations and experimental techniques,effects of atomic substitution on the magnetism and magnetocalorics of Fe2P-type intermetallic compounds MnFeX（X=P,As,Ge,Si） is reviewed.Substituting Si（or Ge） for As leads to an As-free new magnetic material MnFeP1-xSi（Ge）x.These new materials show large magnetocaloric effects resembling MnFe（P,As） near room temperature.Some new physical phenomena,such as huge thermal hysteresis and ＇virgin＇ effect,were found in new materials.On the basis of Landau theory,a theoretical model was developed for studying the mechanism of phase transition in these materials.Our studies reveal that MnFe（P,Si） compound is a very promising material for room-temperature magnetic refrigeration and thermo-magnetic power generation.

Preparation of LiFePO_4 for lithium ion battery using Fe_2P_2O_7 as precursor

In order to obtain a new precursor for LiFePO4, Fe2P2O7 with high purity was prepared through solid phase reaction at 650 ℃ using starting materials of FeC2O4 and NH4H2PO4 in an argon atmosphere. Using the as-prepared Fe2P2O7, Li2CO3 and glucose as raw materials, pure LiFePO4 and LiFePO4/C composite materials were respectively synthesized by solid state reaction at 700 ℃ in an argon atmosphere. X-ray diffractometry and scanning electron microscopy（SEM） were employed to characterize the as-prepared Fe2P2O7, LiFePO4 and LiFePO4/C. The as-prepared Fe2P2O7 crystallizes in the Cl space group and belongs to β-Fe2P2O7 for crystal phase. The particle size distribution of Fe2P2O7 observed by SEM is 0.4-3.0 μm. During the Li^＋ ion chemical intercalation, radical P2O7^4- is disrupted into two PO4^3- ions in the presence of O^2-, thus providing a feasible technique to dispose this poor dissolvable pyrophosphate. LiFePO4/C composite exhibits initial charge and discharge capacities of 154 and 132 mA·h/g, respectively.