Ni对Fe_3Si化合物硬度影响的微观组织结构和电子结构研究

采用实验和第一性原理方法,从微观组织结构、电子结构、力学常数和布局分析研究了Ni浓度和烧结温度对Fe_3Si化合物硬度的影响.结果表明Ni含量为3.125at.%时,化合物具有最小硬度值.进一步增加Ni浓度,其硬度增大,B/c44比值先增加后减小,而G/B比值先减小后增加.但当浓度超过6.25at.%后,不仅不能改善Fe_3Si脆性,反而使合金脆化程度加剧,说明适当添加Ni可韧化Fe_3Si化合物.烧结温度较低时,电子结构对Fe_3Si化合物硬度的影响占主导作用,随烧结温度的升高,先析出的晶粒迅速长大,Ni含量对化合物硬度的影响有所减弱,微观组织结构的影响大于电子结构.     

烧结Nd-Fe-B磁体的磁性能一致性与其微观结构的关系

分析了微观结构和热处理工艺对矫顽力的影响,发现在矫顽力一定的情况下,磁体的微观结构越“差”,则保证不同批次磁体矫顽力变化不大于某一给定值所需的工艺条件就越严格;反之则越宽松.就同一炉产品而言,微观结构越好的磁体,其矫顽力受烧结(热处理)炉温度梯度的影响越小,其结果是该炉产品的一致性越高.反之,受温度梯度的影响越大,磁体的一致性也就越低.该研究结果说明:在条件许可的情况下,应首先考虑通过改善磁体的微观结构来提高磁性能一致性. 关键词： Nd-Fe-B永磁体 微观结构 内禀矫顽力 一致性     

R_2(Fe_(1-x)Al_x)_(14)B的内禀磁性和永磁性能(R=Nd和Y)

本文研究了Al在R_2(Fe_(1-x)Al_x)_(14)B多元合金中的固溶度(R=Nd和Y),当x<0.1时,可形成四方结构。研究了在此类合金中,饱和磁化强度、居里温度、磁晶各向异性等内禀磁性,以及矫顽力和磁能积等永磁性能随Al含量的变化。发现以Al代换Fe时,使铁次点阵的磁晶各向异性出现极值;同时以Al代换Fe时,可使磁体的矫顽力显著提高。以Co和Al同时对Fe进行代换,制造成分约为Nd_(16·5)B_7(Fe_(1-x-y)Al_xCo_y)_(76.5)的磁体,既可提高居里温度,又可提高矫顽力,从而可以改善具有高磁能积磁体的温度性能和减少磁体的总损失。     

稀土含量对速凝工艺制备(Nd,Dy)-(Fe,Al)-B合金结构和磁性能的影响

采用双合金法制备了不同稀土含量的(Nd,Dy)-(Fe,Al)-B合金系列,研究了稀土含量的多寡对薄带和最终烧结磁体的微观结构和磁性能的影响.研究结果表明,适量的稀土含量(～3145%)不仅能改善速凝带主相(Nd,Dy)₂Fe₁₄B的单相性,还有利于富稀土(Nd,Dy)相在晶界的均匀分布.当主相薄带的稀土含量在接近2∶14∶1相稀土含量时,磁体的内禀矫顽力和磁能积显著提高.当稀土含量较少时,对速凝薄带的合适时效热处理将能有效地提高最终烧结NdFeB磁体的磁特性. 关键词： 双相烧结 速凝技术 微观结构 磁性能     

Sm_2Co_(17)型永磁合金的辐照效应研究

Sm_2Co_(17)型永磁合金大量使用在上海同步辐射光源储存环的永磁型波荡器上,在受到长期辐照后会发生磁性能损失的现象,进而影响同步辐射光的品质.为了探索其潜在的微观机理,本文首先对Sm_2Co_(17)型永磁合金所处混合辐射场的粒子及相关物理量进行了计算分析,确定引发磁性能损失的主要粒子是中子.然后采用Ar离子模拟中子辐照损伤的方法对其进行辐照,采用透射电镜对其辐照前后的微观形貌及微观结构进行了研究探讨,采用振动样品磁强计对永磁合金辐照前后的饱和磁化强度进行了分析对比,并讨论了微观结构演化与宏观磁性能变化的联系.结果表明,Ar离子辐照后Sm_2Co_(17)型永磁合金饱和磁化强度的不可逆损失与微观结构变化有直接的关系,其2:17相从单晶结构转变为非晶结构是造成其磁性能损失可能的微观机制.     

Fe_9Si的电子结构及铁磁性质的第一性原理研究

采用第一性原理的密度泛函理论(Density Functional Theory)赝势平面波方法,对Fe_9Si的电子结构和铁磁性质进行理论计算.计算结果表明:(1)Fe_9Si具有负的形成热-0.1094 eV/atom,结合能5.124eV/atom,表明Fe_9Si合金具有强结合力和结构稳定性;(2)Fe_9Si具有典型的金属能带特征,穿过Fermi能级的能带最主要是Fe的3d态电子的贡献,其次是来自Si的3p态电子的贡献.结合键不是单一金属键,而是金属键和共价键组成的混合键;(3)Fe_9Si的铁磁性主要来自Fe原子的未满层壳的3d态电子的自旋.计算结果为Fe_9Si铁磁性材料的设计与应用提供了理论依据.     

Si对Nd_2Fe_(14)B四方相结构和磁性的影响

本文对Si加入Nd_2Fe_(14)B四方相后所形成的合金相的结构和磁性进行了研究。结果表明,Si加入Nd_2Fe_(14)B四方相后并不破坏它的结构(Si的含量可达B的两倍),而形成Nd_2(Fe,Si)_(14)B赝三元金属间化合物。随着Si含量的增加,晶格常数和饱和磁化强度随之减小,但居里温度则随之增加。Si的加入,并不改变Nd_2Fe_(14)B的室温各向异性的方向和大小,但对低温下的各向异性影响很大,使易磁化锥面与c轴的夹角增大。     

落管中Ni-Fe-Ti合金的快速凝固机理及其磁学性能

采用落管自由落体方法实现了Ni_(45)Fe_(40)Ti_(15)合金在微重力无容器条件下的快速凝固,获得了直径介于160—1050μm的合金液滴.理论计算表明冷却速率及过冷度随液滴直径减小而增大,并呈指数函数关系,实验获得的最大过冷度为210 K(0.14 T_L).随着过冷度增大,凝固组织中粗大的γ-(Fe,Ni)枝晶逐渐细化,二次枝晶间距减小,溶质Ti在γ-(Fe,Ni)相中的固溶度显著扩展.对不同直径合金液滴的凝固样品进行磁学性能分析,结果表明随着凝固合金液滴直径减小,其饱和磁化强度增大,矫顽力减小,矩形比下降,软磁性能明显提高.     

Nd_2(Fe,Si)_(17)合金的结构与磁性

本文对Nd-Fe-Si三元系富铁区域相的结构和磁性进行了研究。结果表明,Nd-Fe-Si三元系富铁区域(Fe>40at％), 除出现NdFe_2Si_2三元金属间化合物外(Si>20at％),同时只出现Nd_2(Fe,Si)_(17)赝二元金属间化合物,其中Si取代9d位的Fe原子,而不能形成类似于Nd_2Fe_(14)B的三元金属间化合物,Si取代Nd_2Fe_(17)中的9d位Fe原子后,使晶胞体积缩小;使饱和磁化强度减小;同时使Fe次晶格的铁磁相互作用增强,导致居里温度增高;还使得Fe次晶格的易面各向异性减弱,造成室温下各向异性场减小。     

直流磁控溅射Si和玻璃衬底Fe/Co多层膜的磁性能比较

对直流磁控溅射Si和玻璃衬底［Co_t/Fe_3t］₅(t=2, 3, 4, 5nm)多层膜的磁性能进行了比较.对于t相同但衬底不同的样品,实验发现饱和磁化强度相差很小,但是矫顽力却相差很大.对矫顽力差异的理论分析表明,多层膜的粗糙度和畴壁类型是引起这种差异的主要原因. 关键词： Fe/Co多层膜 磁性能 矫顽力     

Effect of magnetic properties of soft magnetic phase on the energy product of an exchange-spring magnet

Research on exchange-spring magnets has focused on the microstructures of the materials.However,research has seldom been concerned with the effect of magnetic properties of soft magnetic phase on the energy product of an exchangespring magnet.In this paper,a simple one-dimensional numerical simulation is used to investigate this effect in a Nd2Fe14Bbased exchange-spring magnet.The results reveal that the larger the anisotropy constant,the stronger the exchange coupling,and the higher the magnetization of the soft magnetic4 phase,the larger the energy product of an exchange-spring magnet.This provides evidence for choosing a soft magnetic phase in an exchange-spring magnet.     

Effect of alloying on magnetic properties of Fe-Cr-12 wt% Co permanent magnet alloys

Effect of alloying additional elements (Al, Si, Ti, V, Ni, Cu, Zr, Nb and Mo) with Fe-22/30 wt% Cr-12 wt% Co permanent magnet alloys manufactured by magnetic aging has been systematically studied with magnetic measurements and transmission electron microscopy (TEM), on a laboratory scale. It is found that the alloying shifts the optimum Cr content to a lower lever. Ti and Si show the greatest enhancement on magnetic properties yet narrow the optimum magnetic aging temperature range. Mo, Nb and Cu, when used together with Si, promote magnetic properties and widen the optimum magnetic aging temperature range. Ni and Zr are simply magnetic diluents. V is good for the magnetic properties only at a large amount of addition. The origin of alloying effects explored by TEM microscopy is attributed to the degree of particle entanglement as well as elongation.     

New developments in technologically important magnetic materials

In the past decade there has been a number of new developments in magnetic materials that should pave the way for expanded applications. These include: highly oriented high induction silicon steel; new varieties of permalloys, especially near 65% Ni; amorphous soft magnetic materials of the type (Fe, Co, Ni)₈₀ (P, B, Al)₂₀ produced by continuous rapid quenching; rare earth-cobalt permanent magnets with _iH_c to 150 kA/m and (BH)_max to 200 kJ/m³; ductile chromium cobalt iron permanent magnets with properties comparable to the alnicos; new families of ductile semihard magnets particularly for miniature self-latching dry reed contacts; and a new memory technology based on magnetic bubbles. These new developments will be discussed along with prospects for future applications.     

Magnetocrystalline anisotropy in permalloy revisited

Permalloy with a body-centered-cubic structure has been grown on GaAs(001) by molecular beam epitaxy. Its magnetism, Curie temperature, and magnetic anisotropy are determined experimentally and compared to those of conventional face-centered-cubic Permalloy. Unexpectedly the vanishing magnetic cubic anisotropy in Permalloy is found to be independent of its atomic structure but depends only upon the stoichiometry of Fe and Ni in the FexNi1-x alloy. This observation is further investigated and confirmed by first-principles electronic band calculations, which help to understand the long-standing issue of why Permalloy should be a soft magnet.     

Nb含量对烧结NbFeB永磁体磁性能及显微结构的影响

关键词：     

The growth of soft magnetic FeNiN thin films under different experimental procedures

FeNiN thin films with good soft magnetic properties were synthesized on Si (1 0 0) substrates at 473 K by RF magnetron sputtering. The dependence of phase structure and magnetic properties on nitrogen partial pressure, nickel concentrations, film thickness and substrate temperature were systematically investigated. The phase evolution from α-(Fe,Ni)N to ξ-(Fe,Ni)₂N with increase of nitrogen partial pressure was seen. The addition of Ni caused FeNiN films to turn from BCC structure to FCC structure. Clear reproducible striped domains appeared at the film surfaces when X_Ni=19.6%, which is explained by the high enough perpendicular anisotropy and the small stress in the film. All films show smooth surfaces and good soft magnetic properties compared to corresponding FeN compounds. The magnetic properties depended dramatically on the phase structure. Optimum soft magnetic properties with H_C of <1 Oe are obtained between 5.0%?X_Ni?10.0%.     

The effect of F substitution on the magnetic properties of Nd−Fe−B based compounds

Various efforts are currently undertaken to raise the relatively low Curie temperature of the otherwise promising Nd?Fe?B type permanent magnet material. The substitution of Fe by several elements was found to increaseT _c, which, on the other hand, can be accompanied by a reduction of the magnetocrystalline anistropy. In the present paper a systematic Mössbauer study was carried out, using Co, Ni, Al, Si and Ga as substituents. The specific influence of each element upon the magnetic properties is attributed to its preference for entering a certain Fe lattice site. Simple atomic size considerations are proved to be insufficient for explaining the preferred occupation observed experimentally. Obviously the local electronic structure has to be studied more carefully. Finally, the interplay between magnetism and metallurgy (particularly the formation of precipitations), is found to be of some importance.     

Magnetic properties and resistivity of a 2:17-type SmCo magnet doped with ZrO_2

In order to counteract the demagnetization caused by eddy current loss, widespread attention has been devoted to increasing the resistivity of permanent magnets. We prepared 2:17-type Sm Co magnets doped with different ZrO_2 contents and investigated the influence of the ZrO_2 content on the magnetic properties and resistive anisotropism. The results showed that not only was the resistivity of the magnet improved, but, in addition, the coercivity of the magnet was significantly increased. The microstructure was studied with TEM, which showed that ZrO_2 doping was able to cause a decrease in the lamellar phase density and the growth of cellular structures. The increased grain boundaries and Sm_2O_3 phases were favorable to the improvement of resistivity. The decrease of the lamellar phases caused a narrowing of the resistive anisotropism. The additional Cu in the center of the cellular boundaries was the main reason for the enhancement of Hcj.However, an excessive amount caused an increase of the Zr_6(Fe Co)_(23) phase and a deterioration of the cellular structure,thereby leading to a decrease in coercivity.