纳米Zn0.6CoxFe2.4－xO4晶粒的结构相变与磁性研究

采用溶胶 凝胶自燃烧法制备了纳米尺度的锌钴铁氧体Zn06CoxFe24-  xO4(x=0—030)粉体,分别在不同温度下进行了热处理，利用x射线衍射仪(XRD) 和振动样品磁强计(VSM)对其物 相结构和磁性进行了测量和分析.实验结果表明，锌钴铁氧体Zn06Co015Fe 225O4在550—800℃温度区间出现α Fe2O3过渡相，在高于800℃温度时生 成 单一尖晶石相锌钴铁氧体；随钴含量的增加，Zn06CoxFe2 关键词： 锌钴铁氧体 磁性 结构 相变 溶胶 凝胶     

钙钛矿锰氧化物La_(2/3)Sr_(1/3)Fe_xMn_(1-x)O_3的结构与磁性研究

本文利用溶胶-凝胶法制备了名义成分为La_(2/3)Sr_(1/3)Fe_xMn_(1-x)O_3(x=0.0,0.1,0.2,0.3,0.5)的系列样品,样品先后经过773,873,1073 K热处理,热处理时采用缓慢升温方式,X射线衍射分析表明,该系列样品均为单相钙钛矿结构,空间群为R3c,利用X'Pert HighScore Plus软件计算了样品的晶粒尺寸、晶格常数、晶胞体积及键长、键角,利用物理性能测量系统测量了样品的磁性,发现样品在10K的磁矩随掺杂量的增加而减小,但存在两个明显不同的变化区域:从x=0到x=0.2时,平均每个分子的磁矩从2.72μB迅速下降到0.33μB,居里温度从327 K下降到95 K,下降了232 K;而从x=0.2到x=0.5时,平均每个分子的磁矩从0.33μB缓慢下降到0.05μB,居里温度从95K下降到46K,只下降了49K,我们认为Fe与Mn离子磁矩反平行是样品磁矩随Fe掺杂量增加而下降的原因之一。     

Pr(Sr_(0.2)Ca_(0.8))_2Mn_2O_7纳米颗粒的磁性研究

采用溶胶-凝胶法成功制备了双层钙钛矿锰氧化物Pr(Sr0.2Ca0.8)2Mn2O7纳米颗粒样品,并研究了样品的相结构和显微形貌及样品的磁性.X射线衍射分析结果表明样品中没有出现明显的杂相,SEM分析晶粒平均尺寸约为35nm,EDS测得的样品原子百分比表明成分基本没有偏析,Scherrer公式计算晶粒平均尺寸与SEM测试结果相同约为35nm.在场冷(field cooling FC)和零场冷(zero field cooling ZFC)模式测得的磁化强度-温度(M~T)曲线上,没有观察到300K时电荷有序转变;通过不同温度下磁化强度-磁场强度(M~T)曲线可以清楚的看出,Pr(Sr0.2Ca0.8)2Mn2O7纳米样品在5K和77K时都表现出铁磁行为,表明样品中铁磁(ferromagnetic FM)团簇磁矩已经开始有序排列形成铁磁态.     

纳米结构Zn_xFe_(3-x)O_4-α-Fe_2O_3多晶材料中的巨隧道磁电阻效应

在具有纳米绝缘层的多晶锌铁氧体体系中 ,当晶界为α Fe2 O3纳米量级 ( 6— 7nm)的绝缘层时 ,则构成 (ZnxFe3-xO4 ) α Fe2 O3非均匀体 ,高分辨电子显微镜已证实了这种微结构 ,该体系在 0 .5T磁场、4 .2K温度下 ,磁电阻效应可达12 80 % ,3 0 0℃下为 15 8% .     

层状铁电体Ba_(1-x)Bi_(2+x)Ti_xNb_(2-x)O_9的结构相变研究

本文应用拉曼光谱方法研究了Ba1-xBi2+xTixNb2-xO9的结构相变。与x≠0的情况相比,x=0的情况BaBi2Bn2O9表现出了明确不同的拉曼光谱。前者有与Aurivillius层状铁电体家族的铁电相相似的拉曼光谱。因此认为BaBi2Nb2O9发生了铁电—非铁电相变。此外,用内模方法对层次铁电体Ba1-xBi2+xTixNb2-xO9的拉曼振动模式进行了初步的指认     

溶胶-凝胶法制备Ni_xZn_(1-x)S薄膜的磁性分析

由于离子掺杂可有效改善ZnS薄膜的特性,故本研究以溶胶-凝胶法制备Ni_xZn_(1-x)S薄膜(x=0.00, 0.05, 0.10, 0.15),并利用XRD、PL光谱及磁性测试仪分析Ni掺杂对其磁性的影响.研究结果表明Ni掺杂量x为0.00、0.05、0.10及0.15时薄膜的饱和磁化强度随分别为6.59×10~(-6) emu/cm~3、4.61×10~(-6) emu/cm~3、3.88×10~(-6) emu/cm~3及3.52×10~(-6) emu/cm~3,即饱和磁化强度随x增加而减小. PL分析表明缺陷发光强度随x增加而减弱,能隙发光强度则随之增强,结合束缚极化子理论便知饱和磁化强度会随x增加而减小. XRD分析表示结晶品质随x增加而变好,说明薄膜中的缺陷数量会随x增加而减少,使得磁信号无法通过缺陷方式传导而导致其磁性减弱.     

Co50Fe50-xSix合金的结构相变和磁性

利用实验测量和理论计算相结合的方法,研究了介于B2结构CoFe低有序合金和L21结构Co2FeSi高有序合金之间的Co50Fe50-xSix合金的结构相变、磁相变、分子磁矩和居里温度.采用考虑Coulomb相互作用的广义梯度近似（GGA＋U）方法计算了合金的能带结构.研究发现,合金出现较强的原子有序倾向,表现出较强的共价成相作用.合金的晶格常数、磁矩、居里温度随Si含量的增加而线性地降低,极限成分Co2FeSi合金的分子磁矩和居里温度分别达到5.92μB和777℃.原子尺寸效应导致合金晶格发生变化,但并未成为居里温度和分子磁矩变化的主导因素.分子磁矩的变化符合Slater-Pauling原理,但发现原子磁矩的变化并非线性,据此提出了共价成相对磁性影响的观点.采用Stearns理论解释了居里温度的变化趋势,排除了原子间距对居里温度的主导影响作用.能带计算的结果还表明,Co2FeSi作为半金属材料并非十分完美,可能在实际应用中会出现自旋极化率降低的问题.发现该系列合金的结构相变和磁相变随着成分的变化聚集在窄小的成分和温度范围内.     

化学合成的钯改性的NiFe2O4纳米颗粒的结构和磁性

采用溶胶-凝胶自动燃烧方法合成了镍铁-钯复合材料NiFe₂O₄-Pd的磁性纳米颗粒. 样品在800 ℃烧结6 h生成结晶相. X射线衍射证实样品呈尖晶石结构. 利用场发射扫描电子显微镜研究结构形态和纳米颗粒的大小. 饱和磁化强度在100和300 K时,随着钯含量增加达5%降低,但加入10%Pd时磁化强度突然上升.     

烧结温度、La掺杂对Bi_(1-x)La_xMnO_3结构及磁性能的影响

用溶胶-凝胶(so-lgel)法制备了多铁Bi1-xLaxMnO3(BLMO,0.1≤x≤0.4)系列样品.样品的结构表征(X-射线衍射,扫描电子显微镜)及差热-热重(TG-DTA)分析测量显示,形成稳定的BLMO钙钛矿相的烧结温度位于900~950℃.La掺杂对BLMO样品(950℃烧结)的结构和磁性能的影响也被仔细研究.结果显示,随着La掺杂减少,样品中BLMO钙钛矿相减弱,铁磁转变温度(TC)由53K降至41K,而饱和磁化强度经历了先降低再升高的变化.这可归因于La含量较少的样品中Bi空位浓度的增加诱导了Mn-O-Mn键角的减小和局域Mn4+离子的增多,使得Mn3+和Mn4+离子的铁磁超交换增强和Mn3+离子的dz2轨道有序受到局域破坏.     

溶胶凝胶法制备Ce_xPd_(1-x)O_(2-δ)纳米晶的结构表征及紫外拉曼光谱研究

通过溶胶凝胶法合成了Ce_xPd_(1-x)O_(2-δ)(x=1,0.7,0.5,0.3)系列纳米晶,X射线衍射(XRD)结果显示所得晶体为立方相。X射线光电子能谱(XPS)测试结果显示Pd的价态有Pd~(4+),Pd~(2+)及Pd0,其中Pd4+的出现说明形成了固溶体结构。结合高分辨透射电镜(HRTEM)、XRD和Raman光谱数据,发现掺杂物的物相中含有PdO。HRTEM谱图显示CeO_2表面分布有Pd单质,说明形成固溶体后高温导致晶格中的Pd析出。对系列化合物分别进行可见光拉曼谱(λ_(ex)=532nm)和紫外光拉曼谱(λ_(ex)=325nm)测试,并采用归一化法对比PdO的峰面积及CeO_2的峰面积,发现紫外光谱下CeO_2的F2g峰得到增强,同时还在593cm-1,1170cm-1,1750cm-1处出现三个峰,分别归为CeO_2本征纵向光学吸收LO(longitudinal optic),2LO和3LO,该现象由于共振拉曼效应导致的。结合紫外拉曼光谱,对不同比例Pd掺杂的CeO_2纳米晶中的氧缺位进行了量化研究。结果表明,随着Pd掺杂量的提高,氧缺位浓度逐渐增加,这与XPS测试结果的趋势基本一致。     

(Nd1－xErx)2Co15.5V1.5的结构转变与磁性

利用电弧熔炼制备了(Nd1-xErx)2Co15.5V1.5（x=0—1.0）化合物样品.通过x射线衍射分析和磁性测量研究了Er替代Nd2Co15.5V1.5中的Nd时对化合物结构和磁性的影响.研究结果表明，低Er含量（x<0.4），化合物为Th2Zn17型结构；高Er含量时(x>0.)，化合物转变为Th2Ni17结构；Er含量为x＝0.4和0.5时，两种结构共存.两种结构的晶胞参数a,c和晶胞体积V随着Er含量的增加都呈现递减的趋势.随着Er含量的增加，(Nd1-xErx)2Co15.5V1.5化合物的 关键词： (Nd1-xErx)2Co15.5V1.5 结构转变 磁性     

Effect of Magnetic Anisotropy on Magnetic Thermal Induction of Mn_(0.3)Zn_(0.3)Co_xFe_(2.4-x)O_4 Nanoparticles

Mn_(0.3)Zn_(0.3)Co_xFe_(2.4-x)O_4 series magnetic nanoparticles are prepared by the high-temperature organic solvent method, and Mn_(0.3)Zn_(0.3)Co_xFe_(2.4-x)O_4@SiO_2 composite nanoparticles are prepared by the reverse microemulsion method. The as-prepared samples are characterized, and the results show that the magnetic anisotropy constant of nanoparticles increases with the cobalt content, and the magnetic thermal induction shows a trend of increasing first and then decreasing. The optimal magnetic thermal induction is obtained at x = 0.12 with a specific loss power of 2086 w/gmetal, which is a bright prospect in clinical magnetic hyperthermia.     

(Nd_(1-x)Er_x)_2Co_(15.5)V_(1.5)的结构转变与磁性

利用电弧熔炼制备了 (Nd1 xErx) 2 Co1 5 5V1 5(x=0— 1 0 )化合物样品 .通过x射线衍射分析和磁性测量研究了Er替代Nd2 Co1 5 5V1 5中的Nd时对化合物结构和磁性的影响 .研究结果表明 ,低Er含量 (x <0 4 ) ,化合物为Th2 Zn1 7型结构 ;高Er含量时 (x >0 5 ) ,化合物转变为Th2 Ni1 7结构 ;Er含量为x =0 4和 0 5时 ,两种结构共存 .两种结构的晶胞参数a ,c和晶胞体积V随着Er含量的增加都呈现递减的趋势 .随着Er含量的增加 ,(Nd1 xErx) 2 Co1 5 5V1 5化合物的居里温度和饱和磁化强度都单调下降 .(Nd1 xErx) 2 Co1 5 5V1 5化合物的室温各向异性由低Er含量时的易锥型转变为高Er含量时的易轴型 .x =0— 0 5的化合物在温度升高时发生自旋重取向转变 ,自旋重取向温度Tsr随Er含量的增加而减小     

Enhanced hyperthermia performance in hard-soft magnetic mixed Zn0.5CoxFe2.5−xO4/SiO2 composite magnetic nanoparticles

High quality Zn0.5CoxFe2.5?xO4(x=0,0.05,0.1,0.15)serial magnetic nanoparticles with single cubic structures were prepared by the modified thermal decomposition method,and Zn0.5CoxFe2.5?xO4/SiO2 composite magnetic nanoparticles were prepared by surface modification of SiO2.The magnetic anisotropy of the sample increases with the increase of the doping amount of Co2+.When the doping amount is 0.1,the sample shows the transition from superparamagnetism to ferrimagnetism at room temperature.In the Zn0.5CoxFe2.5?xO4/SiO2 serial samples,the maximum value of specific loss power(SLP)with 1974 W/gmetal can also be found at doping amount of x=0.1.The composite nanoparticles are expected to be an excellent candidate for clinical magnetic hyperthermia.     

Structural and magnetic properties of turmeric functionalized CoFe_2O_4 nanocomposite powder

The structural and magnetic properties of the synthesized pure and functionalized CoFe_2O_4 magnetic nanoparticles(NPs) are studied by analyzing the results from the x-ray diffraction(XRD), transmission electron microscopy(TEM), FT–IR spectroscopy, thermogravimetry(TG), and vibrating sample magnetometer(VSM). To extract the structure and lattice parameters from the XRD analysis results, we first apply the pseudo-Voigt model function to the experimental data obtained from XRD analysis and then the Rietveld algorithm is used in order to optimize the model function to estimate the true intensity values. Our simulated intensities are in good agreement with the experimental peaks, therefore, all structural parameters such as crystallite size and lattice constant are achieved through this simulation. Magnetic analysis reveals that the synthesized functionalized NPs have a saturation magnetization almost equal to that of pure nanoparticles(PNPs). It is also found that the presence of the turmeric causes a small reduction in coercivity of the functionalized NPs in comparison with PNP. Our TGA and FTIR results show that the turmeric is bonded very well to the surface of the NPs. So it can be inferred that a nancomposite(NC) powder of turmeric and nanoparticles is produced. As an application, the anti-arsenic characteristic of turmeric makes the synthesized functionalized NPs or NC powder a good candidate for arsenic removal from polluted industrial waste water.     

Photoinduced phase transition accompanied with the changes in magnetic properties

Recently, many studies have been started in search for materials which show a photoinduced phase transition (PIPT). In this work, we review two systems as typical examples of PIPT accompanied with changes in magnetic characteristics; (1) organo-metal complex [Fe(2-pic)₃]Cl₂ EtOH (2-pic = 2-amino-methyl-pyridine) and (2) III-V based magnetic semiconductors (In_1-x , Mn _x )As. In the former case, we show several nonlinear characteristics in dynamical process of photoinduced spin state transition from low-spin to high-spin states. In the latter one, photocarrier-induced ferromagnetic order has been observed by both magnetic and transport measurements.     

Crystal structures,phase relationships,and magnetic phase transitions of R_5M_4 compounds (R = rare earths,M = Si,Ge)

Our recent studies of the crystal structures, phase transitions, and magnetic properties of intermetallic compounds R5M4 (R = rare earths; M = Si, Ge) are reviewed briefly. First, crystal structures, phase relationships, and magnetic properties of several 5:4 compounds, including Nd5Si4xGex , Pr5Si4xGex, Gd5xLaxGe4,La5Si4, and Gd5Sn4 , are presented. In particular, the canted spin structures as well as the magnetic phase transitions in Pr5Si2Ge2 and Pr 5 Ge 4 investigated by neutron powder diffractions and small-angle neutron scattering are reviewed. Second, the crystal structures and magnetic properties of the most studied compounds Gd5(Si,Ge)4 are summarized. The focus is on the parent compound Gd5Ge4 , which is an amazing material exhibiting magnetic anisotropy, angular dependent spin-flop transition, metastable magnetic response, Griffiths-like phase, thermal effect under pulsed fields, antiferromagnetic and ferromagnetic resonances, pronounced effects of impurities, and high-field induced magnetic transitions.     

Effects of Mg substitution on the structural and magnetic properties of Co_(0.5)Ni_(0.5-x)Mg_xFe_2O_4 nanoparticle ferrites

In this study, nanocrystalline Co–Ni–Mg ferrite powders with composition Co_(0.5)Ni_(0.5-x)Mg_xFe_2O_4 are successfully synthesized by the co-precipitation method. A systematic investigation on the structural, morphological and magnetic properties of un-doped and Mg-doped Co–Ni ferrite nanoparticles is carried out. The prepared samples are characterized using x-ray diffraction(XRD) analysis, Fourier transform infrared spectroscopy(FTIR), field emission scanning electron microscopy(FESEM), and vibrating sample magnetometry(VSM). The XRD analyses of the synthesized samples confirm the formation of single-phase cubic spinel structures with crystallite sizes in a range of ~ 32 nm to ~ 36 nm. The lattice constant increases with increasing Mg content. FESEM images show that the synthesized samples are homogeneous with a uniformly distributed grain. The results of IR spectroscopy analysis indicate the formation of functional groups of spinel ferrite in the co-precipitation process. By increasing Mg2+substitution, room temperature magnetic measurement shows that maximum magnetization and coercivity increase from ~ 57.35 emu/g to~ 61.49 emu/g and ~ 603.26 Oe to~ 684.11 Oe(1 Oe = 79.5775 A·m-1), respectively. The higher values of magnetization Ms and Mr suggest that the optimum composition is Co_(0.5)N_(i0.4)Mg_(0.1)Fe_2O_4 that can be applied to high-density recording media and microwave devices.