非晶态(Fe1-xVx)84B16合金的磁性和电性

用单辊急冷法制备了非晶态(Fe_1-xV_x)₈₄B₁₆(x=0,0.02,0.04,0.06,0.10)合金的薄带,分别用磁天平和四端引线法测量了饱和磁化强度和高温电阻率的温度关系。得到平均每个磁性原子的磁矩随V含量的增加近似线性下降,计算出每个Fe原子和每个V原子的平均磁矩分别为2.08μ_B和-5.08μ_B。居里温度T_c从x=0时的622K下降到x=0.10时的478K。利用自旋波激发公式:σ(T)=σ(0)(1-BT^* 关键词：     

La_(0.67)Ba_(0.33)Mn_(1–x)Zn_xO_3的磁性和电输运性质北大核心CSCD

采用传统固相反应法制备了La0.67Ba0.33Mn1–x Znx O3(0≤x≤0.2)多晶样品,系统研究了Zn掺杂对于多晶样品的结构,磁性和电输运性质的影响.XRD衍射表明样品均具有单一的立方钙钛矿结构.在外加磁场(H=1000Oe)环境中测得的磁化强度温度(M^T)曲线表明,在5~350K的温区内所有样品均发生了顺磁相(PM)到铁磁相(FM)的转变.样品的居里温度(TC)和磁化强度随着Zn的掺杂量的增加呈现下降的趋势,当x=0.1时,样品的TC和磁化强度与未掺杂的样品相比下降的幅度不大.但是当x=0.2时,样品的TC和磁化强度都发生明显的下降.从零场(H=0T)和外加磁场(H=2T)下测得的电阻温度曲线可见,样品在测量的温区范围内均发生绝缘相到金属相的转变.随着掺杂量的增加绝缘-金属相转变温度(TIM)向低温区移动,但是样品的电阻逐渐增大.所有样品在TIM附近呈现均出现磁电阻(MR)峰,随着Zn的掺杂量的增加MR值由x=0时的-22%(T=314.5K)增加到x=0.2时的-73%(T=80K),且样品的磁电阻温区被明显拓宽.     

Ru掺杂La0.7Ca0.2Ba0.1Mn1-xRuxO3的磁性和输运性质

利用固相反应法制备了Ru掺杂La0.7Ca0.2Ba0.1Mn1-xRuxO3(x=0～0.06)的多晶样品,探讨了Ru掺杂对体系结构,输运性质以及磁电阻的影响.多晶X射线衍射证实所有样品均保持简单立方钙钛矿结构.通过零场冷却(ZFC)和加场冷却(FC)下的磁化曲线的测量发现随温度降低样品发生了顺磁(PM)到铁磁(FM)的相变,且样品的居里温度(Tc)随Ru掺杂发生了显著的变化,从x=0.00时的306.7K,下降到x=0.02时的294.3K,紧接着又上升到x=0.04时的302.4K.测得居里温度明显高于La0.7Ca0.2Ba0.1Mn1-xMoxO3体系,而且其磁性也大为增强.由零场和外加磁场H=1T测量得到样品的ρ～T曲线表明随温度降低样品同时发生了从绝缘体到金属的转变,绝缘体-金属转变温度低于相应的居里温度.适量的Ru掺杂降低了样品的电阻率,增强了低温时的磁电阻.     

非晶态(Fe_(1-x)V_x)_(84)B_(16)合金的磁性和电性

用单辊急冷法制备了非晶态(Fe_(1-x)V_x)_(84)B_(16)(x=0,0.02,0.04,0.06,0.10)合金的薄带,分别用磁天平和四端引线法测量了饱和磁化强度和高温电阻率的温度关系。得到平均每个磁性原子的磁矩随V含量的增加近似线性下降,计算出每个Fe原子和每个V原子的平均磁矩分别为2.08μ_B和-5.08μ_B。居里温度T_c从x=0时的622K下降到x=0.10时的478K。利用自旋波激发公式:σ(T)=σ(0)(1-BT~(3/2)-CT~(5/2))得到,自旋波劲度系数D在75.4-81.8(meV·)之间(x=0-0.10),交换相互作用范围的平方平均值〈r~2〉从x=0.02时的4.4增加到x=0.10时的6.5。电阻率的测量得到,室温电阻率在155-127(μQ·cm)之间,晶化过程中电阻率的下降幅度随V含量增加而线性减小,其原因与晶化过程中的相变有关。     

Mo掺杂La_(0.7)Ca_(0.2)Ba_(0.1)Mn_(1-x)Mo_xO_3体系的磁电性质

本文采用固相反应法制备了高价态离子Mo掺杂的La0.7Ca0.2Ba0.1Mn1-xMoxO3(x=0,0.01,…,0.06)多晶样品,研究了Mo掺杂对样品的结构、磁性和磁电阻的影响.X射线衍射谱证实所有样品均为具有正交对称性的钙钛矿结构.零场冷却(ZFC)和加场冷却(FCH=0.01T)下其磁化～温度(M～T)曲线的测量表明样品随温度降低发生了从顺磁(PM)到铁磁(FM)的相变,T相似文献   

钙钛矿锰氧化物Lao.8-x Eux Sro.2MnO3(x=0,0.05)的磁性和磁熵变研究

本篇文章主要研究钙钛矿氧化物La_(0.8-x)Eu_xSr_(0.2)MnO_3(x=0,0.05)中A位掺杂铕(Eu)后对样品的磁性和磁熵变的影响.采用传统的固相反应法制备多晶样品,根据数据拟合得到XRD图像和晶格参数,通过对两样品的M-T曲线和M-H曲线研究发现:x=0和x=0.05两样品在高温区均表现出顺磁性,居里温度T_c分别为283 K(x=0)和284 K(x=0.05),且在居里温度附近表现出铁磁性.随着掺杂量增加,样品的居里外斯温度降低(θ_(x=0)=322 K、θ_(x=0.05)=304 K),表明Eu~(3+)掺杂改变了系统内的铁磁耦合.在7 T磁场下磁熵变的最大值分别为2.73 J/kg·K和4.19 J/kg·K,表明Eu~(3+)掺杂使得最大磁熵变值增大.对比制冷效率,发现该系列样品具有作为磁制冷材料的潜质.     

Co掺杂对Mn_3Sn_(1-x)Co_xC_(1.1)化合物的磁性质、熵变以及磁卡效应的影响

利用固态反应法制备了Mn3Sn1-xCoxC1.1(x=0.05,0.1,0.2)系列化合物,研究了Co掺杂对其磁性质、相变、熵变的影响.随着Co掺杂量的增加,样品的居里温度由283 K先降到212 K(Mn3Sn0.9Co0.1C1.1)后又升到332 K(Mn3Sn0.2Co0.8C1.1),相变类型由一级相变逐渐转变为二级相变.增大Co的掺杂量,Mn3Sn1-xCoxC1.1化合物的熵变峰值逐渐减小,磁熵变温区由9 K展宽到300 K.当Co掺杂量为0.2时,相对制冷量达到最高,为103 J/kg(磁场强度为1.6 MA/m).由于室温附近良好的磁致冷效应,该类材料在磁制冷领域可能具有重要的应用前景.     

非晶态(Fe_(1-x)Nb_x)_(84.5)B_(15.5)合金低温下的磁性和自旋波激发

非晶态(Fe_(1-x)Nb_x)_(34.5)B_(15.5)(0≤x≤0.1)合金是用单辊急冷技术制备的。用提拉法和磁天平测量了磁化强度与温度以及磁场的关系。推出OK时的自发磁化强度σ(0)随Nb含量的增加近似线性下降,计算出每个Fe原子和每个Nb原子的平均磁矩分别为2.05μB和-2.57μB。在室温以下,磁化强度的温度关系较好地与自旋波激发公式σ(T)/σ(0)=1—BT~(3/2)-CT~(5/2)-…相符,得到自旋波劲度系数D从x=0时的71.3 mev·A~2下降到x=0.1时的59.8 mev·A~2,而D与居里温度的比值D/Tc随成分变化很小。当x从0增加到0.1时,交换相互作用范围的平方平均值〈r~2〉在11.8A~2—13.6A~2之间。     

钙钛矿La0.8Ca0.2MnO3多晶样品的制备及低温磁学特性

我们利用固相反应法制备了粉末状La0.8Ca0.2MnO3样品,其空间群为pnma,样品中存在超顺磁性粒子,其截止态和超顺磁态的转变温度为185K,从dσ/dT的负峰得到铁磁-顺磁相变居里温度为210K,在顺磁领域线性拟合而得到顺磁居里温度为216.4K,分子式有效磁矩为6.25μB,低温领域磁化曲线服从布洛赫T32定律,其自旋波劲度系数为49.2meV2.     

非晶态Fe_(13)Ni_(67.2)P_(4.5)B_(15.3)合金的临界现象

本文报道非晶态Fe_(13)Ni_(67.2)P_(4.5)B_(15.3)合金的磁化强度与温度和磁场关系的测量结果。在居里温度附近样品的磁特性符合二级相变规律,得到临界指数β=0.39±0.02,γ=1.56±0.06,δ=5.20±0.1,样品的居里温度T_c=(180.4±0.2)K。在实验误差范围内,临界指数β,γ,δ满足γ=β(δ-1)关系,在168—192K温度范围,实验数据满足二级相变的磁状态方程。当T>270K时,样品顺磁磁化率服从居里-外斯定律,由居里-外斯常数c计算出有效顺磁磁矩 P_(eff)=3.19μ_B。     

Co含量对Bi6Fe2-xCoxTi3O18样品多铁性的影响

用固相工艺制备了Bi₆Fe_2-xCo_xTi₃O₁₈ (BFCT-x, x=0, 0.2, 0.6, 0.8, 1.0, 1.2, 1.6, 1.8, 和2.0)多铁陶瓷样品, 样品X射线谱分析发现, 随着Co含量的增加, 样品晶格常数出现了先增大后减小的变化. 室温下, BFCT-0.6样品呈现出相对较高的饱和磁化强度, 2M_s约为4.49 emu/g, BFCT-1.0具有最高的剩余磁化强度, 2M_r约为0.89 emu/g. Co含量在0.2 ≤x≤qslant 1.2范围内, 随着Co含量的增加样品顺磁–铁磁相变温度从752 K降至372 K. 小量的Co改善了样品的铁电性能, 当x=0.6时样品样品的铁电性能最佳, 随着含量增大样品铁电性能下降, 但当x >1.2时样品的铁电性能又得到了改善.     

Crystal and magnetic structure of the sulfur spinels Cu0.45Co0.55Cr2S4 - xSex

The magnetic and crystal structures of the metallic sulfospinels Cu_0.45Co_0.55Cr₂S_{4 - x}Se_x have been investigated for x = 0, 0.42 and 1.0 by neutron powder diffraction techniques. The data have been analyzed by the Rietveld method. All three compositions show ferrimagnetism at low temperatures with a chromium moment of (2.7±0.1)μ_B and a cobalt moment of (2.8±0.1)μ_B. The Curie temperature varies from 293 to 253 K.     

Magnetic properties and magnetocaloric effect of the Cr-based spinel sulfides Co_(1-x)Cu_xCr_2S_4

Crystallographic structure, magnetic properties, and magnetic entropy change of the Cr-based spinel sulfides Co_(1-x)Cu_xCr_2S_4(x = 0–0.8) have been investigated. All these compounds crystallize into the cubic spinel structure, the Cu substitution shrinks linearly the lattice constant at a ratio of 0.0223 per Cu atom in the unit cell, and enhances linearly the Curie temperature and the spontaneous magnetization at the rates of 18K and 0.33 μB/f.u. per Cu atom in the unit cell,respectively. All these compounds show a typical behavior of second order magnetic transition, and a room temperature magnetic entropy change of 2.57 J/kg·K is achieved for Co_(0.4)Cu_(0.6)Cr_2S_4.     

MoSi2薄膜电子性质的第一性原理研究

采用第一性原理计算方法, 研究了四方MoSi₂薄膜的电子性质. 计算结果表明, 各种厚度的薄膜都是金属性的, 并且随着厚度的增加, 其态密度与能带结构都逐渐趋近于MoSi₂块体的特性. 通过对MoSi₂薄膜磁性的分析, 发现三个原子层厚的薄膜具有磁性, 其原胞净磁矩为0.33 μ_B; 而当薄膜的厚度大于三个原子层时, 薄膜不具有磁性. 此外, 进一步对单侧加氢饱和以及双侧加氢饱和结构下三原子层MoSi₂薄膜的电子性质进行了研究, 发现单侧加氢饱和的三原子层MoSi₂薄膜具有磁性, 其原胞净磁矩为0.26 μ_B, 而双侧加氢饱和三原子层MoSi₂薄膜是非磁性的. 双侧未饱和与单侧加氢饱和的三原子层MoSi₂薄膜的自旋极化率分别为30%和33%. 这些研究结果表明, 三原子层厚的MoSi₂ 超薄薄膜在悬空或者生长于基底之上时具有金属磁性, 预示着它在纳米电子学和自旋电子学器件等方面都有潜在的应用前景.     

Neutron diffraction study of magnetic ordering in ErMn2Si2, ErMn2Ge2 and ErFe2Si2

Neutron diffraction study of polycrystalline compounds ErMn₂Si₂, ErMn₂Ge₂ and ErFe₂Si₂ was performed in the temperature range between 1.8 and 293 K. All compounds have tetragonal, ThCr₂Si₂-type crystal structure. The antiferromagnetic collinear structure of ErMn₂Si₂ and ErMn₂Ge₂ at both RT and LNT, consists of a sequence + - + - of ferromagnetic layers of Mn atoms. The magnetic moment of an Mn atom (≈2μ_B) is parallel to the c-axist. At low temperatures (LHT and lower), the ferromagnetic ordering within the Er sublattice is observed. The magnetic moment (μ_Er ≈ 9μ_B) is perpendicular to the c-axis. From the temperature dependence of the intensities of the magnetic peaks, the following values for the Curie temperatures were obtained: (10±5) K for ErMn₂Si₂ and (8.5±3) K for ErMn₂Ge₂. For ErFe₂Si₂ a collinear antiferromagnetic structure of the + - - + type was found, the magnetic unit cell consisting of the chemical one, doubled along the c-axis.     

Pr2(Fe0.8Co0.2)14B磁结构的中子衍射研究

本文报道用中子衍射测定的含硼稀土过渡族金属间化合物Pr₂(Fe_0.8Co_0.2)₁₄B的晶体结构与磁结构。将中子三轴谱仪用作二轴粉末衍射仪,在室温测该化合物粉末样品的中子衍射强度,用轮廓精化法弥合衍射数据。该化合物属Nd₂Fe₁₄B类四方结构,α=8.8110?,c=12.2307?。设Pr,Fe和Co原子磁矩间为铁磁耦合,同一晶位的Fe,Co原子磁矩相等,存在沿c轴的易磁化 关键词：     

Magnetic moments and Fe hyperfine field interactions in Y(Fe1−xRux)2 ternaries

Measurements of magnetization and ⁵⁷Fe Mössbauer spectra have been made for Y(Fe_1−xRu_x)₂. The C15 type cubic structure is stabilized for xx 0.7. The C15 compounds is ferromagnetic with T_c200 K and its saturation moment decreases monotonically with increasing x, while the ⁵⁷Fe hyperfine field decreases only slightly with x. From these results, it is deduced that the Ru atoms have an induced moment of ≈1μ_B in the range x 0.2. In the C14 type phase, no magnetic ordering develops even at 4.2 K.     

Direct measurement of the magnetocaloric effect in La0.67Ca0.33MnO3

Polycrystalline perovskite La_0.67Ca_0.33MnO₃ was synthesized by a sol–gel method. Its adiabatic temperature change ΔT_ad induced by a magnetic field change was measured directly. At 268 K, near its Curie temperature T_C, ΔT_ad of La_0.67Ca_0.33MnO₃ induced by a magnetic field change of 2.02 T reaches 2.4 K. The latent heat Q and magnetic entropy change −ΔS_M induced by a magnetic field change were calculated from the temperature dependence of ΔT_ad and zero-field heat capacity C_p. The maximum values of Q and −ΔS_M in La_0.67Ca_0.33MnO₃ induced by a magnetic field change of 2.02 T are 1.85 J g⁻¹ and 6.9 J kg⁻¹ K⁻¹, respectively. The former is larger than the phase transition latent heat of heating or cooling, which is about 1.70 J g⁻¹.     

Preparation and structural study of LaMnO3 magnetic material

We report the crystallographic parameters of LaMnO₃ obtained from X-ray diffraction data and electronic properties predictions using the density functional theory (DFT). LaMnO₃ was prepared by the citrate precursor method (CPM). The initial solution was 0.1 M of each cation and the citrate nitrate relation was one. The solution was dried at 373 K; the yielded foam was annealed at 873 K and then was characterized by X-ray diffraction. Diffraction peaks show that the space group is R-3c (#167) with a=b =5.523 Å and c=13.324 Å (rhombohedrally distorted perovskite). Structural results of the Rietveld method have a matching of 97% with that obtained from the Structure Prediction Diagnostic Software. DFT calculation reveals a half-metallic character and its magnetic moment is about 2.0 μ_B.