Y(TiFe)12的中子衍射研究

用中子衍射研究了Y(TiFe)₁₂的晶体结构及其磁的特性。观测到Y(TiFe)₁₂为ThMn₁₂型结构,空间群为14/mmm,Fe和Ti分布在三个不等效的晶位上,且Fe和Ti分别择优占据某些晶位。对所得结果进行了初步讨论。 关键词：     

新型金属间化合物R_2Fe_(17)N_(2.4)的结构与磁性

本文采用适当的热处理,使氮原子进入到R_2Fe_(17)的结构中去.利用X射线衍射、磁测量和中子衍射技术研究了R_2Fe_(17)N_(24)的晶体结构和内禀磁性及其之间的联系.中子衍射研究结果表明,氮原子在Th_2Zn_(17)型菱方结构中,占据9e间隙位置.氮的加入使晶胞体积增大、Curie温度升高;使铁原子3d电子正负能带电子数目差额扩大、饱和磁矩增强;并且氮原子对稀土晶位的晶场效应有重大影响,导致Sm_2Fe_(17)N_(24)具有易磁化轴.所有这些效应使得Sm_2Fe_(17)N_(24)具备了研制高矫顽力永磁体的内禀性能.     

同步辐射异常散射研究超薄金属多层膜

近些年来,巨磁电阻金属多层膜由于其在信息存储和其它传感器方面的应用而广受关注.但是,由于金属多层膜中每层厚度都很薄,界面及层内微结构研究很困难.本文介绍利用同步辐射异常散射技术和反射技术相结合,研究超薄金属多层膜中元素分布的原理,及其在不同系统中的应用.     

CRYSTALLOGRAPHIC STRUCTURE AND MAGNETIC PROPERTIES OF R_(2)Fe_(17)N_(2.4)

By a proper thermal treatment, the nitrogen atoms can enter the R2Fe17 structure. The crystallographic and intrinsic magnetic properties as well as their relationship have been studied by magnetic measurements, X-ray and neutron diffraction techniques. The neutron data indicate that the nitrogen atoms occupy the interstitial sites in the Th2Zn17-type rhom-bohedral structure. The inserting nitrogen atoms are found to dilate the cell volume, increase the Curie temperature and enhance the saturation moment by raising the difference in the electron number between the spin-up and spin-down 3d subbands of the Fe atoms. Furthermore, the nitrogen atoms have an important effect on the magnetocrystallic anisotropy, which results in an easy axis with Sm2Fe17N2.4. All these make Sm2Fe17N2.4 favorable for permanent magnet applications.     

低温生长的Ge/Si超晶格界面结构的X射线散射研究

低温下用MBE方法生长了Ge/Si超晶格,X射线反射及横向散射研究表明,Ge亚层上下表面的粗糙度呈反对称,下表面大的粗糙度来源于Ge向Si亚层中扩散形成SiGe混合组分结构,这种组分结构可以用一平均成分的SiGe合金层加以拟合,从而使得各亚层均有一个合理的粗糙度,旋转样品进行的X射线散射研究表明,这种SiGe的混合是各向同性的,这与透射电子显微镜的研究结构相一致.     

CRYSTALLOGRAPHIC STRUCTURE AND INTRINSIC MAGENTIC PROPERTIES OF R2Fe14BNx

We found that the nitrogen atoms can enter into the R₂Fe₁₄B structure by a proper heat treatment in nitrogen atmosphere. The crystallographic structure and magnetic properties of R₂Fe₁₄BN_x, R =Nd and Y, have been investigated by using X-ray and neutron diffraction techniques as well as magnetic measurements. The neutron diffrac-tion data show that the nitrogen atoms occupy the 4f interstices. The interstitial nitrogen atoms were found to have an effect of enhancing Curie temerature, whereas, decreasing saturation magnetization and magneto-crystalline anisotropy. The rela-tionship of the crystal structure and the intrinsic magnetic properties of this crystal is discussed.     

CRYSTALLOGRAPHIC STRUCTURE AND INTRINSIC MAGENTIC PROPERTIES OF R2Fe14BNx

We found that the nitrogen atoms can enter into the R₂Fe₁₄B structure by a proper heat treatment in nitrogen atmosphere. The crystallographic structure and magnetic properties of R₂Fe₁₄BN_x, R =Nd and Y, have been investigated by using X-ray and neutron diffraction techniques as well as magnetic measurements. The neutron diffrac-tion data show that the nitrogen atoms occupy the 4f interstices. The interstitial nitrogen atoms were found to have an effect of enhancing Curie temerature, whereas, decreasing saturation magnetization and magneto-crystalline anisotropy. The rela-tionship of the crystal structure and the intrinsic magnetic properties of this crystal is discussed.     

YBa_2(Cu_(0.95)M_(0.05))_3O_(7-δ)的代换效应及其中子衍射研究

X射线衍射实验表明YBa_2(Cu_(0.95)M_(0.05))_3O_(7-δ)(M=Ti,V,Cr,Mn,Fe,Co,Ni,Cu和Zn)均为单相结构。Fe,Co,Ni和Zn对Cu的替代使超导临界温度T_c显著下降,而同样含量的Ti,V,Cr,Mn对Cu的替代并未对超导性能产生显著影响。并利用中子衍射分析了Ti,Mn,Fe和Co对Cu原子的取代,发现代换原子对Cu的两个晶位各自存在不同的择优占据,从而为分析不同晶位Cu在超导机制中的作用提供了依据。同时,本文研究了YBa_2·(Cu_(0.95)M_(0.05))_3O_(7-δ)的磁性,讨论了用3d金属离子代换Cu离子时对磁性的影响,以及磁性与超导性能之间的联系。     

Y_2(Fe_(1-x)Si_x)_(14)B的中子衍射研究

Nd_2Fe_(14)B是一种磁能积很高的优良的永磁材料,但在实用上稍嫌它的居里温度低了一点。为了提高它的居里温度,人们曾用某些元素替代其中的一些铁作了尝试。文献[9]及我们最近的实验表明:用硅代替部分铁之后,材料的居里点都获得了提高。本文用中子衍射法研究了Si在Y_2Fe_(14)B中的占位情况,以了解Si对磁性能产生的影响。中子衍射的结果表明:Si择优地占据c,j_1及k_2晶位。最后,用磁交换作用对结果进行了讨论。     

YBa2(Cu0.95M0.05)3O7-δ的代换效应及其中子衍射研究

X射线衍射实验表明YBa₂(Cu_0.95M_0.05)₃O_7-δ(M=Ti,V,Cr,Mn,Fe,Co,Ni,Cu和Zn)均为单相结构。Fe,Co,Ni和Zn对Cu的替代使超导临界温度T_c显著下降,而同样含量的Ti,V,Cr,Mn对Cu的替代并未对超导性能产生显著影响。并利用中子衍射分析了Ti,Mn,Fe和Co对Cu原子的取代,发现代换原子对Cu的两个晶位各自存在不同的择优占据 关键词：