摘要
以金属盐及柠檬酸为原料,采用溶胶–凝胶法制备了尖晶石氧化物Co_(2-x)Mn_(1+x)O_4和Co_(2-x)Fe_xMnO_4系列,通过XRD、FT-IR及PPMS等手段研究了Co_2MnO_4及系列掺杂样品的成相、结构、磁性等特征。结果表明,Co_(2-x)Mn_(1+x)O_4系列在x<0.6时,呈单相立方结构,晶格常数和磁性随着Mn掺杂量的增加而增大,x≥0.6时逐渐向四方结构转化,磁性下降,并呈现磁化强度不易饱和的特征;Co_(2-x)Fe_xMnO_4系列样品在x<1.75成分范围内均可保持立方结构,且晶格常数和磁性都随着x增大而提高。这些变化主要是由于掺杂原子尺度及磁矩均大于原有元素,掺杂后样品内部的磁性相互作用有所增强。
Spinel solid solution Co2.xMnl+xO4 and C02.xFexMnO4 were synthesized by Sol-Gel method using metal ni- trates and citric acid as the starting materials. Crystalline phases, structure and magnetic properties of the C02MnO4 doped with different concentrations of Fe and Mn were investigated by XRD, FT-IR and PPMS, respectively. Results show that C02-xMnl-xO4 series are single-phase cubic spinel structure at x〈0.6, the lattice parameter as well as the satu- ration magnetization are found to be increasing with the Mn content increasing. Co2-xMnl+xO4 series transform to tetragonal structure gradually at x≥0.6, which result in the decline of magnetic properties and difficulty of reaching satuation. Co2_xFexMnO4 samples have cubic spinel structure at x〈1.75, the lattice parameter and magnetic increase with the increase of Fe-substitution. When the Fe content increases to 1.75, Fe203 phase is formed in the sample. The changes of performance are mainly due to the larger atom radius of the doping atoms (Fe or Mn) as compared to that of Co. And magnetic moment is another important factor to the performance change. The first-principles calculation results show that the magnetic moments of Fe and Mn are larger than that of Co. As a result, the interatomic magnetic interaction is enhanced by doping.
出处
《无机材料学报》
SCIE
EI
CAS
CSCD
北大核心
2017年第6期609-614,共6页
Journal of Inorganic Materials
基金
国家自然科学基金(51371075
51501054
51471184)~~
关键词
尖晶石氧化物
晶体结构
磁性耦合
spinel-type oxide
crystal structure
magnetic coupling
