Composites of nanotubular polyaniline containing Fe3O4 nanoparticles

Results of charge-transport and magnetic measurements of nanotubular polyaniline (PANI) composites containing Fe_3O_4 nanoparticles (～10nm) synthesized by a "template-free" method are reported. The T^{-1/2} resistivity has been observed, and dc magnetic susceptibility data are fitted to an equation χ=χ^*_P+C/T. With increasing weight ratio of Fe_3O_4, the electrical conductivity and temperature- independent susceptibility χ^*_P increase, and the Curie-type susceptibility is suppressed at low temperatures. Further discussions have been given. The PANI-H_3PO_4/Fe_3O_4 composite containing 27wt% of Fe_3O_4 nanoparticles is superparamagnetic, exhibiting very little hysteresis even at 5K.     

简单的方法制备°-Fe2O3纳米粒子及其磁性质和电化学性质

报道了制备磁性Fe2O3纳米粒子的一种简单易行的方法．利用部分还原共沉淀法， 以Na2S2O4作为还原剂， 用FeCl3先制备出Fe2O3纳米微粒， 再在空气中直接煅烧， 成功地制备出粒径较均匀(约13 nm)的磁性Fe2O3微粒． 实验发现Na2S2O4在部分还原共沉淀法中起到了去氧剂兼还原剂的特殊作用．研究表明， 样品在室温下具有铁磁性， 其饱和磁化强度和矫顽力分别为70 emu/g和164 Oe； 产物具有好的电化学性质，在3.0?0.3 V(相对于金属锂)、0.2 mA/cm2时，样品的首次放电容量可达到933 mAh/g．同时还讨论了放电过程中金属锂与Fe2O3的反应机理．     

磁性掺杂技术：让OLED效率提高30％

Oak Ridge国家实验室（ORNL）声称，通过向OLED中掺杂磁纳米粒子，可使OLED的效率提高30％。作为回报，把磁性材料引入OLED之中，将使亮度得到控制，而不必附加电接触。     

感温磁性材料及其应用

磁性材料的磁感应强度B随着温度的变化而强烈的变化——线性的或陡峭的变化,具有这种特性的材料称之感温磁性材料。 该类磁性材料的居里点温度都很低,一般都低于160℃,在100 Oe的磁场强度下磁化,随着温度的升高,磁感应强度B值将以30-60Gs/℃线性规律下降或在某一温度点(在120℃以内)磁感应强度B值将以150-2000Gs/℃的速度陡然下降至近于零。     

Experimental and theoretical study of the nonlinear response of agiant magnetostrictive rod

In this paper, a magnetomechanical coupling constitutive relation of the giant magnetostrictive material was investigated experimentally and theoretically. A grain-oriented magnetostrictive rod of iron and rare earth was tested under a combined magnetomechanical loading. Two types of experimental curves were obtained, i.e., the magnetostrictive curve of the extensional strain vs the magnetic field, and the curve of the magnetic polarization intensity vs the pre-stress. A new theoretical constitutive model, based on the density of domain switching, is developed. Comparison of the theoretical predictions with the experimental results indicates that this model can capture the main characteristics of the magnetoelastic coupling deformation of a giant magnetostrictive rod. The project supported by the National Natural Science Foundation of China (10025209, 10132010, 10102007)