1) composite Li-ferrite
复合锂铁氧体
2) Li-ferrite
锂铁氧体
1.
The Cu-Ti co-metal wave-guide films on Li-ferrite material surface were made by a magnetron sputtering deposition.
采用磁控溅射镀膜方法,在锂铁氧体材料表面,制备了Cu-Ti复合金属波导膜系。
2.
The calculated results showed that the effective magnetic anisotropy constants of ultrafine particles were larger than the magnetocrystalline anisotropy constant of Li-ferrite.
结果发现,有效磁各向异性常数随粒度的减小而增大,微粉的有效磁各向异性常数大于锂铁氧体的磁晶各向异性常
3) lithium ferrite
锂铁氧体
1.
Influence of Dy_2O_3 Dopant on Microwave Absorption Properties Of Nanocrystalline Lithium Ferrite Powders;
Dy_2O_3掺杂对纳米锂铁氧体微波吸收特性的影响
4) Li ferrite
锂铁氧体
1.
The Li ferrite materials were prepared by conventional ceramic technology.
结果表明,添加适量超细球状Bi2O3粉可有效抑制Li的挥发,同时引入Zn2+、、Ti4+、、Mg2+、、Mn2+等金属离子可将锂铁氧体的烧结温度降低至900℃以下,从而实现与银内电极的低温共烧。
2.
The Cu Ti co metal wave guide films on Li ferrite material surface have been made by magnetron sputtering deposition.
采用磁控溅射镀膜方法 ,在锂铁氧体材料表面 ,制备了 Cu- Ti复合金属波导膜系。
5) compound ferrite
复合铁氧体
1.
Hydrothermal synthesis of compound ferrite and reclamation of copper from electroplating sludge;
电镀污泥水热合成复合铁氧体与回收铜试验研究
6) lithium zinc ferrite
锂锌铁氧体
1.
Study on the influence of precursor mixture ratio and calcination temperature on microstructure and microwave absorption properties of lithium zinc ferrites;
原料配比和煅烧温度对锂锌铁氧体微观结构和吸波性能的影响
2.
The influence of different calcination treatments on microstructure and microwave absorbing properties of lithium zinc ferrites prepared by sol-gel method
不同煅烧处理对由溶胶凝胶法制备的锂锌铁氧体的微观结构及其吸波性能的影响
3.
Influence of Bi_2O_3 and Bi(NO_3)_3 dopant on microstructure and microwave Absorption of lithium zinc ferrites
Bi_2O_3和Bi(NO_3)_3掺杂对锂锌铁氧体微观结构和微波吸收性能的影响
补充资料:锂锰铁氧体
分子式:Li0.5Fe2.2~2.4Mn0.1~0.27O4
CAS号:
性质:以铁和锂氧化物为主同时掺锰的复合氧化物矩磁材料。立方晶系尖晶石结构。具有较高的饱和磁感应强度和矫顽力,居里点高约600℃,温度系数小。采用高温固相烧结法制备,主要用作宽温度范围(-55~125℃)磁心存储元件材料。
CAS号:
性质:以铁和锂氧化物为主同时掺锰的复合氧化物矩磁材料。立方晶系尖晶石结构。具有较高的饱和磁感应强度和矫顽力,居里点高约600℃,温度系数小。采用高温固相烧结法制备,主要用作宽温度范围(-55~125℃)磁心存储元件材料。
说明:补充资料仅用于学习参考,请勿用于其它任何用途。
参考词条