1) capillary anisotropy
界面能各向异性
1.
Based on the adaptive finite element method,the phase-field model has been employed to simulate the free dendritic growth process governed by capillary anisotropy or kinetic anisotropy.
采用自适应有限元方法求解相场模型,分别对界面能各向异性和界面动力学各向异性条件下自由枝晶生长过程进行了模拟。
2) interface anisotropy
界面各向异性
1.
Our theory holds for arbitrary external magnetic field,ferromagnetic or antiferromagnetic interface exchange coupling and arbitrary easy axis(unaxial) volume and interface anisotropy.
结果发现,在三链系统中,有两种不同类型的光学界面自旋波,它们在不同界面各向异性条件下,均可存在0~2个自旋波
2.
Our theory holds for arbitrary external magnetic field,ferromagnetic or antiferromagnetic interface exchange coupling,and arbitrary easy axis (unaxial) volume and interface anisotropy.
计入外磁场、铁磁和反铁磁层间耦合、体和界面各向异性后,研究了A-B-A 三链系统中的声学型界面自旋波及其存在条件。
3.
The model of a ferromagnetic bichain with arbitrary easy axsi unaxial volume and interface anisotropy,and ferromagnetic or antiferromagnetic interface exchange coupling is investigated.
在考虑了外磁场、界面各向异性后,详细研究了铁磁和反铁磁层间耦合下自旋双链系统中的声-光型界面自旋波及其存在的充要条件。
5) anisotropy energy
各向异性能
1.
L10 ordered FePt thin films have drawn considerable attention as a potential ultra-high density magnetic recording material, due to its large magnetocrystalline anisotropy energy, high coercivity, high energy product, high Curie temperature, and excellent resistance of corrosion.
L10有序FePt合金薄膜具有高磁晶各向异性能、高矫顽力、高磁能积、高居里温度和抗腐蚀能力强等优点,能够满足超高密度磁记录的要求,极有可能成为下一代超高密度磁存储介质。
6) planar anisotropy
平面各向异性
1.
Grain structure,texture and planar anisotropy of Al-Mg-Sc alloy plate;
铝-镁-钪合金板材晶粒结构、织构和力学性能平面各向异性
2.
The effect of cold reduction on the planar anisotropy of cold rolled and annealed low carbon steel sheets microalloyed with Ti was studied under prescribed processing conditions in the lab.
在实验室工艺条件下,研究了冷轧压下率对微钛处理的低碳钢板的平面各向异性的影响,对不同压下率下钢板的典型织构进行了比较,并对压下率和钛共同作用,影响平面各向异性的机理进行了分析。
3.
The effect of titanium on the planar anisotropy of cold rolled and annealed sheets was studied under prescribed processing conditions.
研究了在一定工艺条件下,微合金化元素钛对冷轧退火态钢板平面各向异性的影响,比较了不同钛含量的ODF(取向密度函数)织构图,并对钛影响平面各向异性的机理进行了分析。
补充资料:界面能
分子式:
CAS号:
性质:又称总表面能或表面内能。是在恒温恒压条件下增加单位界(或表)面体系内能的增量。
CAS号:
性质:又称总表面能或表面内能。是在恒温恒压条件下增加单位界(或表)面体系内能的增量。
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