| 1. | Face - centered cubic lattice
面心立方格子 |
| 2. | Face - centered cubic , fcc
按照面心立方 |
| 3. | Face - centered cubic f . c . c
面心立方 |
| 4. | Face - centered orthorhombic
面心斜方 |
| 5. | Face - centered cubic fc
面心立方 |
| 6. | Simulation of face - centered cubic lattice ' s first brillouin zone with 3 - dimensional animation
面心立方晶格第一布里渊区的三维动画模拟 |
| 7. | The inorganic cds in the composite is about 20 % , and the crystalline structure of cds in the composite is of face - centered structure
Xrd分析结果表明,复合微球中cds具有面心立方结构;复合微球中无机物含量约为20 。 |
| 8. | Xrd reveals a mixture structure of the face - centered cubic and hexagonal close - packed phases . the sn doped makes the electrical conductivity change from insulator to n - type semiconductor
用共蒸发法制备掺锡的c60薄膜,发现掺入的sn原子的薄膜导电性由原来的绝缘体变为n型半导体。 |
| 9. | Determination of single crystal size in artificial opals by measuring the width of the transmission dip in the f ? direction of face - centered cubic artificial opals with different thicknesses , we determine the size of the single crystal domain in the opal
人工opal光子晶体单畴大小的测定测定了不同厚度的人工opal在? l方向的透射谱,得出opal光子晶体中单畴的尺寸。 |
| 10. | By using a cell equivalent method , the present model can deal with the face - center square structure of erf . combining the scheme of the classical conductivity model for the single - chain structure , a new formula for the prediction of the shear yield stress of erf is set up . the influences of the separation distance of the particles , the volume fraction of the particles and the applied electric field on the shear yield stress are investigated
在电导模型的基础上,建立在电流变液体在外加电场的作用下,粒子之间会形成某种特定的微观结构,利用等效胞元的方法,将这微观结构等效成一个平板,建立了等效的微观结构平板模型,通过计算电流变液体内部的局部电场,对电流变液体的工作机理和剪切屈服应力进行了预测,并且分别考虑了在不同的粒子间距、不同的粒子浓度、不同的外加电场的情况下,对剪切屈服应力的影响。 |
