| 1. | The ground effect increases the thrust force and efficiency
表面效应使机翼推力增大,推进效率提高。 |
| 2. | It possesses small - dimension effect , quantum dimensional effect and surface effect
它具有小尺寸效应、量子尺寸效应和表面效应。 |
| 3. | Atomistic simulation of tension properties of nano crystal copper wire under surface effects
表面效应对纳米铜杆拉伸性能影响的原子模拟 |
| 4. | It is found that surface effect is obvious in the nanoscale . nanometer material stress is not zero without force
研究表明,纳米材料表面效应不可忽略,未受外力作用下,材料表面内部有应力存在。 |
| 5. | Surface effect , tension and bending of nano single - crystal copper are researched on the basis of molecular dynamics using the eam ( embedded atom method ) potential
本文主要应用分子动力学方法对纳米单晶铜杆的表面效应及拉伸、弯曲性能做了分析和研究。 |
| 6. | The pressure dependence of permeation flux indicates strong surface contribution . the way of filling hydrogen by continuous flow and / or bubble can increase permeation flux
从渗透通量与样品上游氢压的关系来看,涂层使得表面效应对渗透过程的影响很大。 |
| 7. | Nano - matreials have a perfect perspective for their volume effects and surface effects , which could enhance biologic activity , adhesiveness and proliferation of cells
纳米材料因具有一些独特的效应,如体积效应和表面效应,有利于细胞黏附、增殖和功能表达,因而作为生物医用材料特别是组织工程支架材料具有良好的应用前景。 |
| 8. | In this chapter , we described some basic properties of nanoparticle , such as quantum - size effect , surface effect , small - size effect , macro - quantum tunnel effect and so on
第一部分:综述第一章;纳米微粒的特性与应用本章主要介绍了纳米材料的一些基本特性。例如:量子尺寸效应、表面效应、小尺寸效应、宏观量子尺寸效应等。 |
| 9. | A relaxation surface effect is simulated on the basis of a molecular dynamics using the eam ( embedded atom method ) potential by applying a periodic boundary condition for copper . surface atom ' s potential , stress and position changes are presented
运用分子动力学方法对纳米单晶铜在接近绝对零度下的表面效应进行了分析,给出了表面原子位置变化、能量大小、应力的大小。 |
| 10. | For the effects of dimension and surface , the lattice structure , chemical states and the electronic states in the film surface ( interface ) have greatly affected the properties of the films and the practical applies in industries
由于纳米材料的小尺寸效应及表面效应,薄膜表(界)面的晶格结构、化学形态和电子态成为决定薄膜性能的重要因素,而这些因素又直接影响着钛酸钡系薄膜的实际应用。 |
