Ostwald ripening
英
美 [ˈɑstwəld ˈraɪpənɪŋ]
奥斯特瓦尔德熟化
双语例句
- The inside-out Ostwald ripening is responsible for the growth of spherical particles and the formation of hollow like-nanosphere.
对Ostwald成熟机理在球形颗粒的成长及中空类纳米球颗粒形成中的作用进行了讨论。 - The growth of the nanorods can be explained by the Ostwald ripening mechanism.
纳米棒沿(100)晶向生长,其形成可以用Ostwald成熟机制来解释。 - A possible mechanism was established to explain the formation of nanorings with TEM of different reaction time, which involved oriented aggregation and Ostwald ripening.
最后通过不同反应时间的透射电镜照片,解释了纳米环簇的形成机理,涉及取向聚集和奥氏熟化两种常用的机理。 - Theoretical Analysis on Controlled Element of Ostwald Ripening Process of Manganese Sulfide in Steels
硫化锰在钢中的Ostwald熟化过程的控制性元素的理论分析 - The coexistence of the dual surfactants and the cooperation of oriented attachment and Ostwald ripening played important roles in the formation of the crystals.
双表面活性剂的共存以及定向聚集和奥斯特瓦尔德熟化的协同作用对晶体的形成起着重要的作用。 - The results show: when the strain energy is neglected, randomly distributed equiaxed particles were obtained with isotropic characteristics, its coarsening follows the Ostwald ripening mechanism: smaller particles dwindle and larger particles grow;
研究发现:当忽略应变能时,沉淀相为随机分布的等轴颗粒,呈各向同性特征,其粗化遵循奥斯瓦尔德熟化机制:小颗粒溶解,大颗粒长大。 - There appeared two kinds of variations in the QDs as time progresses, one is the Ostwald ripening process, the other is the dot formation process.
随着时间的推移,量子点发生了两种变化,即Ostwald熟化过程和量子点的生成过程。 - Coalescence and growth through boundary diffusion and Ostwald ripening happen during series annealing at high temperature of copper nanoparticles immersing plating on Si-NPA.
浸渍沉积于Si-NPA表面的铜纳米颗粒在高温系列退火过程中发生了由边界扩散和Ostwald熟化导致的团聚生长。 - In the hydrothermal process, morphology and structure of the product were affected through both mechanisms of Ostwald ripening and phase transition.
在水热过程中,水热产物的形貌和结构按Ostwald陈化和相转化机制的发生改变。 - Analysis showed that the growing of Ag nanoparticles was mainly controlled by Ostwald ripening. The shape changed of Ag nanoparticles was due to the preferential adsorption of PVP on Ag ( 100) crystal surface.
分析表明在高温缺少Ag源条件下,Ag纳米粒子的生长主要受Ostwald熟化控制,异形化主要是由于PVP对Ag(100)晶面优先吸附的结果。