Strategy for Regulation from Heterogeneous Nucleation to Homogeneous Nucleation: Application of Ultrasound

IF 4.3 3区 材料科学 Q1 ENGINEERING, ELECTRICAL & ELECTRONIC
Rongxi Guo, Mengyang Cai, Jingjing Zhao, Pengpeng Yang, Hanjie Ying and Keke Zhang*, 
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Abstract

In this study, the nucleation rate and the corresponding nucleation parameters were calculated by measuring the induction time of isonicotinamide (INA) in ethanol, and it was demonstrated that the nucleation of INA is controlled by kinetics. We found that ultrasound can control the nucleation rate of INA in different supersaturated INA–ethanol systems and play a promoting or inhibiting role. The underlying mechanism for those phenomena was supposed to be the jointly effects of ultrasonics, where the cavitation bubbles generated by ultrasonic pretreatment undergo rupture leading to the collision of solute molecules in solution or the dispersion of solute molecules, and the energy generated by ultrasonics can influence the intermolecular hydrogen bond interaction in solution. In addition, the introduction of ultrasonics was found to promote the nucleation mechanism transformation from heterogeneous nucleation to homogeneous nucleation, through the homogeneous dispersion of solute molecules in solution, which we believe to be due to the micromixing mechanism of the ultrasonic. The transition from heterogeneous nucleation to homogeneous nucleation through introduction of ultrasonics provides a feasible approach to avoid heterogeneous nucleation and promote homogeneous nucleation and also provides a new perspective for controlling the crystallization process.

Abstract Image

从异质成核到均质成核的调节策略:超声波的应用
本研究通过测量异烟酰胺(INA)在乙醇中的诱导时间,计算了其成核率和相应的成核参数,证明了异烟酰胺的成核受动力学控制。我们发现,在不同的过饱和异烟酰胺-乙醇体系中,超声可以控制异烟酰胺的成核率,并起到促进或抑制作用。超声预处理产生的空化气泡破裂会导致溶液中溶质分子的碰撞或分散,而超声产生的能量会影响溶液中分子间氢键的相互作用。此外,研究还发现超声波的引入通过溶质分子在溶液中的均匀分散,促进了成核机制从异质成核到均质成核的转变,我们认为这是由于超声波的微混合机制所致。通过引入超声波实现从异质成核到均质成核的转变,为避免异质成核和促进均质成核提供了可行的方法,也为控制结晶过程提供了新的视角。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
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来源期刊
CiteScore
7.20
自引率
4.30%
发文量
567
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