Evolution of Zinc Oxide Nanostructures through Kinetics Control.

Jian Shi, Hao Hong, Yong Ding, Yunan Yang, Weibo Cai, Xudong Wang
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引用次数: 32

Abstract

In-depth understanding of the kinetics of the vapor deposition process is substantial for advancing this capable bottom-up nanostructure synthesis approach into a versatile large-scale nanomanufacturing technology. In this paper, we report a systematic study of the vapor deposition kinetics of ZnO nanomaterials under controlled atmosphere and properly refined deposition conditions. The experiments clearly evidenced the self-catalyzed growth of ZnO NWs via the formation of ZnO nanoflowers. This result illustrated how ZnO morphologies were associated with the discrepancy between oxidation rate and condensation rate of Zn. The capability of switching the NW morphologies and possibly mechanisms was demonstrated by kinetically controlling the deposition system. The high Zn composition during the deposition resulted in strongly luminescent NWs, which can be used for optical imaging applications. This research discovered a fundamental kinetics that governs the mechanisms and morphology selection of nanostructures in a non-catalyst growth system.

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动力学控制下氧化锌纳米结构的演化。
深入了解气相沉积过程的动力学对于将这种自下而上的纳米结构合成方法推进到通用的大规模纳米制造技术是至关重要的。在本文中,我们报道了在可控气氛和适当细化的沉积条件下ZnO纳米材料气相沉积动力学的系统研究。实验通过ZnO纳米花的形成清楚地证明了ZnO纳米ws的自催化生长。这一结果说明了ZnO的形貌与Zn的氧化速率和缩合速率的差异之间的关系。通过对沉积系统进行动力学控制,证明了其改变NW形貌的能力和可能的机制。在沉积过程中,高锌成分导致了强发光的NWs,可用于光学成像应用。本研究发现了在非催化剂生长系统中控制纳米结构的机制和形态选择的基本动力学。
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
Journal of Materials Chemistry
Journal of Materials Chemistry 工程技术-材料科学:综合
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审稿时长
1.5 months
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