通过热注射和升温法形成均匀纳米晶体的机理。

Formation mechanisms of uniform nanocrystals via hot-injection and heat-up methods.

机构信息

National Creative Research Initiative Center for Oxide Nanocrystalline, Materials and World Class University program of Chemical, Convergence for Energy & Environment and School of Chemical and Biological Engineering, Seoul National University, Seoul, 151-744, Korea.

出版信息

Small. 2011 Oct 4;7(19):2685-702. doi: 10.1002/smll.201002022. Epub 2011 Aug 1.

DOI:10.1002/smll.201002022

PMID:21805623

Abstract

Synthesis of uniform nanocrystals is very important because the size uniformity of an ensemble of nanocrystals is directly related to the homogeneity of their chemical and physical properties. Classical theory suggests that burst nucleation and diffusion-controlled growth are the most important factors for the control of the size distribution in colloidal synthesis. In the last two decades, the numerous reports on the synthesis of uniform nanocrystals have popularized two major synthetic methods, namely, hot-injection and heat-up, to obtain uniform nanocrystals of various materials including metals, semiconductors, and oxides. Mechanistic studies on how such uniform nanocrystals are obtained in those two methods are reviewed and theoretical explanations are provided in the current review.

摘要

合成均匀的纳米晶体非常重要，因为纳米晶体的大小均匀性直接与其化学和物理性质的均一性相关。经典理论表明，成核的爆发和扩散控制的生长是胶体合成中控制尺寸分布的最重要因素。在过去的二十年中，关于合成均匀纳米晶体的众多报道已经推广了两种主要的合成方法，即热注入法和升温法，以获得包括金属、半导体和氧化物在内的各种材料的均匀纳米晶体。本综述回顾了这两种方法中如何获得均匀纳米晶体的机制研究，并提供了理论解释。

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通过热注射和升温法形成均匀纳米晶体的机理。

Formation mechanisms of uniform nanocrystals via hot-injection and heat-up methods.

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