文献类型：期刊文献

中文题名：热注射法制备金属硒化物纳米晶

英文题名：Preparation of metal selenide nanocrystals with hot-injection method

作者：刘仪柯 唐雅琴 魏静 赵清 俞大鹏 刘芳洋 蒋良兴

第一作者：刘仪柯

通信作者：Zhao, Qing

机构：[1]贵州理工学院材料与冶金工程学院,贵阳550003;[2]北京大学物理学院人工微结构与介观物理国家重点实验室电子显微镜实验室,北京100871;[3]量子物质科学协同创新中心,北京100084;[4]中南大学冶金与环境学院先进电池材料教育部重点实验室,长沙410083

第一机构：贵州理工学院材料与冶金工程学院

年份：2017

卷号：62

期号：23

起止页码：2649-2659

中文期刊名：科学通报

外文期刊名：Chinese Science Bulletin

收录：CSTPCD;;EI(收录号：20173704157858);Scopus(收录号：2-s2.0-85076383526);北大核心:【北大核心2014】；CSCD:【CSCD2017_2018】；

基金：国家自然科学基金(51604088,51622201,91433102);贵州省自然科学基金(黔科合LH字[2015]7091);贵州理工学院高层次人才科研启动经费(XJGC20161236)资助

语种：中文

中文关键词：金属硒化物;纳米晶;热注射法;绿色制备

外文关键词：metal selenide; nanocrystals; hot-injection method; green synthesis

摘要：金属硒化物纳米晶由于其独特的物理、化学性质,在光伏、光电探测、热电和生物医疗探针等领域表现出了巨大的应用潜力,引起人们的广泛关注.热注射法是液相合成金属硒化物纳米晶最有效、最重要的方法之一.本文介绍了热注射法制备纳米晶的基本原理、实施过程和特点,并概述了国内外利用该方法制备金属硒化物纳米晶的研究进展.
Nanomaterials have received extensive and growing research interests due to their unique properties and potential applications in various fields. They have contributed immensely to modern materials science and technology during the last three decades. Among various types of functional nanomaterials, metal selenide nanocrystals have attracted considerable attention because of their special properties. These nanomaterials have been applied in a wide range, such as medicine, electronics, photonics, energy conversion and storage devices, etc. Interestingly, when metals are chemically combined with selenide in the form of nanocrystals, they exhibit semiconductor-like electronic properties. These metal selenide nanocrystals have attracted significant attention in recent years due to their potential applications in solar energy conversion and storage, which are the most important challenges to be addressed to meet the world＇s rising demand for clean energy in the future. Hot-injection method is an effective method for the synthesis of metal selenide nanocrystals. The success of this approach lies in the use of non-ionic precursors in high-boiling organic solvents. This makes it possible to grow the nanocrystals relatively slowly at a high temperature, which yields defect-free, well-passivated nanocrystals. The anther important aspect of this method is the separation of the nucleation and growth stages. Due to this, a high degree of monodispersity can be achieved. The fundamental principle of hot-injection method with concrete steps has been introduced. This review surveys the recent progress of the preparation of metal selenide nanocrystals by hot-injection method in terms of binary metal selenide nanocrystals, ternary metal selenide nanocrystals, quaternary, and multinary metal selenide nanocrystals. For binary metal selenide nanocrystals, four important binary metal selenide nanocrystals including Cd Se, Zn Se, Pb Se, and Sb_2Se_3 nanocrystals are discussed. Then the achievement of synthesis for Cu In Se_2 and Cu GaSe_2 nanocrystals by hot-injection method and their application in photovoltaic field are systematically cataloged as well. And the progress in preparation for CuInGaSe_2 and Cu_2 ZnSnSe_4 nanocrystals by hot-injection method has been clarified clearly. Organoselenide chemicals are generally toxic and unstable. The replacement of phosphine containing compounds in the synthesis process of metal selenide nanocrystals via hot-injection method has received considerable attention in recent years. Many attempts have been made to replace trioctylphosphine（TOP） as a medium for delivering selenium in these reactions, but each alternative possesses has significant limitations. This review mainly emphasizes on the recent advances toward the development of methods to achieve ＂green Se precursor＂ with high activity and ＂facile green synthesis＂ of metal selenide nanocrystals involved in various approaches. Two kinds of different schemes for synthesis and utilization ＂green Se precursor＂ are described. Finally, technical challenges and future trends are presented for synthesis of high quality metal selenide nanocrystals, in terms of composition-tunable and structure-controllable multinary metal selenide nanocrystals, green synthesis, industrial production and large-scale application.