Single‐precursor phase‐controlled synthesis of copper selenide nanocrystals and their conversion to amorphous hollow nanostructures

SmartMat Pub Date : 2023-03-03 DOI:10.1002/smm2.1193
Feifan Chen, Yadong Zhang, Lijun Hu, Lifang Zheng, Feiyue Ge, Changsheng Feng, Dan-tong Xu, Ch Tao, Xuejun Wu
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引用次数: 2

Abstract

The crystal phases are essential to the physicochemical properties and functionalities of materials. Copper selenide has emerged as an important and appealing semiconductor, which can exist in a variety of polymorphic phases. However, the richness of polymorphs also makes it a challenge to the direct preparation of copper selenide nanocrystals with tunable phases. Herein, two polymorphs, that is, quasi‐tetragonal Cu2−xSe nanocubes and metastable wurtzite Cu2Se nanodisks, are successfully synthesized by using a single precursor, copper(I) selenocyanate (CuSeCN), as the Cu and Se sources. The key to phase modulation is the optimal choice of the ligand in the synthesis. The as‐prepared nanocrystals possess different morphologies and compositions, giving rise to distinct optical properties and electrical conductivities. Interestingly, the copper selenide nanocrystals can provide a platform for the rational construction of two types of amorphous hollow Au─Cu─Se nanostructures by reaction with Au(I) precursor, in which their final shapes are well kept as that of the original nanocrystal templates. This work provides an easy strategy for the phase‐controlled synthesis of copper selenide nanocrystals and enables the design of new materials for broad applications.
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单前驱体控制的硒化铜纳米晶的合成及其向非晶中空纳米结构的转化
晶体相对材料的物理化学性质和功能至关重要。硒化铜是一种重要的、具有吸引力的半导体,它可以存在于多种多晶相中。然而,多晶的丰富性也给直接制备具有可调相的硒化铜纳米晶体带来了挑战。本文以硒酸铜(Cu)和硒酸铜(CuSeCN)为前驱体,成功合成了准四方Cu2−xSe纳米立方体和亚稳纤锌矿Cu2Se纳米圆盘。相位调制的关键是合成过程中配体的最佳选择。制备的纳米晶体具有不同的形貌和组成,产生不同的光学性质和电导率。有趣的是,硒化铜纳米晶体可以通过与Au(I)前驱体反应,为合理构建两种非晶空心Au─Cu─Se纳米结构提供平台,其最终形状与原始纳米晶体模板保持一致。这项工作为相控合成硒化铜纳米晶体提供了一种简单的策略,并使新材料的设计具有广泛的应用前景。
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