Green synthesis of nanostructured 1T/2H-MoS2 hybrid phase with polyol solvents and microwave heating

Thi Minh Nguyet Nguyen, V. Vuong, Huu Huy Phuc Nguyen, Van Thang Le
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引用次数: 0

Abstract

Green synthesis approaches have attracted greatly of attention in recent years since they address the issues associated with sustainability than conventional synthesis methods. New research fields in green nanoscience are being developed as a result of the incorporation of green chemistry principles into nanoscience. In this paper, the successful microwave-assisted green synthesis of MoS2 nanoparticles in a single pot using polyol solvents such as ethylene glycol and glycerol is demonstrated. The coexistence of 1T and 2H phases in MoS2 nanomaterials was determined using advanced techniques such as XRD, Raman, XPS, and TEM images. The highest 1T proportion obtained was 84.5% when compared to the 2H phase. The reaction mechanism and the phase transition between 1T and 2H were described and illustrated. The role of polyol solvents in the practical synthesis of nano MoS2 under microwave heating is also evaluated and explained. Due to the ability of the metallic 1T phase to enhance electrical conductivity, it is believed that hybrid nanostructures exhibit superior electrochemical performance for energy storage and conversion applications.
利用多元醇溶剂和微波加热绿色合成纳米结构 1T/2H-MoS2 混合相
与传统合成方法相比,绿色合成方法能够解决与可持续性相关的问题,因此近年来备受关注。将绿色化学原理融入纳米科学,正在开发绿色纳米科学的新研究领域。本文展示了使用乙二醇和甘油等多元醇溶剂在单锅中成功地微波辅助绿色合成 MoS2 纳米粒子。利用 XRD、拉曼、XPS 和 TEM 图像等先进技术测定了 MoS2 纳米材料中 1T 相和 2H 相的共存情况。与 2H 相相比,1T 所占比例最高,达到 84.5%。对反应机理和 1T 与 2H 之间的相变进行了描述和说明。此外,还评估并解释了多元醇溶剂在微波加热下实际合成纳米 MoS2 中的作用。由于金属 1T 相具有增强导电性的能力,相信混合纳米结构在能量存储和转换应用中会表现出卓越的电化学性能。
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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