等离子体电化学法制备金、银纳米颗粒与碳量子点的研究进展及关键问题
RESEARCH PROGRESS AND KEY ISSUES IN SYNTHESIS OF GOLD AND SILVER NANOPARTICLES AND CARBON QUANTUM DOTS BY PLASMA ELECTROCHEMICAL METHOD
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摘要: 通过高电压击穿气体可产生大量的自由电子和离子, 形成对外大致呈电中性的气体放电等离子体, 同时荷能粒子引发的各种过程会在等离子体中产生种类丰富的反应性物质. 大气压低温等离子体具有非平衡特性, 因此在低气体温度下可保持高反应活性. 当大气压低温等离子体与溶液接触时, 可形成等离子体电化学系统. 在等离子体−液体界面存在电荷和物质转移, 可引发一系列物理化学及电化学过程, 从而使得等离子体电化学系统可广泛应用于多种领域, 纳米材料合成即是其众多应用之一. 当前, 已有大量的研究利用等离子体电化学法合成纳米材料, 也存在相关的综述文章, 但缺乏聚焦于金、银纳米颗粒与碳量子点相关的综述, 因此我们在此综述了近年来采用等离子体电化学方法制备金、银纳米颗粒与碳量子点的研究成果. 首先介绍了等离子体电化学方法, 接着考察了制备金、银纳米颗粒与碳量子点的实验结果及其应用的进展, 最后讨论了当前研究中遇到的问题与挑战, 并提出了解决方案.Abstract: A large number of free electrons and ions can be generated by high voltage breakdown of the gas, forming a gas discharge plasma that is roughly electrically neutral to the outside world, while various processes initiated by energetic particles produce a rich variety of reactive substances in the plasma. Atmospheric pressure low-temperature plasma has non-equilibrium characteristics, and therefore maintains high reactivity at low gas temperatures. When an atmospheric pressure low-temperature plasma is in contact with a solution, a plasma electrochemical system can be formed. Charge and substance transfer at the plasma-liquid interface can lead to a series of physicochemical and electrochemical processes, which makes the plasma electrochemical system widely used in a variety of fields, and the synthesis of nanomaterials is one of the many applications. Currently, there have been a large number of studies on the synthesis of nanomaterials using plasma electrochemistry, and there are also related review articles, but there is a lack of reviews focusing on gold and silver nanoparticles and carbon quantum dots, so here we review the results of the research on the synthesis of gold and silver nanoparticles and carbon quantum dots using plasma electrochemistry in recent years. Firstly, we introduce the plasma electrochemical method, then we examine the experimental results of the synthesis of gold and silver nanoparticles and carbon quantum dots and the progress of their applications, and finally we discuss the problems and challenges encountered in the current research and try to propose solutions.