表面等离子共振热电子注入机理及在光催化与光电催化应用中的研究进展

由于金属纳米晶表面等离子共振产生的热电子效应,金属/半导体异质纳米晶的可控合成对于增强半导体光催化与光电催化性能具有显著的促进作用。本综述阐述了热电子产生与驰豫的微观机制,探讨了影响热电子在金属-半导体异质纳米晶中界面传递效率的关键因素及异质界面调控合成的重要性,简要介绍了热电子注入效应在光催化与光电催化制备太阳能燃料研究中的应用进展,分析了目前存在的主要问题并对该领域未来的发展趋势进行了展望。

Ru-Co-Mn trimetallic alloy nanocatalyst driving bifunctional redox electrocatalysis

Water electrolysis is one of the most promising approaches for producing hydrogen.However,it has been hindered by the sluggishness of the anodic oxygen evolution reaction.In this work,we fabricated Ru-Co-Mn trimetallic alloy nanoparticles on N-doped carbon support(RuCoMn@NC)via the pyrolysis-adsorption-pyrolysis process using ZIF-67 as a precursor.The RuCoMn@NC catalyst exhibited excellent electrocatalytic performance for the hydrogen evolution reaction(HER)over a wide range of pH and glucose oxidation reaction in alkaline media.It showed exceptional HER activity in alkaline medium,superior to that of the commercial Pt/C catalyst(20 wt%),and good electrochemical stability.Further,a two-electrode alkaline electrolyzer pairing RuCoMn@NC as both cathode and anode was employed,and only a cell voltage of 1.63 V was required to attain a current density of 10 mA cm^(-2)in glucose electrolysis,which is about 270 mV lower than that in the overall water-splitting electrolyzer.This paper provides a promising method for developing efficiently bifunctional electrocatalysts driving redox electrocatalysis,and it would be beneficial to energy-saving electrolytic H_(2) production.

贵金属磷化物的合成及电催化分解水的研究进展

电化学水分解被认为是一种环保、高效的无污染制氢途径,提高其阳极析氧反应(OER)和阴极析氢反应(HER)的关键是构造高效的电催化剂.近年来,研究者致力于开发各种性能优良的电催化剂.其中,贵金属磷化物因其突出的催化活性、全pH值适用性以及相比于Pt基催化剂的成本优势而极具发展前景.本文就这一研究领域的最新进展进行了概述,以电解水反应机理为基础,总结了贵金属磷化物的主要合成方法,并详细讨论了贵金属磷化物在电解水方面的应用现状.最后,总结了贵金属磷化物电催化剂的优势与面临的挑战,并讨论了未来可能的发展方向,以期为新型电催化剂的设计和制造提供有价值的参考.