Liu Haiyang, Wu Rong, Tian Lie, Kong Yangyang, Sun Yanfei
School of Physics Science and Technology, Xinjiang University, Xinjiang 830046, People's Republic of China.
Nanotechnology. 2018 Jul 13;29(28):285402. doi: 10.1088/1361-6528/aabf56. Epub 2018 Apr 19.
Semiconductor phase transitions and plasma noble metal quantum dots (QDs) for visible-light-driven photocatalysts have attracted significant research interest. In this study, novel microwave hydrothermal and photo-reduction methods are proposed to synthesise a visible-light-driven plasma photocatalytic 1T@2H-MoS/Ag composite. Photoelectrochemical results show that the introduction of the 1T phase and Ag significantly enhances the light response range and charge separation. The 1T phase can act as a co-catalyst to provide a high electron concentration. Ag QDs can effectively improve the light absorption and catalytic effect. The synergistic effect between the 1T@2H-MoS microspheres and localised surface plasmon resonance of the Ag QDs can effectively enhance the photocatalytic activity of 1T@2H-MoS/Ag. The developed 1T@2H-MoS/Ag composite is superior, not only with respect to a visible-light photocatalytic degradation of conventional dyes, but also in the photocatalytic reduction of Cr(VI). Compared with 2H-MoS, the catalytic efficiency of 1T@2H-MoS/Ag for Cr(VI) and MB is increased by 81% and 41%, respectively. This study demonstrates that the introduction of 1T-MoS and Ag QDs can significantly enhance the catalytic properties of 2H-MoS. The microwave and photo-reduction technologies can be employed as green, safe, simple, and rapid methods for the synthesis of noble metal plasma composites.
用于可见光驱动光催化剂的半导体相变和等离子体贵金属量子点(QDs)引起了广泛的研究兴趣。在本研究中,提出了新颖的微波水热法和光还原法来合成可见光驱动的等离子体光催化1T@2H-MoS/Ag复合材料。光电化学结果表明,1T相和Ag的引入显著拓宽了光响应范围并促进了电荷分离。1T相可作为助催化剂提供高电子浓度。Ag量子点能有效提高光吸收和催化效果。1T@2H-MoS微球与Ag量子点的局域表面等离子体共振之间的协同效应可有效增强1T@2H-MoS/Ag的光催化活性。所制备的1T@2H-MoS/Ag复合材料不仅在可见光光催化降解传统染料方面表现优异,而且在光催化还原Cr(VI)方面也具有出色性能。与2H-MoS相比,1T@2H-MoS/Ag对Cr(VI)和亚甲基蓝(MB)的催化效率分别提高了81%和41%。本研究表明,引入1T-MoS和Ag量子点可显著增强2H-MoS的催化性能。微波和光还原技术可作为绿色、安全、简单且快速的方法用于合成贵金属等离子体复合材料。