posted on 2023-09-14, 05:04authored byCheng Jin, Chuang Zhi, Zhongti Sun, Shaosheng Rao, Qinqin Liu, Yexin Jiang, Lei Liu, Yingjie Sun, Juan Yang
Constructing
an efficient visible light-responsive antibacterial
material for water treatment remains a principal goal yet is a huge
challenge. Herein, a 2D/2D heterojunction composite with robust interfacial
contact, named MXene/CN (MCN), was controllably fabricated by using
a urea molecule intercalated into MXene following an in situ calcination method, which can realize the rapid separation and migration
of photogenerated carriers under visible light irradiation and significantly
improve the carrier concentration of the MXene surface, thus generating
more reactive oxygen species. The generation of heat induced by MXene
could also increase photogenic electron activity to facilitate the
photocatalytic reaction using in situ time-resolved
photoluminescence characterization. The visible light-activated germicide
exhibits a sterilization efficacy against Escherichia coli of 99.70%, higher than those of pure CN (60.21%) and MXene (31.75%),
due to the effect of photothermally assisted photocatalytic treatment.
This work is an attempt to construct a visible light-driven antimicrobial
material using Schottky junctions achieving photothermally assisted
photocatalytic disinfection.