Recently, photocatalysts have been

Recently, photocatalysts have been examined as viable
alternatives to traditional disinfection methods because of their
superior ability to inactivate a variety of harmful bacteria [8–14].
Titanium dioxide (TiO2) is one of the most popular and successful
photocatalysts. TiO2 photocatalysts have been widely recognized
as viable solutions to environmental problems because of their
exceptional optical and electronic properties, chemical stability,
non-toxicity, and low cost [15–17]. In recent years, TiO2 photocatalysts
have been studied for use in bacterial disinfection due to
their stable and strong oxidative reactions that result in biocidal
activity [18]. It has been well documented that an electron-hole
pair is generated when a TiO2 photocatalyst is excited by UV irradiation,
which requires energy that is equal to or higher than its
band gap energy. The electron-hole pairs react with water, hydroxyl
groups, and molecular oxygen absorbed on the TiO2 surface, generating
reactive oxygen species such as the hydroxyl radical (•OH)
and superoxide anion (•O2
−). These oxy radical species participate
in oxidation reactions that attack vital organic components
in microorganisms, such as cell membranes, RNA, DNA, proteins,
and lipids, resulting in the death of the microorganisms. However,
in a practical system using light sources, such as a white light fluorescent
lamp and solar light whose UV radiation intensity for
photo-exciting TiO2 is very weak, the TiO2 exhibits low photocatalytic
disinfection activity. Therefore, a large number of studies