Defect
engineering is an effective strategy to enhance the activity
of catalysts for various applications. Herein, it was demonstrated
that in addition to enhancing surface properties via doping, the influence
of dopants on the surface–intermediate interaction is a critical
parameter that impacts the catalytic activity of doped catalysts for
low-temperature formaldehyde (HCHO) oxidation. The incorporation of
Co into the lattice structure of δ-MnO2 led to the
generation of oxygen vacancies, which promoted the formation of surface
active oxygen species, reduced activation energy, and enhanced catalytic
activity for low-temperature oxidation of HCHO. On the contrary, Cu
doping led to a drastic suppression of the catalytic activity of δ-MnO2, despite its enhanced redox properties and slight increase
in the surface concentration of active oxygen species, compared to
pristine δ-MnO2. Diffuse reflectance infrared Fourier
transform analysis revealed that in the presence of Cu, carbonate
intermediate species accumulate on the surface of the catalysts, leading
to partial blockage of active sites and suppression of catalytic activity.
Toluene is one of the pollutants that are dangerous to the environment and human health and has been sorted into priority pollutants; hence the control of its emission is necessary. Due to severe problems caused by toluene, different techniques for the abatement of toluene have been developed.Catalytic oxidation is one of the promising methods and effective technologies for toluene degradation as it oxidizes it to CO2 and does not deliver other pollutants to the environment. This paper highlights the recent progressive advancement of the catalysts for toluene oxidation. Five categories of catalysts, including noble metal catalysts, transition metal catalysts, perovskite catalysts, metal-organic framework (MOFs)-based catalysts, and spinel catalysts reported in the past half a decade (2015-2020), are reviewed. Various factors that influence their catalytic activities, such as morphology and structure, preparation methods, specific surface area, relative humidity, and coke formation, are discussed. Furthermore, the reaction mechanisms and kinetics for catalytic oxidation of toluene are also discussed.
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