Recent development on titania-based nanomaterial for photocatalytic CO2 reduction: A review

“…Several types of reactors can be employed, including top‐down illumination photoreactor, inner/immersed illumination photoreactor, spiral suspension photoreactor, slurry photoreactor, and panel photoreactor [24] . When selecting a reactor for the photocatalytic CO 2 reduction to methane, important considerations include the phase involved (e. g. single‐phase or multiphase solid‐liquid, gas‐solid, or gas‐liquid‐solid), the operating system (e. g. batch, semi‐batch or continuous), the geometric configuration (dimensions and shape), and the light irradiation setup [96–98] …”

“…[24] When selecting a reactor for the photocatalytic CO 2 reduction to methane, important considerations include the phase involved (e. g. single-phase or multiphase solid-liquid, gas-solid, or gas-liquid-solid), the operating system (e. g. batch, semi-batch or continuous), the geometric configuration (dimensions and shape), and the light irradiation setup. [96][97][98]…”

Recent Advances on the Utilization of TiO₂‐Based Catalysts in the Photocatalytic Reduction of CO₂ to Methane

“…Several types of reactors can be employed, including top‐down illumination photoreactor, inner/immersed illumination photoreactor, spiral suspension photoreactor, slurry photoreactor, and panel photoreactor [24] . When selecting a reactor for the photocatalytic CO 2 reduction to methane, important considerations include the phase involved (e. g. single‐phase or multiphase solid‐liquid, gas‐solid, or gas‐liquid‐solid), the operating system (e. g. batch, semi‐batch or continuous), the geometric configuration (dimensions and shape), and the light irradiation setup [96–98] …”

“…[24] When selecting a reactor for the photocatalytic CO 2 reduction to methane, important considerations include the phase involved (e. g. single-phase or multiphase solid-liquid, gas-solid, or gas-liquid-solid), the operating system (e. g. batch, semi-batch or continuous), the geometric configuration (dimensions and shape), and the light irradiation setup. [96][97][98]…”

Recent Advances on the Utilization of TiO₂‐Based Catalysts in the Photocatalytic Reduction of CO₂ to Methane

“…[1][2][3] Titanium dioxide (TiO 2 ), recognized as one of the most important photocatalysts, has garnered extensive attention owing to its cost-effectiveness, alluring properties, and structural stability. 4,5 Nevertheless, its photocatalytic efficacy often falls short of expectations, primarily attributable to the wide bandgap and inefficient separation of photogenerated carriers. To enhance the photocatalytic performance of TiO 2 , it is imperative to devise efficient strategies that broaden its light absorption spectrum and overcome the kinetic constraints associated with photogenerated charge transfer.…”

Constructing Cu defect band within TiO₂ and supporting NiO_x nanoparticles for efficient CO₂ photoreduction

“…The use of fossil fuels produces large amounts of CO 2 and increases the concentration of CO 2 in the atmosphere, − which causes a series of serious environmental problems. Using photocatalysts to convert CO 2 into organic products through solar energy is one of the best ways to solve this problem, like killing two birds with one stone to save our environment. − Various photocatalysts have been explored, including semiconductor materials such as TiO 2 , − Zn 2 GeO 4 , − ZnGa 2 O 4 , − etc. Although the photocatalytic activity of those catalysts has been gradually improved, the inherent physicochemical properties of traditional semiconductor materials limit further improvements in photocatalytic conversion efficiency, such as the poor adsorption performance of CO 2 , low specific surface area, and short lifetime of photogenerated carriers.…”

Controllable Synthesis of MIL-101(Cr)@TiO₂ Core–Shell Nanocomposites for Enhanced Photocatalytic Activity