Recent Progress on Cerium Oxide-Based Nanostructures for Energy and Environmental Applications

Cerium oxide (CeO₂) photo/electrocatalysts for energy storage and environmental applications have attracted considerable interest because of stable crystal structure, low toxicity/cost, superior chemical stability, stable redox (Ce³⁺/Ce⁴⁺) pairs, abundant oxygen defects, and capablility for intense interaction with other materials. However, the wide bandgap and poor conductivity lower the CeO₂ photo/electrocatalytic and energy storage performances. To overcome these limitations, various modification strategies (tuning morphology, doping or loading of metal nanoparticles, and heterostructures) have been applied for the improvement of photocatalytic (removal of organic contaminants from water/wastewater and H₂ production and CO₂ reduction reactions) efficiency, electrocatalytic (hydrogen/oxygen evolution reactions and CO₂ reduction reactions), and energy storage performances (supercapacitor) of CeO₂-based materials. Herein, the recent progress of CeO₂-based materials for electro(photo)catalysis and energy storage applications has been discussed. The challenges and possible direction of CeO₂-based materials for electro(photo)catalysis and energy storage applications have been emphasized. Furthermore, this comprehensive review is expected to advance the design of CeO₂-based materials and their applications in electro(photo)catalysis and energy.