Defective high-entropy oxide photocatalyst with high activity for CO2 conversion

High-entropy oxides (HEOs), as a new family of materials with five or more principal cations, have shown promising properties for various applications. In this work and inspired by inherent defective and strained structure of HEOs, photocatalytic CO2 conversion is examined on a dual-phase TiZrNbHfTaO11 synthesized by a two-step high-pressure torsion mechanical alloying and high-temperature oxidation. The HEO, which had various structural defects, showed simultaneous photocatalytic activity for CO2 to CO and H2O to H2 conversion without the addition of a co-catalyst. The photocatalytic activity of this HEO for CO2 conversion was better than conventional photocatalysts such as anatase TiO2 and BiVO4 and similar to P25 TiO2. The high activity of HEO was discussed in terms of lattice defects, lattice strain, light absorbance, band structure, photocurrent generation and charge carrier mobility to activation centers. The current study confirms the high potential of HEOs as a new family of photocatalysts for CO2 conversion.

Automated summary

High-entropy oxides (HEOs) with inherent defective and strained structure exhibit promising photocatalytic activity for CO2 conversion without the need for additional co-catalysts. The unique structural characteristics of HEOs contribute to their high potential as a new family of photocatalysts for CO2 conversion, surpassing conventional photocatalysts in terms of activity and performance.