Photocatalytic hydrogen evolution on a high-entropy oxide

The introduction of high-entropy oxides (HEOs), i.e. compounds containing oxygen and five or more cations in their crystal structure, has led to interesting functional properties in recent years. In this study, the first high-entropy photocatalyst is synthesized by mechanical alloying via the high-pressure torsion (HPT) method followed by high-temperature oxidation. The synthesized oxide contains 60 mol% of AB(2)O(7) monoclinic perovskite and 40 mol% of A(6)B(2)O(17) orthorhombic perovskite, where A represents Ti, Zr and Hf and B represents Nb and Ta. This two-phase oxide with an overall composition of TiHfZrNbTaO11 and a d(0) electronic configuration shows an appreciable light absorbance in the visible-light region with a bandgap of 2.9 eV and appropriate valence and conduction bands for water splitting. The material successfully produces hydrogen by photocatalytic water splitting, suggesting the potential of HEOs as new low-bandgap photocatalysts.