Abstract

Spinel oxides with tunable chemical compositions have emerged as versatile electrocatalysts, however their performance is greatly limited by small surface area and low electron conductivity. Here, ultrathin high-entropy Fe-based spinel oxides nanosheets are rationally designed (i.e., (Co_0.2Ni_0.2Zn_0.2Mg_0.2Cu_0.2)Fe₂O₄; denotes A⁵Fe₂O₄) in thickness of ≈4.3 nm with large surface area and highly exposed active sites via a modified sol-gel method. Theoretic and experimental results confirm that the bandgap of A⁵Fe₂O₄ nanosheets is significantly smaller than that of ordinary Fe-based spinel oxides, realizing the transformation of binary spinel oxide from semiconductors to metalloids. As a result, such A⁵Fe₂O₄ nanosheets manifest excellent performance for the nitrate reduction reaction (NO₃ ^-RR) to ammonia (NH₃), with a NH₃ yield rate of ≈2.1 mmol h^-1 cm^-2 at -0.5 V versus Reversible hydrogen electrode, outperforming other spinel-based electrocatalysts. Systematic mechanism investigations reveal that the NO₃ ^-RR is mainly occurred on Fe sites, and introducing high-entropy compositions in tetrahedral sites regulates the adsorption strength of N and O-related intermediates on Fe for boosting the NO₃ ^-RR. The above findings offer a high-entropy platform to regulate the bandgap and enhance the electrocatalytic performance of spinel oxides.