AI Article Synopsis
- High-entropy Fe-based spinel oxide nanosheets (AFeO), measuring approximately 4.3 nm in thickness, are developed to enhance electrocatalytic performance by increasing surface area and active sites.
- These nanosheets show a reduced bandgap compared to typical Fe-based spinel oxides, allowing for a transition from semiconductor to metalloid properties.
- As a result, AFeO exhibits superior performance in nitrate reduction to ammonia, achieving a yield rate of about 2.1 mmol h cm at -0.5 V, primarily driven by the optimized adsorption on Fe sites.
Article 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., (CoNiZnMgCu)FeO; denotes AFeO) 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 AFeO 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 AFeO nanosheets manifest excellent performance for the nitrate reduction reaction (NO RR) to ammonia (NH), with a NH yield rate of ≈2.1 mmol h cm at -0.5 V versus Reversible hydrogen electrode, outperforming other spinel-based electrocatalysts. Systematic mechanism investigations reveal that the NO 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 NO RR. The above findings offer a high-entropy platform to regulate the bandgap and enhance the electrocatalytic performance of spinel oxides.
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| http://dx.doi.org/10.1002/adma.202403958 | DOI Listing |
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