A universal chemical-induced tensile strain tuning strategy to boost oxygen-evolving electrocatalysis on perovskite oxides

Exploring effective, facile, and universal tuning strategies to optimize material physicochemical properties and catalysis processes is critical for many sustainable energy systems, but still challenging. Herein, we succeed to introduce tensile strain into various perovskites via a facile thermochemical reduction method, which can greatly improve material performance for the bottleneck oxygen-evolving reaction in water electrolysis. As an ideal proof-of-concept, such a chemical-induced tensile strain turns hydrophobic Ba5Co4.17Fe0.83O14-delta perovskite into the hydrophilic one by modulating its solid-liquid tension, contributing to its beneficial adsorption of important hydroxyl reactants as evidenced by fast operando spectroscopy. Both surface-sensitive and bulk-sensitive absorption spectra show that this strategy introduces oxygen vacancies into the saturated face-sharing Co-O motifs of Ba5Co4.17Fe0.83O14-delta and transforms such local structures into the unsaturated edge-sharing units with positive charges and enlarged electrochemical active areas, creating a molecular-level hydroxyl pool. Theoretical computations reveal that this strategy well reduces the thermodynamic energy barrier for hydroxyl adsorption, lowers the electronic work function, and optimizes the charge/electrostatic potential distribution to facilitate the electron transport between active sites and hydroxyl reactants. Also, this strategy is reliable for other single, double, and Ruddlesden-Popper perovskites. We believe that this finding will enlighten rational material design and in-depth understanding for many potential applications. Published under an exclusive license by AIP Publishing.

Automated summary

This study introduces tensile strain into perovskite materials through a facile thermochemical reduction method, improving material performance in the oxygen-evolving reaction. By modulating solid-liquid tension, the hydrophobic perovskite is transformed into a hydrophilic one, enhancing the adsorption of hydroxyl reactants. Surface-sensitive and bulk-sensitive absorption spectra confirm the effectiveness of this strategy in introducing oxygen vacancies and transforming local structures. Theoretical computations reveal reduced energy barriers for hydroxyl adsorption and optimized electron transport.