Oxygen-vacancy-enhanced piezo-photocatalytic performance of AgNbO3

Piezo-photocatalysis (implement by ultrasound vibration and UV-vis light irradiation), a new-emerging strategy, can suppress the rapid recombination of electrons and holes to enhance the catalytic perfor-mance. The modulation of interface structures (e.g., the introduction of oxygen vacancies, OVs) plays a significant role in the charge-transfer and the catalytic activity. In this paper, the AgNbO3 (ANO) powder was prepared by a facile hydrothermal method. Based on this, we introduce OVs into ANO successfully by annealing in N-2 (ANO-N-2). The ANO-N-2 with OVs exhibits much better piezo-photocatalytic activity for degradation of Rhodamine B (RhB) than the ANO. The result found that OVs can narrow the band gap and improve the UV-vis light absorption, and most importantly, promote the separation of electron hole pairs under electric field to enhance the piezo-photocatalytic performance. The work thus supplies an in-depth understanding of the mechanism between OVs and piezo-photocatalytic performance. (C) 2021 Acta Materialia Inc. Published by Elsevier Ltd. All rights reserved.

Automated summary

Piezo-photocatalysis is a new-emerging strategy that can enhance catalytic performance by modulating interface structures such as introducing oxygen vacancies. In this study, the introduction of oxygen vacancies significantly improved the piezo-photocatalytic activity of AgNbO3 powder, narrowing the band gap and enhancing UV-vis light absorption. The findings suggest that oxygen vacancies play a crucial role in promoting the separation of electron hole pairs to enhance piezo-photocatalytic performance.