A facile method for access to high efficient piezo-photocatalytic synergy of Ba0.85Sr0.15TiO3 through tuning grain size, Curie temperature and energy band gap

Piezo-catalysis represents a promising and environmentally-friendly technology for dye degradation, but the commonly used BaTiO3 piezoelectric material still face bottleneck of relative low piezo-catalytic activity. Enhancement of its catalytic activity via diversified means is crucial for improving the degradation efficiency and implementation of water treatment. In this study, we synthesized Ba1-xSrxTiO3 nanoparticles utilizing the sol-gel method. The highest catalytic performance for degrading rhodamine B is at x = 0.15 through the piezo-photocatalytic synergy, displaying a degradation rate of 92.66 % within 18 min and an impressive reaction rate of 14.26 × 10−2 min−1, surpassing most of other BaTiO3-based materials. Importantly, the nanoparticles exhibited excellent catalytic degradation performance for a variety of pollutants under different environments. In addition, it is confirmed that Sr2+ doping can enhance the catalytic efficiency via three pathways, i.e. modifying energy band gap, modulating grain size as well as Curie temperature. This work provides a convenient strategy for the rational regulation of catalytic performance in BaTiO3-based piezoelectric materials.