Review on strategies toward efficient piezocatalysis of BaTiO3 nanomaterials for wastewater treatment through harvesting vibration energy

An emerging, environmentally friendly and sustainable method of decomposition wastewater urgently needs to be proposed due to the environmental crisis and the limitations of traditional treatment technologies. The pie-zocatalysis which convents vibration energy into electrical energy in dealing with dye wastewater is considered as a promising technology for environmental wastewater treatment owing to its environmental friendliness and sustainability. Piezocatalytic BaTiO3 catalyst, with the advantages of high stability, environment friendly and easy to adjust morphology, is an ideal candidate for the effective decomposition of harmful organic wastewater. Meanwhile, there are many strategies to enhance the piezocatalytic performance of BaTiO3 catalysts, including controlling morphology, doping element, electrically-poling, building heterostructure, coating noble metal, mixing carbon, composing polymer scaffold and increasing active sites. In this review, the synthesis of piezo-electric BaTiO3 catalysts, the mechanism of BaTiO3 piezocatalysis for wastewater treatment, the piezocatalytic energy sources of the BaTiO3-based materials and the strategies of enhanced BaTiO3-based piezocatalysis per-formance are introduced. Finally, the conclusions and perspectives of the BaTiO3-based piezocatalysis are put forward to providing a direction for the future work.

Automated summary

Due to the environmental crisis and the limitations of traditional treatment technologies, there is an urgent need to propose an emerging, environmentally friendly, and sustainable method of decomposing wastewater. Piezocatalytic BaTiO3 catalyst is considered an ideal candidate for the effective decomposition of harmful organic wastewater, and there are many strategies to enhance its performance. This review introduces the synthesis of piezo-electric BaTiO3 catalysts, the mechanism of BaTiO3 piezocatalysis for wastewater treatment, the piezocatalytic energy sources, and strategies for enhancing its performance. The conclusions and perspectives of BaTiO3-based piezocatalysis are also discussed.