Efficient Catalytic Production of Reactive Oxygen Species through Piezoelectricity in Bismuth Sulfide Rich in Sulfur Vacancies
Xiaofeng Zhou, Jinzhou Liu, Shahzad Ali, Bo Shen, Jiwei Zhai, Niklas Hedin, Jiayin Yuan
Abstract
Sulfur (S) vacancies in metal sulfides are of interest in electrocatalysis and photoelectronics, but their effect on the generation of reactive oxygen species (ROS) during mechanical catalysis is unclear. This study investigates the impact of S-vacancies in defective bismuth sulfide (Bi 2 S 3– x ) on ROS production under ultrasonic irradiation and organic contaminant decomposition. S-vacancies disrupt the centrosymmetric structure of intrinsic Bi 2 S 3, inducing piezoelectric effects and enhancing the electrical energy in Bi 2 S 3– x . The positively charged S-vacancies in Bi 2 S 3– x promote the separation of ultrasound-activated electron–hole pairs by capturing electrons. As a result, the optimal rate of H 2 O 2 formation and the reaction rate constant for degrading Rhodamine B dye on Bi 2 S 3– x are found to be 1.9 and 37 times higher, respectively, than those on Bi 2 S 3 under ultrasonic irradiation. The nonzero catalytic efficiency in centrosymmetric Bi 2 S 3 is due to the flexoelectric catalytic effect from nonuniform strain. These results guide the piezocatalyst design and elucidate mechanical catalysis mechanisms.