Abstract

The light and stress dual-responsive Bi 2 O 2 (OH)NO 3 /BiOI heterojunction is developed, and the synergy of interfacial electric field and piezoelectric polarization enables it exceptional piezo-photocatalytic performance. • Bi 2 O 2 (OH)NO 3 /BiOI type-II heterostructure is created through in-situ deposition. • Bi 2 O 2 (OH)NO 3 /BiOI has 1.6 times higher surface potential than BON, suggesting a stronger electric field. • Built-in electric field and piezoelectric polarization greatly enhances charge separation. • It shows exceptional piezo-photocatalytic TH degradation of 80 % within just 10 min. Effective removal of recalcitrant pollutants is crucial for environmental protection. Tetracycline hydrochloride, as a representative recalcitrant organic pollutant, poses a potential threat to environmental integrity when present in aquatic ecosystems. Coupling piezoelectric polarization, capable of considerably promoting the photocharge separation, acts as a very prevalent and attractive strategy to improve the photocatalytic activity. In this study, an efficient piezo-photocatalytic system was developed in Bi 2 O 2 (OH)NO 3 /BiOI heterojunction by collaborating with interfacial electric field and vibration-induced piezoelectric polarization. The construction of type II heterojunction allows an interfacial electric field to propel the photogenerated electrons from BiOI to Bi 2 O 2 (OH)(NO 3 ) under visible light irradiation. The introduction of vibration-induced piezoelectric polarization field strengthens the interfacial electric field, which further promote the separation and migration of photogenerated charges. Profiting from the above advantages, Bi 2 O 2 (OH)(NO 3 )/BiOI heterojunction exhibited a remarkable piezo-photocatalytic performance, achieving an over 80% degradation efficiency of tetracycline hydrochloride within 10 min, which far surpasses that under individual photocatalysis or ultrasound-induced piezocatalysis and also exceeds most of the previously reported piezo-photocatalysts. The combination of electron paramagnetic resonance, piezoresponse force microscopy, COMSOL simulation, and photoelectrochemical tests are conducted to probe the synergistically-catalytic mechanism. This work not only elucidates the comprehensive impact of interfacial electric field and piezoelectric polarization on charge separation, but also highlights the tremendous potential of piezo-photocatalysis for environmental remediation.