Biofilm inhibition mechanism of BiVO4 inserted zinc matrix in marine isolated bacteria

Biofilm plays an important role on microbial corrosion and biofouling in marine environments. Inhibiting biofilm formation on construction surfaces is of great importance. Photocatalytic material with visiblelight response, especially BiVO4, is regarded as a promising material for biofilm inhibition due to its green biocidal effect and high antibacterial efficiency. Approaches which can immobilize the photocatalytic particles onto metal surfaces with high mechanical strength are requisite. In this study, zinc matrixes were served as carriers for BiVO4 particles. The BiVO4-inserted zinc matrixes were successfully obtained by ultrasound assisted electrodeposition. The insertion content of BiVO4 showed positive correlation with ultrasound power. Highly enhanced biofilm inhibition properties were obtained by BiVO4 inserted zinc matrixes with an over 95% decreased bacterial coverage. It was proved that O-center dot(2)- (chief) and (OH)-O-center dot (subordinate) radicals were responsible for the high biocidal performance. Possible antibacterial mechanism was proposed, indicating that the photoinduced holes would both attack zinc crystals to generate active electrons to form O-center dot(2)- radicals, and react with H2O to generate (OH)-O-center dot, finally. Furthermore, corrosion resistance of the matrixes was proved to be stable due to the insertion of BiVO4. This study provides a potential application for photocatalyst in marine antifouling and anti-biocorrosion aspects. (C) 2021 Elsevier B.V. All rights reserved.

Automated summary

Biofilm plays a crucial role in microbial corrosion and biofouling in marine environments. Inhibiting biofilm formation on construction surfaces is important, and BiVO4 is considered a promising material for biofilm inhibition. In this study, zinc matrixes were used as carriers for BiVO4 particles to immobilize them onto metal surfaces. The study showed significantly enhanced biofilm inhibition properties with over 95% decreased bacterial coverage, attributing to the presence of O·2- and (OH)· radicals responsible for high biocidal performance.