Room temperature synthesis of defective cerium oxide for efficient marine anti-biofouling

Mimicking marine algae to prevent marine biofouling on the submerged surface of engineering materials represents an alternative and promising approach to conventional toxic anti-biofouling strategy. Here, a novel CeO2 is synthesized by a simple room temperature approach. The as-synthesized CeO2 with rich oxygen vacancies exhibits significantly higher intrinsic haloperoxidase-like activity than the conventional CeO2 in catalyzing the bromination reaction of organic substrates, with a bromination reaction rate of 0.13 mu M min(-1) at a concentration of 0.05 mg mL(-1). In the presence of Br- and H2O2 oxidant, CeO2 demonstrates significant antibacterial efficacies against both Gram-negative Escherichia coli and Gram-positive Staphylococcus aureus, with a significant antibacterial efficiency of 88% and 90%, respectively. Field tests reveal that the plates containing the defective CeO2 (5 wt.%) can effectively hinder the marine biofouling in open ocean. This work provides a promising approach for the development of effective and green marine inorganic anti-foulants at room temperature.

Automated summary

This study explores a novel approach of mimicking marine algae to prevent marine biofouling on engineering materials, showing promising potential as an alternative to traditional toxic anti-biofouling strategies. The synthesized CeO2 exhibits significantly higher intrinsic haloperoxidase-like activity and antibacterial efficacy, effectively hindering marine biofouling in open ocean environments. This work provides a promising and green solution for developing effective marine inorganic anti-foulants at room temperature.