Recent advances on the spherical metal oxides for sustainable degradation of antibiotics

TL;DR

This review discusses recent progress in designing spherical metal oxides with various microstructures to enhance photocatalytic degradation of antibiotics, aiming for sustainable water purification.

Contribution

It provides a comprehensive summary of the design, synthesis, and structure-property relationships of SMOs for antibiotic degradation, highlighting recent advances and future challenges.

Findings

Microstructure tuning improves active site exposure

Enhanced light utilization increases photocatalytic efficiency

Different SMOs show varied effectiveness in degrading antibiotics

Abstract

Due to the permanent harm to human health and ecosystem balance, antibiotic pollution in water has become an important direction of current environmental governance. Spherical metal oxides (SMOs) have been frequently utilized as effective heterogeneous photocatalysts for the efficient degradation of antibiotics due to the unique properties (e.g., strong light absorption ability, high separation efficiency of photo-generated electron hole pairs, and good catalytic activity). This review will firstly focus on summarizing the rational design and synthesis of SMOs with various tuned microstructures such as hollow, porous shell, yolk shell, core shell, and nanoflowers. These structures can expose more active sites, achieve a higher utilization rate of light, enhance the mass transfer efficiency and improve the effective diffusion of reactive oxygen species (ROS). Secondly, this review will mainly analyze the intrinsic relationship between the structure of SMOs and its photocatalytic property, the ability to generate ROS, and the degradation pathway for antibiotics. Moreover, the photocatalytic mechanisms and recent progress of different SMOs catalysts for degrading typical antibiotics are compared in detail. Finally, challenges and prospects of future direction in the development of SMOs for antibiotic degradation are reviewed. It is expected to provide a rational design of SMOs catalysts for efficient photocatalytic degradation of environmental pollutants.