Magnesiothermal reduction and doping strategies in engineered TiO2 for pharmaceutical degradation and CO2 conversion

Magnesiothermal reduction and doping strategies in engineered TiO2 for pharmaceutical degradation and CO2 conversion

Abstract Pharmaceutical contaminants in water pose a significant ecological risk and require advanced treatment solutions. In this study, the strategy of oxygen-deficient TiO2-x and doping is evaluated for its photocatalytic efficiency under visible light for pharmaceutical pollutant degradation, se...

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Bibliographic Details
Main Authors: Junguang Gao, Hashem O. Alsaab, Masoud Habibi Zare, Saeed Shirazian
Format: Article
Language:English
Published: Nature Portfolio 2025-08-01
Series:npj Clean Water
Online Access:https://doi.org/10.1038/s41545-025-00508-9
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Summary:Abstract Pharmaceutical contaminants in water pose a significant ecological risk and require advanced treatment solutions. In this study, the strategy of oxygen-deficient TiO2-x and doping is evaluated for its photocatalytic efficiency under visible light for pharmaceutical pollutant degradation, seawater purification and green fuel production. The oxygen vacancies reduced the band gap and improved visible light absorption and charge separation, allowing TiO2-x to achieve almost complete degradation of aspirin within 6 h. Mechanistic studies (EPR, LC-MS) revealed •O₂⁻ and h⁺ as the dominant reactive species. The TiO2-x (1:1) catalyst showed excellent stability and reusability. Modified catalysts (TiO2-Cu, TiO2-GO) were also evaluated, with TiO2-Cu and TiO2-x (1:1) showing superior removal of organic pollutants (>90%), natural organic matter (NOM) and divalent ions (Mg2+, Ca2+) in seawater. While efficient degradation reduced biotoxicity (95% EC50 reduction in the Microtox assay), incomplete mineralization in some systems resulted in toxic intermediates, highlighting the need for combined chemical and toxicity assessments. In addition, TiO2-x (1:1) and TiO2-GO showed increased activity in CO2 reduction. This work highlights oxygen vacancy engineering as a promising strategy for visible-light-driven environmental photocatalysis.
ISSN:2059-7037

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