Journal
SEPARATION AND PURIFICATION TECHNOLOGY
Volume 307, Issue -, Pages -Publisher
ELSEVIER
DOI: 10.1016/j.seppur.2022.122801
Keywords
water-soluble PDI derivatives; Iron-dopedTiO2; Organic pollutants; Photocatalysis; Environmental toxicity
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In this study, the authors successfully prepared two composite photocatalysts, TiO2@PDI-NapSO3H and Fe-TiO2@PDI-NapSO3H, by bonding water-soluble PDI derivatives with TiO2 or iron-doped TiO2. These photocatalysts showed improved performance in degrading phenol and diclofenac sodium (DCF) under visible light. The addition of PDI-NapSO3H enhanced the optical absorption properties of TiO2, while the doping of Fe in TiO2 prevented the recombination of photogenerated carriers. The Fe-TiO2@PDI-NapSO3H exhibited higher photocatalytic activity compared to TiO2@PDI-NapSO3H, with almost 99% degradation of phenol or DCF achieved within 90 or 120 minutes, respectively. The authors also discussed the effects of energy band structure and photogenerated carrier separation efficiency on the photocatalytic performance of Fe-TiO2@PDI-NapSO3H through various analyses. They proposed possible degradation pathways of DCF and explained the reduction of environmental toxicity after photocatalytic degradation.
In this paper, we successfully constructed two composite photocatalysts TiO2@PDI-NapSO3H and Fe-TiO2@PDI-NapSO3H by utilizing water-soluble PDI derivatives to bond with TiO2 or iron-doped TiO2. Their photocatalytic performance to degrade phenol and diclofenac sodium (DCF) under visible light were investigated. The results show that PDI-NapSO3H can effectively improve the optical absorption properties of TiO2. Furthermore, the oxygen vacancy produced by doping of Fe in TiO2 prevents the recombination of photogenerated carriers effectively. The larger conjugate plane of PDI-NapSO3H provides a convenient channel for the migration and separation of photogenerated carriers. Thus almost 99 % of phenol or DCF can be degraded by Fe-TiO2@PDI-NapSO3H within 90 or 120 min, respectively. However, the photocatalytic activity of Fe-TiO2@PDI-NapSO3H is better. The rate of phenol degradation is much higher than that of TiO2@PDI-NapSO3H. Further, through the photoelectric response characteristic analysis, radical trapping experiment and EPR test, the effects mechanism of the energy band structure, photogenerated carrier separation efficiency on the photocatalytic performance of Fe-TiO2@PDI-NapSO3H were discussed. In addition, the possible degradation pathways of DCF and the reasons for the obvious reduction of environmental toxicity after photocatalytic degradation were proposed.
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