Ranjbari Alireza, Adhikary Keshab Kumar, Kashif Muhammad, Anbari Alireza Pourvahabi, Siddhartha Tatwadhika Rangin, Kim Doyun, Yoon Seojin, Yoon Juan, Heynderickx Philippe M
Center for Green Chemistry and Environmental Biotechnology, Ghent University Global Campus, 119-5 Songdomunhwa-Ro, Yeonsu-Gu, Incheon, 406-840, South Korea; Department of Green Chemistry and Technology, Faculty of Bioscience Engineering, Ghent University, 653 Coupure Links, Ghent, B-9000, Belgium.
Center for Green Chemistry and Environmental Biotechnology, Ghent University Global Campus, 119-5 Songdomunhwa-Ro, Yeonsu-Gu, Incheon, 406-840, South Korea.
Chemosphere. 2025 Feb;371:144052. doi: 10.1016/j.chemosphere.2024.144052. Epub 2025 Jan 11.
The photocatalytic degradation of rhodamine B (RhB), a cationic dye, and bromocresol green (BCG), an anionic dye, was investigated using oxygen vacancy-enriched ZnO as the catalyst. These dyes were selected due to their differing charges and molecular structures, allowing for a deeper exploration of how these characteristics impact the degradation process. The catalyst was prepared by reducing ZnO with 10% H/Ar gas at 500 °C, and the introduction of oxygen vacancies was confirmed using various characterization techniques. A detailed kinetic model was developed to track dye degradation, accounting for adsorption and photocatalytic degradation simultaneously, both in solution and on the catalyst surface. The model incorporated the effect of pH on adsorption by considering the dissociation behavior of the dyes and their respective pK values. The study revealed that degradation primarily occurs on the catalyst surface at acidic pH, while at basic pH, degradation is more pronounced in the solution. DFT calculations supported these findings, showing that the electrostatic potential of the dyes shifts depending on pH, influencing their interaction with hydroxyl radicals or the catalyst surface. Quantum yield calculations indicate peak values of 6.32 10 molecules per photon for RhB at pH 11, and 4.20 10 for BCG at pH 3.
以富氧空位的氧化锌为催化剂,研究了阳离子染料罗丹明B(RhB)和阴离子染料溴甲酚绿(BCG)的光催化降解。选择这些染料是因为它们具有不同的电荷和分子结构,从而能够更深入地探究这些特性如何影响降解过程。通过在500°C下用10% H/Ar气体还原氧化锌来制备催化剂,并使用各种表征技术确认了氧空位的引入。建立了一个详细的动力学模型来跟踪染料降解,同时考虑了溶液中和催化剂表面上的吸附和光催化降解。该模型通过考虑染料的解离行为及其各自的pK值,纳入了pH对吸附的影响。研究表明,在酸性pH下,降解主要发生在催化剂表面,而在碱性pH下,溶液中的降解更为明显。密度泛函理论(DFT)计算支持了这些发现,表明染料的静电势根据pH值发生变化,影响它们与羟基自由基或催化剂表面的相互作用。量子产率计算表明,在pH 11时,RhB的量子产率峰值为每光子6.32×10个分子,在pH 3时,BCG的量子产率峰值为4.20×10个分子。
