Tuning of persulfate activation from free radical to non-radical pathway through the incorporation of non-redox magnesium oxide
Jawad, A; Zhan, K; Wang, H; et al.Shahzad, A; Zeng, Z; Wang, J; Zhou, X; Ullah, H; Chen, Z; Chen, Z
Date: 23 January 2020
Journal
Environmental Science & Technology
Publisher
American Chemical Society (ACS)
Publisher DOI
Abstract
Nonradical-based advanced oxidation processes for pollutants removal have attracted much attention due to their inherent advantages. Herein we report that magnesium oxides (MgO) in CuOMgO/Fe3O4 not only enhanced the catalytic properties but also switched the free radical peroxymonosulfate-activated process into the 1O2 based nonradical ...
Nonradical-based advanced oxidation processes for pollutants removal have attracted much attention due to their inherent advantages. Herein we report that magnesium oxides (MgO) in CuOMgO/Fe3O4 not only enhanced the catalytic properties but also switched the free radical peroxymonosulfate-activated process into the 1O2 based nonradical process. CuOMgO/Fe3O4 catalyst exhibited consistent performance in a wide pH range from 5.0 to 10.0, and the degradation kinetics were not inhibited by the common free radical scavengers, anions or natural organic matter. Quantitative structure activity relationships (QSARs) revealed the relationship between the degradation rate constant of 14 substituted phenols and their conventional descriptor variables (i.e. Hammett constants σ, σ−, σ+), half-wave oxidation potential (E1/2) and pKa values. QSARs together with kinetic isotopic effect (KIE) recognized the electron transfer as the dominant oxidation process. Characterizations and DFT calculation indicated that the incorporated MgO alters the copper sites to highly oxidized metals centers, offering a more suitable platform for PMS to generate metastable copper intermediates. This highly oxidized metals centers of copper played the key role in producing O2•− after accepting electron from another PMS molecule, and finally 1O2 as sole reactive species was generated from the direct oxidation of O2•− through thermodynamically feasible reactions.
Engineering
Faculty of Environment, Science and Economy
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