Journal
CHEMICAL ENGINEERING JOURNAL ADVANCES
Volume 11, Issue -, Pages -Publisher
ELSEVIER
DOI: 10.1016/j.ceja.2022.100331
Keywords
Persulfate decomposition; Kinetics; Mathematical model; pH effect; Sulfate radicals; Rate coefficient
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The decomposition of persulfate has wide applications in various processes such as polymerization, oxidation, and cellulose production. A kinetic model is developed by integrating dispersed information reported in the literature, and unknown rate coefficients are evaluated using experimental data. It is found that the different reactions in the decomposition process depend on the pH, with the thermal path being present at any pH. The model successfully describes the overall kinetic features of the process at 50 degrees C.
The decomposition of persulfate (S2O42-) is a relevant part of free-radical polymerizations in aqueous media, advanced oxidation processes and nanocellulose production. For the first time, dispersed information reported in the literature about the different reactions that occur in the process were consistently integrated into a kinetic model. A sequence of calculations is proposed to evaluate some unknown rate coefficients mainly at 50 degrees C using experimental kinetic data reported in the literature. It is proposed that the decomposition of persulfate occurs by a set of (at least) four parallel reactions one of which is first order (the thermal path) and the others second order. According to the model results, the predominance of each of them depends on the pH except for the thermal path that is present at any pH. Under strong acid and alkaline conditions at constant pH, first-order/pseudo first-order kinetics is obtained (the observable rate coefficient kd0 is constant). At intermediate pHs, where the concentration of sulfate radicals [SO4*-] is maximized, the second order character of the reaction between S2O42-and SO4*-and the autocatalytic-like behavior of the latter become evident (kd0 decrease with time). Notwithstanding the differences between theory and experiment for certain conditions observed in this work, the proposed mathematical model is able to describe the overall kinetic features of the process under study, at least at 50 degrees C. Recommendations are provided so that future experimental work carried out in different laboratories, is comparable.
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