4.5 Article

Influence of Na2S on the degradation kinetics of CCl4 in the presence of very pure iron

Journal

JOURNAL OF CONTAMINANT HYDROLOGY
Volume 98, Issue 3-4, Pages 128-134

Publisher

ELSEVIER
DOI: 10.1016/j.jconhyd.2008.02.003

Keywords

iron; sulphide; CCl4; degradation; hydrogen embrittlement; FeS

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This paper presents the results of kinetic studies to investigate the effect of FeS film formation on the degradation rate of CCl4 by 99.99% pure metallic iron. The film was formed by submersing metallic iron grains in an oxygen free HCO3-/CO32- electrolyte solution. When the grains had reached a quasi steady-state value of the corrosion potential, Na2S(aq) was injected. Upon injection, a mu m thick poorly crystalline FeS film formed immediately on the iron surface. Over time, the iron became strongly corroded and both the FeS film and the metallic iron grains began to crack leading to exposure of bare metallic iron to the solution. The effect of the surface film on the degradation rate of CCl4 was investigated following four periods of aging, 1, 10, 30, and 60 days. Relative to the controls, the 1-day sulfide-aged iron showed a substantial decrease in rate of degradation of CCl4. However, over time, the rate of degradation increased and surpassed the degradation rate obtained in the controls. It has been proposed that CCl4 is reduced to HCCl3 by metallic iron by electron transfer. The FeS film is substantially less conducting than the bulk iron metal or non-stoichiometric magnetite and from the results of this study, greatly decreases the rate of CCl4 degradation relative to iron that has not been exposed to Na2S. However, continued aging of the FeS film results in breakdown and stress-induced cracking of the film, followed by dissolution and cracking of the iron itself. The cracking of the bulk iron is believed to be a consequence of hydrogen embrittlement, which is promoted by sulfide. The increase in CCl4 degradation rate, as the FeS films age, suggests that the process of hydrogen cracking increases the surface area available for charge transfer. (C) 2008 Elsevier B.V. All rights reserved.

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