Sulfidation
can enhance both the reactivity and selectivity (i.e.,
electron efficiency, εe) of zero-valent iron (ZVI)
in contaminant removal, which may make this technology cost-effective
for a wider range of water treatment applications. However, current
sulfidation methods involve either hazardous or unstable sulfidation
agents (e.g., Na2S, Na2S2O3, and Na2S2O4) or energy-intensive
preparations (e.g., mechanochemical sulfidation with elemental sulfur).
In this study, we demonstrate that very efficient sulfidation of microscale
ZVI (mZVI) can be achieved at all S/Fe molar ratios (∼100%
sulfidation efficiency, εs) simply by direct reaction
between elemental sulfur (S0) and ZVI in an aqueous suspension
at ambient temperature. In comparison, the εs values
obtained using Na2S, Na2S2O3, or Na2S2O4 as the sulfidation
agents were only ∼23, ∼75, and ∼38%, respectively.
The sulfidated mZVI produced using the new method reacts with trichloroethylene
(TCE) with very high rates and electron efficiencies: rate constants
and electron efficiencies were 800- and 79-fold higher than those
of the unsulfidated mZVI. The enhanced performance of this material,
together with the operational advantages of S0 for sulfidation
(including safety, stability, and cost), may make it a desirable product
for full-scale engineering applications.
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