Abstract
1,4-dioxane is an emerging contaminant that was used as a corrosion inhibitor with chlorinated solvents. Metal-activated persulfate can degrade dioxane but reaction kinetics have typically been characterized by a rapid decrease during the first 30 min followed by either a slower decrease or no further change (i.e., plateau). Our objective was to identify the factors responsible for this plateau and then determine if slow-release formulations of sodium persulfate and Fe(0) could provide a more sustainable degradation treatment. We accomplished this by conducting batch experiments where Fe(0)-activated persulfate was used to treat dioxane. Treatment variables included the timing at which the dioxane was added to the Fe(0)-persulfate reaction (T = 0 and 30 min) and including various products of the Fe(0)-persulfate reaction at T = 0 min (Fe(2+), Fe(3+), and SO(4)(2-)). Results showed that when dioxane was spiked into the reaction at 30 min, no degradation occurred; this is in stark contrast to the 60% decrease observed when added at T = 0 min. Adding Fe(2+) at the onset (T = 0 min) also severely halted the reaction and caused a plateau. This indicates that excess ferrous iron produced from the Fe(0)-persulfate reaction scavenges sulfate radicals and prevents further dioxane degradation. By limiting the release of Fe(0) in a slow-release wax formulation, degradation plateaus were avoided and 100% removal of dioxane observed. By using (14)C-labeled dioxane, we show that ∼40% of the dioxane carbon is mineralized within 6 d. These data support the use of slow-release persulfate and zerovalent iron to treat dioxane-contaminated water.