Technology Description

Peroxygen ISCO processes include catalyzed H₂O₂ propagations (CHP) (i.e., modified Fenton's reagent) and activated persulfate. In CHP, hydrogen peroxide decomposition is catalyzed by soluble iron or naturally occurring subsurface minerals and results in the generation of a suite of oxidants, reductants, and nucleophiles, providing a universal treatment mixture capable of degrading oxidized, sorbed, and DNAPL contaminants. The primary disadvantage is low hydrogen peroxide stability. However, recent results from the Strategic Environmental Research and Development Program (SERDP) project ER-1288 demonstrate that hydrogen peroxide can be stabilized through the addition of salts of some organic acids, such as phytate, allowing the oxidant source to move greater distances downgradient from injection wells. Activated persulfate involves the use of persulfate anion (S₂O₈^2-) and an activator, such as iron or hydroxide, to generate a mixture of reactive oxygen species. Activated persulfate has similar reactivity to CHP and can destroy a wide range of contaminants. Persulfate is more stable than hydrogen peroxide, with a half-life of 100 to 500 days. Disadvantages include its higher cost relative to hydrogen peroxide and the lack of stability of some of the activators.