Showing papers on "Magnesium peroxide published in 1997"

Control of BTEX Migration Using a Biologically Enhanced Permeable Barrier

Abstract: A permeable barrier system. consisting of a line of closely spaced wclls. was installed perpendicular to ground water flow to control the migration of a dissolved hydrocarhon plume. The wells were charged wiih concrete briquets that release oxygen and nitrate at a controlled rate. enhancing aerobic bio-degradation in the downgradient aquifer. Laboratory batch reactor experiments were conducted to identify concrete mixtures that slowly released oxygcn over an extended time period. Concretes prepared with urea hydrogen peroxide were unsatisfactory, while concretes prepared with calcium peroxide and a proprietary formalation of magnesium peroxide (ORC®) gradually released oxygen at a steadily declining rate. The 21 percent MgO2 conerete cylinders and briquets released oxygen at measurable rates for up to 300 days, while the 14 percent CaO2 briquets were exhausted by 100 days. A full-scale permeable barrier system using ORC was constructed at a gasoline-spill site. During the first 242 days of operation. total BTFX decreased from 17 to 3.4 mg/L. and dissolved oxygen increased from 0.4 to 1.8 mg/L. during transport through the barrier. Over time, BTEX treatment efficiencies declined. indicating the barrier system had becomc less effective in releasing oxygen and nutrients to the highly contaminated portion of the aquifer. Point dilution tests and sediment analyses performed at the conclusion of the project indicated that ihc aquifer in the vicinity of the remediation wells had been clogged by precipitation with iron minerals. This clogging is believed to result from high pH from the concrete and oxygen released by ihc ORC. Oxygen-releasing permeable barriers and other aerobic bioremediation processes should be used with caution in aquifers with high levels of dissolved iron.

Effects of Oxygen-Releasing Materials on Aerobic Bacterial Degradation Processes

Abstract: The aerobic microbial degradation of p-nitrophenol (PNP) and phenol was examined under oxygen-limiting conditions in the presence of three known oxygen-releasing materials: (1) polyvinylidene chloride-encapsulated sodium percarbonate; (2) REGENESIS oxygen-releasing compound (magnesium peroxide); and (3) PermeOx® solid peroxygen (calcium peroxide). The degradation of PNP or phenol in buffered solutions was measured in 40-mL reaction chambers containing 25 to 300 mg of oxygen-releasing materials in the presence of immobilized chemical-degrading bacteria. Radiometric studies were used to determine total chemical mineralization and material balances of 14C-residues. Degradation of PNP and phenol increased in proportion to both the supplemented amount and the relative oxygen content of each oxygen-releasing material. Comparison of actual to theoretical degradation, based on stoichiometry of balanced equations for mineralization, showed that chemical uptake (primary degradation) at lower concentrations...

Alkaline earth metal peroxide product

Abstract: A homogeneous calcium/magnesium peroxide, its manufacture and use are described. The new calcium/magnesium peroxide is suitable in particular as an additive used as source of oxygen and acid buffer, e.g. in the application, processing, treatment and/or disposal of various biomaterials.