Multicomponent Reactive Transport in an In Situ Zero-Valent Iron Cell

Yabusaki, Steven B.; Cantrell, Kirk J.; Sass, Bruce; Steefel, Carl I.

doi:10.1021/es001209f

Cited by 137 publications

(92 citation statements)

References 24 publications

(28 reference statements)

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“…While contact with the iron surface is desired for HE destruction, it is also true that interstitial pore water both inside and downgradient of PRB will be laden with Fe +2 , Fe +3 , and associated minerals [369,370]. Moreover, when the hydraulic conductivities of the PRB no longer match regional groundwater velocity, as can occur with iron aging, secondary mineral precipitation can occur near the upgradient edge of the PRBs [353,362,371,372].…”

Section: Chemical Reduction Using Zero-valent Iron (Fe 0 ) Ferrous Imentioning

confidence: 99%

Soils contaminated with explosives: Environmental fate and evaluation of state-of-the-art remediation processes (IUPAC Technical Report)

Kalderis

Juhasz

Boopathy

et al. 2011

Pure and Applied Chemistry

147

143

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An explosion occurs when a large amount of energy is suddenly released. This energy may come from an over-pressurized steam boiler, from the products of a chemical reaction involving explosive materials, or from a nuclear reaction that is uncontrolled. In order for an explosion to occur, there must be a local accumulation of energy at the site of the explosion, which is suddenly released. This release of energy can be dissipated as blast waves, propulsion of debris, or by the emission of thermal and ionizing radiation.Modern explosives or energetic materials are nitrogen-containing organic compounds with the potential for self-oxidation to small gaseous molecules (N 2 , H 2 O, and CO 2 ). Explosives are classified as primary or secondary based on their susceptibility of initiation. Primary explosives are highly susceptible to initiation and are often used to ignite secondary explosives, such as TNT (2,4,6-trinitrotoluene), RDX (1,3,5-trinitroperhydro-1,3,5-triazine), HMX (1,3,5,7-tetranitro-1,3,5,7-tetrazocane), and tetryl (N-methyl-N-2,4,6-tetranitroaniline).

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Section: Chemical Reduction Using Zero-valent Iron (Fe 0 ) Ferrous Imentioning

confidence: 99%

Soils contaminated with explosives: Environmental fate and evaluation of state-of-the-art remediation processes (IUPAC Technical Report)

Kalderis

Juhasz

Boopathy

et al. 2011

Pure and Applied Chemistry

147

143

View full text Add to dashboard Cite

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“…Several researchers (Karvonen 2004;Komnitsas et al 2007;Li and Benson 2005;Liang et al 2003;McMahon et al 1999;Puls et al 1999a;Sarr 2001;Vogan et al 1999;Yabusaki 2001) have reported that armouring on the surface of reactive materials and chemical clogging of pores, by precipitated compounds during chemical reactions inside the PRB, decrease the long-term performance parameters such as reactivity, porosity and permeability. Significant concerns relating to precipitation of iron and aluminium oxides and hydroxides also exist in alkaline PRBs with acidic groundwater in ASS terrain because their solubilities are pH-dependent.…”

Section: Introductionmentioning

confidence: 99%

Performance of a PRB for the Remediation of Acidic Groundwater in Acid Sulfate Soil Terrain

Indraratna

Regmi

Nghiem

et al. 2010

J. Geotech. Geoenviron. Eng.

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Contaminated groundwater resulting from pyrite oxidation of acid sulphate soils (ASS) is a major environmental problem in coastal Australia. A column test was carried out for an extended period with recycled concrete to study the efficiency of the reactive materials for neutralising acidic groundwater. Results show that the actual acid neutralisation capacity of the recycled concrete could decrease to less than 50% of the theoretical value due to armouring effects. Nevertheless, the performance is good as a spot treatment in Acid Sulphate Soil Terrain utilising a near-zero cost waste product. Based on the test results and site characterisation, a PRB with recycled concrete was designed and installed in ASS terrain on the Shoalhaven River floodplain, southeastern, Australia in October 2006. The performance of the PRB was studied over two and half years to assess the potential of recycled concrete (i) to neutralise the groundwater acidity and (ii) to remove the dissolved heavy metals such as iron and aluminium from in situ acidic groundwater. To date, performance monitoring of the PRB shows that recycled concrete can successfully improve the pH of groundwater from acidic to mildly alkaline. In addition, it successfully removes groundwater iron and aluminium. Results reported here also reveal a slow decrease in the performance of the PRB due to armouring effects probably caused by precipitation of iron and aluminium on the surface of the reactive recycled concrete materials.

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“…Fortunately, this water reduction reaction is slow and kinetically unfavorable in most environmental systems because of the presence of other oxidizing agents. Because Fe(0) has a high reductive capacity, researchers have begun using it to treat groundwater contaminated with redox-sensitive heavy metals, radionuclides, and organics, such as trichloroethene (TCE) (Yabusaki et al 2001), nitro aromatic compounds (Klausen et al 2003), Cr(VI) (Fruchter 2002), U(VI) (Gu et al 1998;Abdelouas et al 1999), and Tc(VII) (Cantrell et al 1995). These experiments provide some information on the chemical reactions that occur during the corrosion of Fe(0).…”

Section: Theoretical Considerationsmentioning

confidence: 99%

Corrosion of Metal Inclusions In Bulk Vitrification Waste Packages

Bacon¹,

Pierce²,

Wellman³

et al. 2006

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SummaryThe primary purpose of the work reported here is to analyze the potential effect of the release of technetium (Tc) from metal inclusions in bulk vitrification (BV) waste packages once they are placed in the Integrated Disposal Facility (IDF). As part of the strategy for immobilizing waste from the underground tanks at Hanford, selected wastes will be immobilized using BV. During analyses of the glass produced in engineering-scale tests, metal inclusions were found in the glass product. This report contains the results from experiments designed to quantify the corrosion rates of metal inclusions found in the glass product from Test ES-32B (AMEC 2005) and simulations designed to compare the rate of Tc release from the metal inclusions to the release of Tc from glass produced with the BV process. Due to the probability of oxidizing conditions surrounding the waste packages in the IDF, in the simulations the Tc in the metal inclusions and the glass is conservatively assumed to be released congruently as soluble TcO 4 -. The experimental results and modeling calculations (Bacon and McGrail 2005) show that the metal corrosion rate will, under all conceivable conditions at the IDF, be dominated by the presence of the passivating layer and corrosion products on the metal particles. As a result, the release of Tc from the metal particles at the surfaces of fractures in the glass releases at a rate similar to the Tc present as a soluble salt (McGrail et al. 2003;Pierce et al. 2005). The release of the remaining Tc in the metal is controlled by the dissolution of the glass matrix.The dissolution kinetics of iron [Fe(0)] was quantified under conditions of constant dissolved O 2 [O 2 (aq)] and in solutions that minimized the formation of a passive film on the metal surface. These tests were performed to determine the forward reaction rate for the metal inclusions in the BV glass. Single-pass flow through (SPFT) tests were conducted over the pH(23°C) range from 7.0 to 12.0 and temperature range from 23°C to 90°C. The presence of EDTA minimized the formation of a passive film and Fe-bearing secondary phase(s) during testing allowing us to determine the forward dissolution rate. These results indicate that the corrosion of Fe(0) is relatively insensitive to pH and temperature and the forward rate is 3 to 4 orders of magnitude higher than when a passive film and corrosion products are present. Tests conducted with Amasteel (a low carbon steel non-radioactive surrogate) and ES-32B metal indicated that the forward dissolution rates for both metals were similar, if not identical. In other words, the presence of P and 99 Tc in the ES-32B metal appeared to have little effect on the forward dissolution rate. These results indicate that the corrosion rate of the ES-32B metal at repository relevant conditions was not significantly less than the surrogate metal. Because the effects of temperature (E a = 15 ±5 kJ/mol at pH(23°C) = 9.0 based on Fe release from ES-32B metal) and solution pH (η = -0.13 ±0.02 at 70°C based on Fe releas...

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Multicomponent Reactive Transport in an In Situ Zero-Valent Iron Cell

Cited by 137 publications

References 24 publications

Soils contaminated with explosives: Environmental fate and evaluation of state-of-the-art remediation processes (IUPAC Technical Report)

Soils contaminated with explosives: Environmental fate and evaluation of state-of-the-art remediation processes (IUPAC Technical Report)

Performance of a PRB for the Remediation of Acidic Groundwater in Acid Sulfate Soil Terrain

Corrosion of Metal Inclusions In Bulk Vitrification Waste Packages

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