Heterogeneous reduction of Tc(VII) by Fe(II) at the solid–water interface

Peretyazhko, T. S.; Zachara, John M.; Heald, Steve M.; Jeon, Byong‐Hun; Kukkadapu, Ravi; Liu, Chongxuan; Moore, Dean A.; Resch, Charles T.

doi:10.1016/j.gca.2008.01.004

Cited by 155 publications

(176 citation statements)

References 76 publications

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“…In contrast, when Fe(II) is sorbed onto other mineral phases, especially iron oxyhydroxides, surface-mediated heterogeneous catalysis becomes important and reduction of Tc(VII) to Tc(IV) takes place rapidly above pH 6 (Peretyazhko et al 2008a;Peretyazhko et al 2008b;Zachara et al 2007). …”

Section: Redox Chemistrymentioning

confidence: 99%

The Geochemistry of Technetium: A Summary of the Behavior of an Artificial Element in the Natural Environment

Icenhower¹,

Qafoku²,

Martin³

et al. 2008

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Section: Redox Chemistrymentioning

confidence: 99%

The Geochemistry of Technetium: A Summary of the Behavior of an Artificial Element in the Natural Environment

Icenhower¹,

Qafoku²,

Martin³

et al. 2008

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“…28 In SRS Tank Farm waste, it is assumed that the vast majority of technetium existing in sludge solids is present as Tc(IV) and relatively insoluble, in the form of hydrated technetium dioxide (TcO 2 xH 2 O) 29 and/or co-precipitated with iron(II) sorbed onto iron(III) oxide and/or oxyhydroxide particles. 30,31 In contrast, the majority of technetium existing in salt waste is assumed to be present as Tc(VII) and relatively soluble, in the form of sodium pertechnetate (NaTcO 4 ). 29 Some portion of the soluble technetium could also be present as a Tc(IV)-chelant complex 32 or as a Tc(VII)-solvent complex, 33 but these portions are expected to be minor in most SRS waste tanks due to the very low organic content.…”

Section: Solid/liquid Phase Technetium Partitioningmentioning

confidence: 99%

Chemical Differences Between Sludge Solids at the F and H Area Tank Farms

Reboul¹

2012

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“…However, when Fe(II) is adsorbed or surface precipitated on solid phases, especially oxyhydroxides of iron, a surface-mediated catalysis of Tc(VII) reduction is more rapid (Cui and Eriksen 1996a, Cui and Eriksen 1996b, Peretyazhko et al 2008a, Peretyazhko et al 2008b, Zachara et al 2007. Other experiments aimed at assessing the interaction of pertechnetate with iron sulfide minerals, such as mackinawite (FeS), pyrrhotite (Fe 7 S 8 ), and 2.17 greigite (Fe 3 S 4 ), showed that Tc(IV) has an affinity for the surface of sulfide minerals and, upon oxidation to form goethite and sulfate minerals, the…”

Section: Goethitementioning

confidence: 99%

“…The atomic structure of goethite, recently determined by Yang et al (2006), is shown in Figure 2.5. On the other hand, examining the reduced run products with X-ray absorption spectroscopy (XAS) methods (briefly described in Appendix A) has revealed that the 99 Tc-bearing phase is a separate, reduced Tc(IV) oxide phase and may not be substituting for Fe(III)-O in the host ferric oxyhydroxide phase (Burke et al 2006, Fredrickson et al 2004, Fredrickson et al 2009, Morris et al 2008, Peretyazhko et al 2008a, Watson et al 2001, Wharton et al 2000, Zachara et al 2007). In the most detailed study, Fredrickson and coworkers (Fredrickson et al 2009) found that Tc(IV)O 2 -like compounds could exist in a number of states, including physically separate phases or those that are inter-grown with Fe(III)-O compounds.…”

mentioning

confidence: 99%

Review of Potential Candidate Stabilization Technologies for Liquid and Solid Secondary Waste Streams

Pierce¹,

Mattigod²,

Westsik³

et al. 2010

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Executive SummaryPacific Northwest National Laboratory has initiated a waste-form testing program to support the longterm durability evaluation of a waste form for secondary wastes generated from the treatment and immobilization of Hanford radioactive tank wastes. The purpose of the work discussed in this report is to identify candidate stabilization technologies and getters that have the potential to successfully treat the secondary waste stream liquid effluent, mainly from off-gas scrubbers and spent solids, produced by the Hanford Tank Waste Treatment and Immobilization Plant (WTP). Down-selection to the most promising stabilization processes/waste forms is needed to support the design of a solidification treatment unit (STU) to be added to the Effluent Treatment Facility (ETF). To support key decision processes, an initial screening of the secondary liquid waste forms must be completed by February 2010. Later, more comprehensive and longer term performance testing will be conducted, following the guidance provided by the secondary waste-form selection, development, and performance evaluation roadmap. The resulting waste form will be compliant to regulations and performance criteria and will lead to cost-effective disposal of the secondary wastes.This report starts with a brief review of some of the most commonly used solidification formulations that would be candidates for secondary liquid waste streams. In this review, the available data on performance are discussed, and some preliminary recommendations are provided for materials that should undergo additional screening testing. We also 1) discuss options for disposal of WTP secondary solid waste streams, 2) provide a brief overview of standard regulatory test methods used for measuring contaminant leachability and waste-form physical strength (with emphasis on the U.S. Environmental Protection Agency's [EPA's] new methods as a screening tool for comparing waste solidification materials of interest), and 3) provide an overview of factors that must be considered in long-term performance testing, including state-of-the-art characterization tools that can provide the data needed to technically defend predictive modeling simulations of long-term material behavior. The long-term wasteform testing and solid and leachate characterization must be robust enough to effectively predict material performance in the Integrated Disposal Facility over the 10,000-year period of performance for the engineered system. The solidification technologies for liquid waste streams include cement/grout, containerized Cast Stone, phosphate-bonded ceramics, alkali-aluminosilicate geopolymers, hydroceramics, L-TEM, and fluidized-bed steam reforming (FBSR). In addition to these, other mature technologies and two compounds, namely goethite and sodalite (that are still being developed), that show considerable promise as waste forms or getters are also discussed. It is our recommendation, based upon the available literature, that Cast Stone, chemically bonded phosphate ceramics (Ceramicrete...

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Heterogeneous reduction of Tc(VII) by Fe(II) at the solid–water interface

Cited by 155 publications

References 76 publications

The Geochemistry of Technetium: A Summary of the Behavior of an Artificial Element in the Natural Environment

The Geochemistry of Technetium: A Summary of the Behavior of an Artificial Element in the Natural Environment

Chemical Differences Between Sludge Solids at the F and H Area Tank Farms

Review of Potential Candidate Stabilization Technologies for Liquid and Solid Secondary Waste Streams

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