Your search keyword '"Jiamin Wan"' showing total 25 results

1. Additive Surface Complexation Modeling of Uranium(VI) Adsorption onto Quartz-Sand Dominated Sediments

Author

Wenming Dong and Jiamin Wan

Subjects

Geologic Sediments, Water Pollutants, Radioactive, Goethite, Surface Properties, South Carolina, Analytical chemistry, Mineralogy, chemistry.chemical_element, Adsorption, Soil Pollutants, Radioactive, Environmental Chemistry, Kaolinite, Humic acid, Kaolin, Quartz, Humic Substances, chemistry.chemical_classification, Minerals, Mineral, Temperature, General Chemistry, Models, Theoretical, Uranium, Silicon Dioxide, Kinetics, chemistry, visual_art, visual_art.visual_art_medium, Iron Compounds, Geology

Abstract

Many aquifers contaminated by U(VI)-containing acidic plumes are composed predominantly of quartz-sand sediments. The F-Area of the Savannah River Site (SRS) in South Carolina (USA) is an example. To predict U(VI) mobility and natural attenuation, we conducted U(VI) adsorption experiments using the F-Area plume sediments and reference quartz, goethite, and kaolinite. The sediments are composed of ∼96% quartz-sand and 3-4% fine fractions of kaolinite and goethite. We developed a new humic acid adsorption method for determining the relative surface area abundances of goethite and kaolinite in the fine fractions. This method is expected to be applicable to many other binary mineral pairs, and allows successful application of the component additivity (CA) approach based surface complexation modeling (SCM) at the SRS F-Area and other similar aquifers. Our experimental results indicate that quartz has stronger U(VI) adsorption ability per unit surface area than goethite and kaolinite at pH ≤ 4.0. Our modeling results indicate that the binary (goethite/kaolinite) CA-SCM under-predicts U(VI) adsorption to the quartz-sand dominated sediments at pH ≤ 4.0. The new ternary (quartz/goethite/kaolinite) CA-SCM provides excellent predictions. The contributions of quartz-sand, kaolinite, and goethite to U(VI) adsorption and the potential influences of dissolved Al, Si, and Fe are also discussed.

Published

2014

2. Persistent Source Influences on the Trailing Edge of a Groundwater Plume, and Natural Attenuation Timeframes: The F-Area Savannah River Site

Author

Miles E. Denham, Susan S. Hubbard, Tetsu K. Tokunaga, Jiamin Wan, and Wenming Dong

Subjects

Hydrology, Geologic Sediments, Water Pollutants, Radioactive, Nitrates, South Carolina, Savannah River Site, Attenuation, General Chemistry, Models, Theoretical, Tritium, Natural (archaeology), Plume, Radioactive Waste, Water Movements, Uranium, Environmental Chemistry, Trailing edge, National laboratory, Groundwater, Geology, Environmental Monitoring

Abstract

At the Savannah River Site's F-Area, wastewaters containing radionuclides were disposed into seepage basins for decades. After closure and capping in 1991, the U.S. Department of Energy (DOE) has being monitoring and remediating the groundwater plume. Despite numerous studies of the plume, its persistence for over 20 years has not been well understood. To better understand the plume dynamics, a limited number of deep boreholes were drilled to determine the current plume characteristics. A mixing model was developed to predict plume tritium and nitrate concentrations. We found that the plume trailing edges have emerged for some contaminants, and that contaminant recharge from the basin's vadose zone is still important. The model's estimated time-dependent basin drainage rates combined with dilution from natural recharge successfully predicted plume tritium and nitrate concentrations. This new understanding of source zone influences can help guide science-based remediation, and improve predictions of the natural attenuation timeframes.

Published

2012

3. Effects of Organic Carbon Supply Rates on Uranium Mobility in a Previously Bioreduced Contaminated Sediment

Author

Rebecca A. Daly, Mary K. Firestone, Eoin L. Brodie, Jiamin Wan, Tetsu K. Tokunaga, Yongman Kim, and Terry C. Hazen

Subjects

Geologic Sediments, Time Factors, Iron, Carbonates, chemistry.chemical_element, Redox, Uranyl carbonate, chemistry.chemical_compound, Bioremediation, Nitrate, Soil Pollutants, Environmental Chemistry, Total organic carbon, Environmental engineering, Sediment, General Chemistry, Uranium, Carbon, RNA, Bacterial, Biodegradation, Environmental, chemistry, Environmental chemistry, Carbonate, Geobacter, Oxidation-Reduction

Abstract

Bioreduction-based strategies for remediating uranium (U)-contaminated sediments face the challenge of maintaining the reduced status of U for long times. Because groundwater influxes continuously bring in oxidizing terminal electron acceptors (O2, NO3(-)), it is necessary to continue supplying organic carbon (OC) to maintain the reducing environment after U bioreduction is achieved. We tested the influence of OC supply rates on mobility of previously microbial reduced uranium U(IV) in contaminated sediments. We found that high degrees of U mobilization occurred when OC supply rates were high, and when the sediment still contained abundant Fe(III). Although 900 days with low levels of OC supply minimized U mobilization, the sediment redox potential increased with time as did extractable U(VI) fractions. Molecular analyses of total microbial activity demonstrated a positive correlation with OC supply and analyses of Geobacteraceae activity (RT-qPCR of 16S rRNA) indicated continued activity even when the effluent Fe(II) became undetectable. These data support our hypothesis on the mechanisms responsible for remobilization of U under reducing conditions; that microbial respiration caused increased (bi)carbonate concentration and formation of stable uranyl carbonate complexes, thereby shifted U(IV)/U(VI) equilibrium to more reducing potentials. The data also suggested that low OC concentrations could not sustain the reducing condition of the sediment for much longer time. Bioreduced U(IV) is not sustainable in an oxidizing environment for a very long time.

Published

2008

4. Real-Time X-ray Absorption Spectroscopy of Uranium, Iron, and Manganese in Contaminated Sediments During Bioreduction

Author

Steve R. Sutton, Tetsu K. Tokunaga, Matthew Newville, Antonio Lanzirotti, Yongman Kim, William Rao, and Jiamin Wan

Subjects

Total organic carbon, Geologic Sediments, Manganese, Water Pollutants, Radioactive, X-ray absorption spectroscopy, Absorption spectroscopy, Iron, Spectrum Analysis, X-Rays, chemistry.chemical_element, General Chemistry, Uranium, Redox, Bioremediation, chemistry, Environmental Chemistry, Solubility, Oxidation-Reduction, Water Pollutants, Chemical, Nuclear chemistry

Abstract

The oxidation status of uranium in sediments is important because the solubility of this toxic and radioactive element is much greater for U(VI) than for U(IV) species. Thus, redox manipulation to promote precipitation of UO2 is receiving interest as a method to remediate U-contaminated sediments. Presence of Fe and Mn oxides in sediments at much higher concentrations than U requires an understanding of their redox status as well. This study was conducted to determine changes in oxidation states of U, Fe, and Mn in U-contaminated sediments from Oak Ridge National Laboratory. Oxidation states of these elements were measured in real-time and nondestructively using X-ray absorption spectroscopy on sediment columns supplied with synthetic groundwater containing organic carbon (OC, 0, 3, 10, 30, and 100 mM OC as lactate) for over 400 days. In sediments supplied with OCor = 30 mM, 80% of the U was reduced to U(IV), with transient reoxidation at about 150 days. Mn(III,IV) oxides were completely reduced to Mn(II) in sediments infused with OCor = 3 mM. However, Fe remained largely unreduced in all sediment columns, showing that Fe(III) can persist as an electron acceptor in reducing sediments over long times. This result in combination with the complete reduction of all other potential electron acceptors supports the hypothesis that the reactive Fe(III) fraction was responsible for reoxidizing U(IV).

Published

2008

5. Geochemical Controls on Contaminant Uranium in Vadose Hanford Formation Sediments at the 200 Area and 300 Area, Hanford Site, Washington

Author

Steven M. Heald, Jiamin Wan, James P. McKinley, John M. Zachara, and David E. McCready

Subjects

education.field_of_study, Waste management, Hanford Site, Metatorbernite, Geochemistry, Soil Science, chemistry.chemical_element, Boltwoodite, Uranium, Uranyl, chemistry.chemical_compound, chemistry, Vadose zone, education, Geology, Groundwater, Uranophane

Abstract

Long-term historic spills of uranium at the 300 Area fuel fabrication site (58,000 kg of disposed uranium over 32 yr) and at the 200 East Area BX tank farm (7000 kg of spilled uranium in one event), both within the Hanford formation in the Hanford Site, Washington State, were investigated by subsurface sampling and subsequent microscale investigations of excavated samples. The 200 Area sediments contained uranyl silicate mineralization (sodium boltwoodite) in restrictive microfractures in granitic clasts, in the vadose zone over a narrow range in depth. Well logging and column experiments indicated that tank wastes migrated deeper than observed in core samples. The 300 Area sediments included metatorbernite and uranium at low concentrations associated with detrital aluminosilicates, along with other mineral phases that could accommodate uranyl, such as uranophane and calcium carbonate. The association of contaminant uranyl with Hanford formation sediments provided a persistent source of uranium to groundwater. The results of both studies suggest that the formation of secondary solid uranyl-bearing phases infl uences the subsequent release of uranium to the environment and that our understanding of these processes and individual waste sites is incomplete.

Published

2007

6. Uranium Reduction in Sediments under Diffusion-Limited Transport of Organic Carbon

Author

Jasquelin Peña, Matthew Newville, Tetsu K. Tokunaga, Mary K. Firestone, Eoin L. Brodie, Jiamin Wan, Steve R. Sutton, and Antonio Lanzirotti, and Terry C. Hazen

Subjects

Geologic Sediments, Time Factors, Diffusion, chemistry.chemical_element, Soil Pollutants, Soil Pollutants, Radioactive, Environmental Chemistry, Trypsin, Biomass, Organic Chemicals, Soil Microbiology, Total organic carbon, Waste management, Chemistry, Biological Transport, General Chemistry, Hydrogen-Ion Concentration, Contamination, Uranium, Uranium Compounds, Carbon, Oxygen, Biodegradation, Environmental, Environmental chemistry, Uranyl Nitrate, Oxidation-Reduction, Electron Probe Microanalysis

Abstract

Costly disposal of uranium (U) contaminated sediments is motivating research on in situ U(VI) reduction to insoluble U(IV) via directly or indirectly microbially mediated pathways. Delivery of organic carbon (OC) into sediments for stimulating U bioreduction is diffusion-limited in less permeable regions of the subsurface. To study OC-based U reduction in diffusion-limited regions, one slightly acidic and another calcareous sediment were treated with uranyl nitrate, packed into columns, then hydrostatically contacted with tryptic soy broth solutions. Redox potentials, U oxidation state, and microbial communities were well correlated. At average supply rates of 0.9 micromol OC (g sediment)(-1) day(-1), the U reduction zone extended to only about35-45 mm into sediments. The underlying unreduced U(VI) zone persisted over 600 days because the supply of OC was diffusion-limited and metabolized within a short distance. These results also suggestthat low U concentrations in groundwater samples from OC-treated sediments are not necessarily indicative of pervasive U reduction because interior and exterior regions of such sediment blocks can contain primarily U(VI) and U(IV), respectively.

Published

2005

7. Reoxidation of Bioreduced Uranium under Reducing Conditions

Author

Mary K. Firestone, Zheming Wang, Tetsu K. Tokunaga, Eoin L. Brodie, Jiamin Wan, Stephen R. Sutton, Zuoping Zheng, Don Herman, and Terry C. Hazen

Subjects

Environmental remediation, Iron, chemistry.chemical_element, Redox, Uranyl carbonate, Metal, chemistry.chemical_compound, Chemical Precipitation, Soil Pollutants, Radioactive, Environmental Chemistry, Soil Microbiology, chemistry.chemical_classification, Chemistry, General Chemistry, Actinide, Hydrogen-Ion Concentration, Uranium, Electron acceptor, Uranyl, Kinetics, Biodegradation, Environmental, Solubility, visual_art, Environmental chemistry, visual_art.visual_art_medium, Oxidation-Reduction, Nuclear chemistry

Abstract

Nuclear weapons and fuel production have left many soils and sediments contaminated with toxic levels of uranium (U). Although previous short-term experiments on microbially mediated U(VI) reduction have supported the prospect of immobilizing the toxic metal through formation of insoluble U(IV) minerals, our longer-term (17 months) laboratory study showed that microbial reduction of U can be transient, even under sustained reducing conditions. Uranium was reduced during the first 80 days, but later (100-500 days) reoxidized and solubilized, even though a microbial community capable of reducing U(VI) was sustained. Microbial respiration caused increases in (bi)-carbonate concentrations and formation of very stable uranyl carbonate complexes, thereby increasing the thermodynamic favorability of U(IV) oxidation. We propose that kinetic limitations including restricted mass transfer allowed Fe-(III) and possibly Mn(IV) to persist as terminal electron acceptors (TEAs) for U reoxidation. These results show that in-situ U remediation by organic carbon-based reductive precipitation can be problematic in sediments and groundwaters with neutral to alkaline pH, where uranyl carbonates are most stable.

Published

2005

8. Hexavalent Uranium Diffusion into Soils from Concentrated Acidic and Alkaline Solutions

Author

Jasquelin Peña, Tetsu K. Tokunaga, Jiamin Wan, Matthew Newville, and Stephen R. Sutton

Subjects

Surface diffusion, Spectrum Analysis, Diffusion, Mineralogy, chemistry.chemical_element, Sediment, Sorption, General Chemistry, Hydrogen-Ion Concentration, Uranium, complex mixtures, Soil contamination, chemistry, Environmental chemistry, Soil water, Earth Sciences, Soil Pollutants, Radioactive, Environmental Chemistry, Adsorption, Absorption (chemistry), Environmental Monitoring

Abstract

Uranium contamination of soils and sediments often originates from acidic or alkaline waste sources, with diffusion being a major transport mechanism. Measurements of U(VI) diffusion from initially pH 2 and pH 11 solutions into a slightly alkaline Altamont soil and a neutral Oak Ridge soil were obtained through monitoring uptake from boundary reservoirs and from U concentration profiles within soil columns. The soils provided pH buffering, resulting in diffusion at nearly constant pH. Micro X-ray absorption near edge structure spectra confirmed that U remained in U(VI) forms in all soils. Time trends of U(VI) depletion from reservoirs and U(VI) concentration profiles within soil columns yielded Kdvalues consistent with those determined in batch tests at similar concentrations (approximately 1 mM) and much lower than values for sorption at much lower concentrations (nM to microM). These results show that U(VI) transport at high concentrations can be relatively fast at non-neutral pH, with negligible surface diffusion, because of weak sorption.

Published

2004

9. Influence of Calcium Carbonate on U(VI) Sorption to Soils

Author

Tetsu K. Tokunaga, Jiamin Wan, and Zuoping Zheng

Subjects

chemistry.chemical_element, Mineralogy, Sorption, General Chemistry, Hydrogen-Ion Concentration, Calcium, complex mixtures, Uranyl carbonate, Calcium Carbonate, Partition coefficient, Ferrihydrite, chemistry.chemical_compound, Calcium carbonate, Solubility, chemistry, Desorption, Environmental chemistry, Clay, Soil Pollutants, Radioactive, Uranium, Environmental Chemistry, Aluminum Silicates, Adsorption, Clay minerals

Abstract

The high stability of calcium uranyl carbonate complexes in the circumneutral pH range has a strong impact on U(VI) sorption in calcareous soils. To quantify this influence, sorption of U(VI) to soils in the presence of naturally occurring calcium carbonate was investigated by conducting batch experiments in which either U(VI) concentration or solution pH was varied. Two soils containing different calcium carbonate concentrations were selected, one from Oak Ridge, TN, and another from Altamont Pass, CA. The results show that the presence of calcium carbonate in soils strongly affects U(VI) sorption. Higher concentrations of soil calcium carbonate lead to a pronounced suppression of the pH-dependent sorption curve in the neutral pH range because of the formation of a very stable neutral complex of calcium uranyl carbonate in solution. A surface complexation model considering both strong and weak sites for ferrihydrite and ionizable hydroxyl sites for clay minerals was compared with experimental results, and U(VI) binding parameters were reasonably estimated. Fair agreement was found between the model predictions and sorption data, which span a wide range of U(VI) concentrations and pH. The results also show that appropriate solution-to-solid ratios need to be used when measuring distribution coefficients in calcareous soils to avoid complete CaCO3 dissolution and consequent dilution of calcium uranyl carbonate complexes.

Published

2003

10. Aqueous uranium(VI) concentrations controlled by calcium uranyl vanadate precipitates

Author

Li Yang, Tetsu K. Tokunaga, Yongman Kim, and Jiamin Wan

Subjects

Langmuir, Time Factors, Inorganic chemistry, chemistry.chemical_element, chemistry.chemical_compound, Environmental Chemistry, Chemical Precipitation, Vanadate, Solubility, Groundwater, Minerals, Aqueous solution, Water, General Chemistry, Uranium, Hydrogen-Ion Concentration, Uranyl, Uranium Compounds, Tyuyamunite, Solutions, chemistry, Thermodynamics, Vanadates, Oxidation-Reduction, Water Pollutants, Chemical, Uranophane

Abstract

Elevated concentrations of U in contaminated environments necessitate understanding controls on its solubility in groundwaters. Here, calculations were performed to compare U(VI) concentrations expected in typical oxidizing groundwaters in equilibrium with different U(VI) minerals. Among common U(VI) minerals, only tyuyamunite (Ca(UO(2))(2)V(2)O(8)·8H(2)O), uranophane (Ca(UO(2))(2)(SiO(3)OH)(2)·5H(2)O), and a putative well-crystallized becquerelite (Ca(UO(2))(6)O(4)(OH)(6)·8H(2)O) were predicted to control U concentrations around its maximum contaminant level (MCL = 0.13 μM), albeit over narrow ranges of pH. Given the limited information available on uranyl vanadates, room temperature Ca-U-V precipitation experiments were conducted in order to compare aqueous U concentrations with tyuyamunite equilibrium predictions. Measured U concentrations were in approximate agreement with predictions based on Langmuir's estimated ΔG(f)°, although the precipitated solids were amorphous and had wide ranges of Ca/U/V molar ratios. Nevertheless, high initial U concentrations were decreased to below the MCL over the pH range 5.5-6.5 in the presence of newly formed CaUV solids, indicating that such solids can be important in controlling U in some environments.

Published

2012

11. Uranium(VI) adsorption and surface complexation modeling onto background sediments from the F-Area Savannah River Site

Author

James A. Davis, Tetsu K. Tokunaga, Wenming Dong, and Jiamin Wan

Subjects

Geologic Sediments, Goethite, Georgia, Savannah River Site, Mineralogy, chemistry.chemical_element, Aquifer, Adsorption, Environmental Chemistry, Kaolinite, Kaolin, Quartz, Groundwater, geography, Minerals, geography.geographical_feature_category, General Chemistry, Uranium, Hydrogen-Ion Concentration, Plume, chemistry, Models, Chemical, visual_art, visual_art.visual_art_medium, Geology, Iron Compounds, Radioactive Pollutants

Abstract

The mobility of an acidic uranium waste plume in the F-Area of Savannah River Site is of great concern. In order to understand and predict uranium mobility, U(VI) adsorption experiments were performed as a function of pH using background F-Area aquifer sediments and reference goethite and kaolinite (major reactive phases of F-Area sediments), and a component-additivity (CA) based surface complexation model (SCM) was developed. Our experimental results indicate that the fine fractions (≤45 μm) in sediments control U(VI) adsorption due to their large surface area, although the quartz sands show a stronger adsorption ability per unit surface area than the fine fractions at pH5.0. Kaolinite is a more important sorbent for U(VI) at pH4.0, while goethite plays a major role at pH4.0. Our CA model combines an existing U(VI) SCM for goethite and a modified U(VI) SCM for kaolinite along with estimated relative surface area abundances of these component minerals. The modeling approach successfully predicts U(VI) adsorption behavior by the background F-Area sediments. The model suggests that exchange sites on kaolinite dominate U(VI) adsorption at pH4.0, goethite and kaolinite edge sites cocontribute to U(VI) adsorption at pH 4.0-6.0, and goethite dominates U(VI) adsorption at pH6.0.

Published

2011

12. Method to attenuate U(VI) mobility in acidic waste plumes using humic acids

Author

Wenming Dong, Tetsu K. Tokunaga, and Jiamin Wan

Subjects

chemistry.chemical_classification, Water Pollutants, Radioactive, Environmental remediation, Environmental engineering, chemistry.chemical_element, Fresh Water, General Chemistry, Uranium, Biodegradation, Hydrogen-Ion Concentration, Mining, Kinetics, Adsorption, chemistry, Reagent, Desorption, Environmental chemistry, Environmental Chemistry, Humic acid, Leaching (metallurgy), Environmental Restoration and Remediation, Humic Substances

Abstract

Acidic uranium (U) contaminated plumes have resulted from acid-extraction of plutonium during the Cold War and from U mining and milling operations. A sustainable method for in-situ immobilization of U under acidic conditions is not yet available. Here, we propose to use humic acids (HAs) for in-situ U immobilization in acidic waste plumes. Our laboratory batch experiments show that HA can adsorb onto aquifer sediments rapidly, strongly and practically irreversibly. Adding HA greatly enhanced U adsorption capacity to sediments at pH below 5.0. Our column experiments using historically contaminated sediments from the Savannah River Site under slow flow rates (120 and 12 m/y) show that desorption of U and HA were non-detectable over 100 pore-volumes of leaching with simulated acidic groundwaters. Upon HA-treatment, 99% of the contaminant [U] was immobilized at pH < 4.5, compared to 5% and 58% immobilized in the control columns at pH 3.5 and 4.5, respectively. These results demonstrated that HA-treatment is a promising in-situ remediation method for acidic U waste plumes. As a remediation reagent, HAs are resistant to biodegradation, cost effective, nontoxic, and easily introducible to the subsurface.

Published

2011

13. Potential remediation approach for uranium-contaminated groundwaters through potassium uranyl vanadate precipitation

Author

Jiamin Wan, Yongman Kim, and Tetsu K. Tokunaga

Subjects

Water Pollutants, Radioactive, Environmental remediation, chemistry.chemical_element, General Chemistry, Uranium, Uranyl, Carnotite, Water Purification, chemistry.chemical_compound, Bioremediation, Autunite, chemistry, Water Supply, Groundwater pollution, Environmental chemistry, Oxidizing agent, Potassium, Environmental Chemistry, Chemical Precipitation, Soil Pollutants, Radioactive, Thermodynamics, Vanadates

Abstract

Methods for remediating groundwaters contaminated with uranium (U) through precipitation under oxidizing conditions are needed because bioreduction-based approaches require indefinite supply of electron donor. Although strategies based on precipitation of some phosphate minerals within the (meta)autunite group have been considered for this purpose, thermodynamic calculations for K- and Ca-uranyl phopsphates, meta-ankoleite and autunite, predict that U concentrations will exceed the Maximum Contaminant Level (MCL = 0.13 microM for U) at any pH and pCO2, unless phosphate is maintained at much higher concentrations than the sub-microM levels typically found in groundwaters. We hypothesized that potassium uranyl vanadate will control U(VI) concentrations below regulatory levels in slightly acidic to neutral solutions based on thermodynamic data available for carnotite, K2(UO2)2V2O8. The calculations indicate that maintaining U concentrations below the MCL through precipitation of carnotite will be sustainable in some oxidizing waters having pH in the range of 5.5 to 7, even when dissolution of this solid phase becomes the sole supply of sub-microM levels of V. Batch experiments were conducted in solutions at pH 6.0 and 7.8, chosen because of their very different predicted extents of U(VI) removal. Conditions were identified where U concentrations dropped below the MCL within 1-5 days of contact with oxidizing solutions containing 0.2-10 mM K, and 0.1-20 microM V(V). This method may also have application in extracting (mining) U and V from groundwaters where they both occur at elevated concentrations.

Published

2009

14. Spatially resolved U(VI) partitioning and speciation: implications for plume scale behavior of contaminant U in the Hanford vadose zone

Author

Nobumichi Tamura, Yongman Kim, Suvasis Dixit, Martin Kunz, Jiamin Wan, Tetsu K. Tokunaga, Zheming Wang, Carl I. Steefel, and Eduardo Saiz

Subjects

Hydrology, Washington, Geologic Sediments, Water Pollutants, Radioactive, Hanford Site, Borehole, chemistry.chemical_element, General Chemistry, Uranium, Hydrogen-Ion Concentration, Plume, chemistry, Groundwater pollution, Vadose zone, Panache, Environmental Chemistry, Thermodynamics, Groundwater, Geology

Abstract

A saline-alkaline brine containing high concentration of U(VI) was accidentally spilled at the Hanford Site in 1951, introducing 10 tons of U into sediments under storage tank BX-102. U concentrations in the deep vadose zone and groundwater plumes increase with time, yet how the U has been migrating is not fully understood. We simulated the spill event in laboratory soil columns, followed by aging, and obtained spatially resolved U partitioning and speciation along simulated plumes. We found after aging, at apparent steady state, that the pore aqueous phase U concentrations remained surprisingly high (up to 0.022 M), in close agreement with the recently reported high U concentrations (up to 0.027 M) in the vadose zone plume (1). The pH values of aged pore liquids varying from 10 to 7, consistent with the measured pH of the field borehole sediments varying from 9.5 to 7.4 (2), from near the plume source to the plume front. The direct measurements of aged pore liquids together with thermodynamic calculations using a Pitzer approach revealed that UO2(CO3)3(4-) is the dominant aqueous U species within the plume body (pH 8-10), whereas Ca2UO2(CO3)3 and CaUO2(CO3)32- are also significant in the plume frontvicinity (pH 7-8), consistent with that measured from field borehole pore-waters (3). U solid phase speciation varies at different locations along the plume flow path and even within single sediment grains, because of location dependent pore and micropore solution chemistry. Our results suggest that continuous gravity-driven migration of the highly stable U02(CO3)34 in the residual carbonate and sodium rich tank waste solution is likely responsible for the detected growing U concentrations in the vadose zone and groundwater.

Published

2009

15. Influences of organic carbon supply rate on uranium bioreduction in initially oxidizing, contaminated sediment

Author

Tetsu K. Tokunaga, Don Herman, Rebecca A. Daly, Terry C. Hazen, Eoin L. Brodie, Jiamin Wan, Yongman Kim, and Mary K. Firestone

Subjects

Geologic Sediments, Time Factors, Environmental remediation, Partial Pressure, Acetates, chemistry.chemical_compound, Oxidizing agent, Environmental Chemistry, Soil Pollutants, Radioactive, Lactic Acid, Sulfate, Organic Chemicals, Effluent, Electrodes, Total organic carbon, Bacteria, Environmental engineering, General Chemistry, Biodegradation, Carbon Dioxide, Carbon, Biodegradation, Environmental, chemistry, Environmental chemistry, Carbon dioxide, Carbonate, Uranium, Oxidation-Reduction

Abstract

Remediation of uranium-contaminated sediments through in situ stimulation of bioreduction to insoluble UO2 is a potential treatment strategy under active investigation. Previously, we found that newly reduced U(IV) can be reoxidized under reducing conditions sustained by a continuous supply of organic carbon (OC) because of residual reactive Fe(III) and enhanced U(VI) solubilitythrough complexation with carbonate generated through OC oxidation. That finding motivated this investigation directed at identifying a range of OC supply rates that is optimal for establishing U bioreduction and immobilization in initially oxidizing sediments. The effects of OC supply rate, from 0 to 580 mmol of OC (kg of sediment)(-1) year(-1), and OC form (lactate and acetate) on U bioreduction were tested in flow-through columns containing U-contaminated sediments. An intermediate supply rate on the order of 150 mmol of OC (kg of sediment)(-1) year(-1) was determined to be most effective at immobilizing U. At lower OC supply rates, U bioreduction was not achieved, and U(VI) solubilitywas enhanced by complexation with carbonate (from OC oxidation). At the highest OC supply rate, the resulting highly carbonate-enriched solutions also supported elevated levels of U(VI), even though strongly reducing conditions were established. Lactate and acetate were found to have very similar geochemical impacts on effluent U concentrations (and other measured chemical species), when compared at equivalent OC supply rates. While the catalysts of U(VI) reduction to U(IV) are presumably bacteria, the composition of the bacterial community,the Fe-reducing community, and the sulfate-reducing community had no direct relationship with effluent U concentrations. The OC supply rate has competing effects of driving reduction of U(VI) to low-solubility U(IV) solids, as well as causing formation of highly soluble U(VI)-carbonato complexes. These offsetting influences will require careful control of OC supply rates in order to optimize bioreduction-based U stabilization.

Published

2009

16. Effect of Saline Waste Solution Infiltration Rates on Uranium Retention and Spatial Distribution in Hanford Sediments

Author

Zheming Wang, Jiamin Wan, Tetsu K. Tokunaga, R. Jeffrey Serne, Yongman Kim, Antonio Lanzirotti, and Eduardo Saiz

Subjects

Washington, Geologic Sediments, Salinity, Water Pollutants, Radioactive, Hanford Site, chemistry.chemical_element, Vadose zone, Environmental Chemistry, Chemical Precipitation, Colloids, Hydrology, Radioactive waste, Sediment, General Chemistry, Uranium, Hydrogen-Ion Concentration, Infiltration (HVAC), Plume, Solutions, Kinetics, chemistry, Radioactive Waste, Earth Sciences, Adsorption, Tonne, Geology

Abstract

Effect of Saline Waste Solution Infiltration Rates on Uranium Retention and Spatial Distribution in Hanford Sediments Jiamin Wan 1* , Tetsu K. Tokunaga 1 , Yongman Kim 1 , Zheming Wang 2 , Antonio Lanzirotti 3 , Eduardo Saiz 4 , and R. Jeffrey Serne 2 1. Earth Sciences Division, Lawrence Berkeley National Laboratory, Berkeley, CA 94720 2. Pacific Northwest National Laboratory, Richland, WA 99352 3. University of Chicago, Chicago, IL 60637 4. Material Science Division, Lawrence Berkeley National Laboratory, Berkeley, CA 94720 ABSTRACT The accidental overfilling of waste liquid from tank BX-102 at the Hanford Site in 1951 put about 10 metric tons of U(VI) into the vadose zone. In order to understand the dominant geochemical reactions and transport processes occurred during the initial infiltration and help understand current spatial distribution, we simulated the waste liquid spilling event in laboratory sediment columns using synthesized metal waste solution. We found that, as the plume propagating through sediments, pH decreased greatly (as much as 4 units) at the moving plume front. Infiltration flow rates strongly affect U behavior. Slower flow rates resulted in higher sediment-associated U concentrations, and higher flow rates ( 5 cm/day) permitted practically unretarded U transport. Therefore, given the very high K sat of most of Hanford formation, the low permeability zones within the sediment could have been most important in retaining high concentrations of U during initial release into the vadose zone. Massive amount of colloids, including U-colloids, formed at the plume fronts. Total U concentrations (aqueous and colloid) within plume fronts exceeded the source concentration by up to 5-fold. Uranium colloid

Published

2008

17. Mesoscale Biotransformations of Uranium: Identifying Sites and Strategies where Reductive Immobilization is Practical

Author

Tetsu K. Tokunaga, Rebecca A. Daly, Mary K. Firestone, Yongman Kim, Terry C. Hazen, Eoin L. Brodie, and Jiamin Wan

Subjects

Biogeochemical cycle, Chemistry, Environmental chemistry, Environmental engineering, chemistry.chemical_element, Uranium, Redox

Abstract

Bioreduction of U in contaminated sediments is an attractive strategy because of its low cost, and because of short-term studies supporting its feasibility. However, any in-situ immobilization approach for U will require assurance of either permanent fixation, or of very low release rates into the biosphere. Our previous long-term (2 years) laboratory experiments have shown that organic carbon (OC) based U(VI) bioreduction to UO2 can be transient even under sustained reducing (methanogenic) conditions. The biogeochemical processes underlying this finding urgently need to be understood. The current research is designed to identify mechanisms responsible for anaerobic U oxidation, and identify conditions that will support long-term stability of bioreduced U. We are investigating: (1) effects of OC concentration and supply rate on remobilization of bioreduced U, (2) the roles of Fe- and Mn-oxides as potential U oxidants in sediments, and (3) the role of microorganisms in U reoxidation, and (4) influences of pH on U(IV)/U(VI) redox equilibrium.

Published

2006

18. Quantifying and Predicting Reactive Transport of Uranium in Waste Plumes: Are Colloids and Nanoparticles Important?

Author

Jiamin Wan, Tetsu K. Tokunaga, Carl I. Steefel, and Peter Burns

Subjects

Waste site, chemistry, Waste management, Hanford Site, Vadose zone, Environmental engineering, chemistry.chemical_element, Environmental science, Uranium, Contamination, Groundwater, Plutonium

Abstract

The Hanford Site is the DOE's largest legacy waste site, with uranium (U) from plutonium processing being a major contaminant in its subsurface. Accidental release of highly concentrated high-level wastes left large quantities of U in the vadose zone under tank farms. The U contamination has been found in groundwater beneath the tank farms, indicating U is mobile.

Published

2006

19. Reactive Transport of Uranium in Waste Plumes of Hanford Site

Author

Tetsu K. Tokunaga, Peter Burns, Jiamin Wan, and Carl I. Steefel

Subjects

Pore water pressure, Adsorption, chemistry, Waste management, Hanford Site, Vadose zone, Environmental engineering, Borehole, chemistry.chemical_element, Environmental science, Uranium, Particulates, Plume

Abstract

The overall objective of this renewal proposal is to construct an experimentally supported conceptual model of U fate and transport, during and after the tank leakage, at heavily Uncontaminated areas within the Hanford Site. Through simulating the tank leakage event in laboratory columns, we will better understand the spatial and temporal distribution of the spilled U, and its mobility. These laboratory results will specifically be used to compare with and help explain borehole data from underneath tank BX-102. Our research focuses on the following basic issues: (1) Determining the spatial distribution of U within the plume during the early stage of waste plume development. (2) Determining the forms and amount of U partitioned in the pore water relative to the matrix associated U. Identify dissolved U and suspended mobile U-rich colloids in the aqueous phase, and characterize matrix-associated forms (deposited U colloids, sorbed and precipitated U species). (3) Determine how all the above change with time. (4) Determining the mobility of U (release and transport) as function of aging. (5) Developing a mechanistic reactive transport model capable of accounting for both dissolved and particulate U(VI) in the Hanford vadose zone. An overall understanding of U-precipitation vs. adsorption, stability of nanoparticles and their transport, will improve our ability to predict current and future development of U-waste plumes.

Published

2004

20. Removal of uranium(VI) from contaminated sediments by surfactants

Author

Tetsu K. Tokunaga, Jiamin Wan, and Frederic Gadelle

Subjects

Geologic Sediments, Water Pollutants, Radioactive, Environmental Engineering, Mineralogy, chemistry.chemical_element, Management, Monitoring, Policy and Law, complex mixtures, Matrix (chemical analysis), Surface-Active Agents, Pulmonary surfactant, Soil pH, Desorption, Soil Pollutants, Waste Management and Disposal, Dissolution, Water Science and Technology, Chemistry, Water Pollution, Sorption, Uranium, Hydrogen-Ion Concentration, Pollution, Soil contamination, Environmental chemistry, Adsorption

Abstract

Uranium(VI) sorption onto a soil collected at the Melton Branch Watershed (Oak Ridge National Laboratory, TN) is strongly influenced by the pH of the soil solution and, to a lesser extent, by the presence of calcium, suggesting specific chemical interactions between U(VI) and the soil matrix. Batch experiments designed to evaluate factors controlling desorption indicate that two anionic surfactants, AOK and T77, at concentrations ranging from 60 to 200 mM, are most suitable for U(VI) removal from acidic soils such as the Oak Ridge sediment. These surfactants are very efficient solubilizing agents at low uranium concentrations: ca. 100% U(VI) removal for [U(VI)] o,sorbed = 10 -6 mol kg -1 . At greater uranium concentrations (e.g., [U(VI)] o,serbed = ca. 10 -5 mol kg -1 ), the desorption efficiency of the surfactant solutions increases with an increase in surfactant concentration and reaches a plateau of 75 to 80% of the U(VI) initially sorbed. The most probable mechanisms responsible for U(VI) desorption include cation exchange in the electric double layer surrounding the micelles and, to a lesser extent, dissolution of the soil matrix. Limitations associated with the surfactant treatment include loss of surfactants onto the soil (sorption) and greater affinity between U(VI) and the soil matrix at large soil to liquid ratios. Parallel experiments with H 2 SO 4 and carbonate-bicarbonate (CB) solutions indicate that these more conventional methods suffer from strong matrix dissolution with the acid and reduced desorption efficiency with CB due to the buffering capacity of the acidic soil.

Published

2001

21. Influences of Organic Carbon Supply Rate on Uranium Bioreduction in Initially Oxidizing, Contaminated Sediment.

Author

TOKUNAGA, TETSU K., JIAMIN WAN, YONGMAN KIM, DALY, REBECCA A., BRODIE, EOIN L., HAZEN, TERRY C., HERMAN, DON, and FIRESTONE, MARY K.

Subjects

*CHEMICAL reduction, *URANIUM, *CONTAMINATED sediments, *CARBON, *SOLUBILITY, *ENVIRONMENTAL remediation, *OXIDATION, *CATALYSTS, *BACTERIA

Abstract

Remediation of uranium-contaminated sediments through in situ stimulation of bioreduction to insoluble UO2 is a potential treatment strategy under active investigation. Previously, we found that newly reduced U(IV) can be reoxidized under reducing conditions sustained by a continuous supply of organic carbon (OC) because of residual reactive Fe(III) and enhanced U(VI) solubility through complexation with carbonate generated through OC oxidation. That finding motivated this investigation directed at identifying a range of OC supply rates that is optimal for establishing U bioreduction and immobilization in initially oxidizing sediments. The effects of OC supply rate, from 0 to 580 mmol of OC (kg of sediment)-1 year-1, and OC form (lactate and acetate) on U bioreduction were tested in flow-through columns containing U-contaminated sediments. An intermediate supply rate on the order of 150 mmol of OC (kg of sediment)-1 year-1 was determined to be most effective at immobilizing U. At lower OC supply rates, U bioreduction was not achieved, and U(VI) solubility was enhanced by complexation with carbonate (from OC oxidation). At the highest OC supply rate, the resulting highly carbonate-enriched solutions also supported elevated levels of U(VI), even though strongly reducing conditions were established, Lactate and acetate were found to have very similar geochemical impacts on effluent U concentrations (and other measured chemical species), when compared at equivalent OC supply rates. While the catalysts of U(VI) reduction to U(IV) are presumably bacteria, the composition of the bacterial community, the Fe-reducing community, and the sulfate-reducing community had no direct relationship with effluent U concentrations. The OC supply rate has competing effects of driving reduction of U(VI) to low-solubility U(IV) solids, as well as causing formation of highly soluble U(VI)-carbonato complexes. These offsetting influences will require careful control of OC supply rates in order to optimize bioreduction-based U stabilization. [ABSTRACT FROM AUTHOR]

Published

2008

22. Real-Time X-ray Absorption Spectroscopy of Uranium, Iron, and Manganese in Contaminated Sediments During Bioreduction.

Author

Tokunaga, Tetsu K., Jiamin Wan, Yongman Kim, Sutton, Steve R., Newville, Matthew, Lanzirotti, Antonio, and Rao, William

Subjects

*CONTAMINATED sediments, *ABSORPTION spectra, *URANIUM, *IRON, *MANGANESE, *OXIDATION, *X-rays, *OXIDES, *ELECTROPHILES

Abstract

The oxidation status of uranium in sediments is important because the solubility of this toxic and radioactive element is much greater for U(VI) than for U(IV) species. Thus, redox manipulation to promote precipitation of UO2 is receiving interest as a method to remediate U-contaminated sediments. Presence of Fe and Mn oxides in sediments at much higher concentrations than U requires an understanding of their redox status as well. This study was conducted to determine changes in oxidation states of U, Fe, and Mn in U-contaminated sediments from Oak Ridge National Laboratory. Oxidation states of these elements were measured in real-time and nondestructively using X-ray absorption spectroscopy on sediment columns supplied with synthetic groundwater containing organic carbon (OC, 0, 3, 10, 30, and 100 mM OC as lactate) for over 400 days. In sediments supplied with OC ≥ 30 mM, 80% of the U was reduced to U(IV), with transient reoxidation at about 150 days. Mn(III,lV) oxides were completely reduced to Mn(II) in sediments infused with OC ≥ 3 mM. However, Fe remained largely unreduced in all sediment columns, showing that Fe(Ill) can persist as an electron acceptor in reducing sediments over long times. This result in combination with the complete reduction of all other potential electron acceptors supports the hypothesis that the reactive Fe(II) fraction was responsible for reoxidizing U(IV). [ABSTRACT FROM AUTHOR]

Published

2008

23. Uranium Reduction in Sediments under Diffusion-Limited Transport of Organic Carbon.

Author

Tokunaga, Tetsu K., Jiamin Wan, Pena, Jasquelin, Brodie, Eoin L., Firestone, Mary K., Hazen, Terry C., Sutton, Steve R., Lanzirotti, Antonio, and Newville, Matthew

Subjects

*URANIUM, *SEDIMENTS, *DIFFUSION, *CARBON, *POLLUTION, *OXIDATION

Abstract

Costly disposal of uranium (U) contaminated sediments is motivating research on in situ U(VI) reduction to insoluble U(IV) via directly or indirectly microbially mediated pathways. Delivery of organic carbon (OC) into sediments for stimulating U bioreduction is diffusion-limited in less permeable regions of the subsurface. To study OC-based U reduction in diffusion-limited regions, one slightly acidic and another calcareous sediment were treated with uranyl nitrate, packed into columns, then hydrostatically contacted with tryptic soy broth solutions. Redox potentials, U oxidation state, and microbial communities were well correlated. At average supply rates of 0.9 μmol OC (g sediment)-1 day-1, the U reduction zone extended to only about 35-45 mm into sediments. The underlying unreduced U(VI) zone persisted over 600 days because the supply of OC was diffusion-limited and metabolized within a short distance. These results also suggest that low U concentrations in groundwater samples from OC-treated sediments are not necessarily indicative of pervasive U reduction because interior and exterior regions of such sediment blocks can contain primarily U(VI) and U(IV), respectively. [ABSTRACT FROM AUTHOR]

Published

2005

24. Geochemical Controls on Contaminant Uranium in Vadose Hanford Formation Sediments at the 200 Area and 300 Area, Hanford Site, Washington.

Author

McKinley, James P., Zachara, John M., Jiamin Wan, McCready, David E., and Heald, Steven M.

Subjects

URANIUM, CHEMICAL spills, WASTE spills, SEDIMENTS, GROUNDWATER

Abstract

Long-term historic spills of uranium at the 300 Area fuel fabrication site (58,000 kg of disposed uranium over 32 yr) and at the 200 East Area BX tank farm (7000 kg of spilled uranium in one event), both within the Hanford formation in the Hanford Site, Washington State, were investigated by subsurface sampling and subsequent microscale investigations of excavated samples. The 200 Area sediments contained uranyl silicate mineralization (sodium boltwoodite) in restrictive microfractures in granitic clasts, in the vadose zone over a narrow range in depth. Well logging and column experiments indicated that tank wastes migrated deeper than observed in core samples. The 300 Area sediments included metatorbernite and uranium at low concentrations associated with detrital aluminosilicates, along with other mineral phases that could accommodate uranyl, such as uranophane and calcium carbonate. The association of contaminant uranyl with Hanford formation sediments provided a persistent source of uranium to groundwater. The results of both studies suggest that the formation of secondary solid uranyl-bearing phases influences the subsequent release of uranium to the environment and that our understanding of these processes and individual waste sites is incomplete. [ABSTRACT FROM AUTHOR]

Published

2007

25. Aqueous Uranium(Vl) Concentrations Controlled by Calcium Uranyl Vanadate Precipitates.

Author

Tokunaga, Tetsu K., Yongman Kim, Jiamin Wan, and Li Yang

Subjects

*GROUNDWATER research, *URANIUM, *URANYL compounds, *AQUEOUS solutions, *ANALYTICAL chemistry, *MEASUREMENT of solubility, *TYUYAMUNITE, *WATER pollution, *PRECIPITATION (Chemistry)

Abstract

Elevated concentrations of U in contaminated environments necessitate understanding controls on its solubility in groundwaters. Here, calculations were performed to compare U(VI) concentrations expected in typical oxidizing groundwaters in equilibrium with different U(VI) minerals. Among common U(VI) minerals, only tyuyamunite (Ca(UO2)2V2O8·8H2O), uranophane (Ca(UO2)2(SiO3OH)2·5H2O), and a putative well-crystallized becquerelite (Ca(UO2)6O4(OH)6·8H2O) were predicted to control U concentrations around its maximum contaminant level (MCL = 0.13 μM), albeit over narrow ranges of pH. Given the limited information available on uranyl vanadates, room temperature Ca-U-V precipitation experiments were conducted in order to compare aqueous U concentrations with tyuyamunite equilibrium predictions. Measured U concentrations were in approximate agreement with predictions based on Langmuir's estimated ΔGfo, although the precipitated solids were amorphous and had wide ranges of Ca/U/V molar ratios. Nevertheless, high initial U concentrations were decreased to below the MCL over the pH range 5.5-6.5 in the presence of newly formed CaUV solids, indicating that such solids can be important in controlling U in some environments. [ABSTRACT FROM AUTHOR]

Published

2012