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| Author | : Bernard Frederick Parker |
| Publisher | : |
| Total Pages | : 155 |
| Release | : 2017 |
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| Author | : Mark A. Lashley |
| Publisher | : |
| Total Pages | : 122 |
| Release | : 2018 |
| Genre | : Electronic dissertations |
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| Total Pages | : 13 |
| Release | : 2015 |
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This milestone report summarizes the data obtained in FY15 on the major task of quantifying the binding strength of amidoxime-related ligands. Thermodynamic studies of the interaction between U(VI) and amidoxime ligand HLIII were studied to quantify the binding ability of U(VI) with amidoxime-related ligands and help to select grafting/reaction conditions so that higher yield of preferred amidoxime-related ligands is obtained. Besides the thermodynamic task, structural studies on vanadium complexation with amidoxime ligand were conducted to help understand the extremely strong sorption of vanadium on poly(amidoxime) sorbents. Data processing and summarization of the vanadium system are in progress and will be included in the next milestone report.
| Author | : Ruma Joshi |
| Publisher | : |
| Total Pages | : 360 |
| Release | : 2017 |
| Genre | : Marine mineral resources |
| ISBN | : |
Nuclear power is a significant alternative energy resource because it is free of carbon emissions and hence prevents global warming and climate change. Uranium is an essential fuel used for the generation of nuclear power. Since the current uranium deposits of about 63 million metric tons present in terrestrial sources might be exhausted by the end of this century, active research has been done in the past and is still under development for the establishment of a cost-effective technique for the extraction of uranium from seawater. Chapter one provides an outlook on different energy resources and the importance of nuclear energy. Chapter two highlights the novel approaches explored by various research groups for the extraction of uranium from seawater using amidoxime-based polymer adsorbents. Competition of vanadium with uranium in seawater for adsorption to the amidoxime-based adsorbent is discussed. Chapter three examines the solution phase complexation of glutarimidedioxime and glutardiamidoxime with UO2+2, VO2+, and VO+2 because the knowledge gained will aid in understanding the adsorption of uranium and vanadium using amidoxime-based adsorbents for the extraction of uranium from seawater. Chapter four uses 13C CP/MAS solid state NMR (SSNMR) spectroscopy for the characterization of a newly synthesized LCW polymer adsorbent derived from acrylic fiber and the Oak Ridge National Lab adsorbent (ORNL-AF1). According to the SSNMR results, the former contains primarily the open-chain glutardiamidoxime groups, whereas the latter contains mainly the cyclic glutarimidedioxime groups. The vanadium uptake by the adsorbents was examined in simulated seawater conditions using the ICP-MS technique. The ORNL-AF1 adsorbent has a higher vanadium adsorption capacity relative to the LCW adsorbent. The result is consistent with the observation made in the solution phase complexation study, which shows that vanadium has a much higher affinity for cyclic glutarimidedioxime than the open-chain glutardiamidoxime. It should be cautioned that the coordination behavior of metal ions with free ligand molecules may not be the same as the ligand attached to a polymer adsorbent. Nevertheless, the information obtained from the solution phase chemistry of the metal/ligand complexes presented in Chapter three of the dissertation is still valuable for designing new amidoxime-based adsorbents with higher uranium adsorption capacity.
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| Total Pages | : 20 |
| Release | : 2016 |
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Even at a concentration of 3 [mu]g/L, the world's oceans contain a thousand times more uranium than currently know terrestrial sources. In order to take advantage of this stockpile, methods and materials must be developed to extract it efficiently, a difficult task considering the very low concentration of the element and the competition for extraction by other atoms in seawater such as sodium, calcium, and vanadium. The majority of current research on methods to extract uranium from seawater are vertical explorations of the grafting of amidoxime ligand which was originally discovered and promoted by Japanese studies in the late 1980s. Our study expands on this research horizontally by exploring the effectiveness of novel uranium extraction ligands grafted to the surface of polymer substrates using radiation. Through this expansion, a greater understanding of uranium binding chemistry and radiation grafting effects on polymers has been obtained. While amidoxime-functionalized fabrics have been shown to have the greatest extraction efficiency so far, they suffer from an extensive chemical processing step which involves treatment with powerful basic solutions. Not only does this add to the chemical waste produced in the extraction process and add to the method's complexity, but it also significantly impacts the regenerability of the amidoxime fabric. The approach of this project has been to utilize alternative, commercially available monomers capable of extracting uranium and containing a carbon-carbon double bond to allow it to be grafted using radiation, specifically phosphate, oxalate, and azo monomers. The use of commercially available monomers and radiation grafting with electron beam or gamma irradiation will allow for an easily scalable fabrication process once the technology has been optimized. The need to develop a cheap and reliable method for extracting uranium from seawater is extremely valuable to energy independence and will extend the quantity of uranium available to the nuclear power industry far into the future. The development of this technology will also promote science in relation to the extraction of other elements from seawater which could expand the known stockpiles of other highly desirable materials.
| Author | : |
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| Total Pages | : 21 |
| Release | : 2016 |
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Even at a concentration of 3 [mu]g/L, the world's oceans contain a thousand times more uranium than currently know terrestrial sources. In order to take advantage of this stockpile, methods and materials must be developed to extract it efficiently, a difficult task considering the very low concentration of the element and the competition for extraction by other atoms in seawater such as sodium, calcium, and vanadium. The majority of current research on methods to extract uranium from seawater are vertical explorations of the grafting of amidoxime ligand which was originally discovered and promoted by Japanese studies in the late 1980s. Our study expands on this research horizontally by exploring the effectiveness of novel uranium extraction ligands grafted to the surface of polymer substrates using radiation. Through this expansion, a greater understanding of uranium binding chemistry and radiation grafting effects on polymers has been obtained. While amidoxime-functionalized fabrics have been shown to have the greatest extraction efficiency so far, they suffer from an extensive chemical processing step which involves treatment with powerful basic solutions. Not only does this add to the chemical waste produced in the extraction process and add to the method's complexity, but it also significantly impacts the regenerability of the amidoxime fabric. The approach of this project has been to utilize alternative, commercially available monomers capable of extracting uranium and containing a carbon-carbon double bond to allow it to be grafted using radiation, specifically phosphate, oxalate, and azo monomers. The use of commercially available monomers and radiation grafting with electron beam or gamma irradiation will allow for an easily scalable fabrication process once the technology has been optimized. The need to develop a cheap and reliable method for extracting uranium from seawater is extremely valuable to energy independence and will extend the quantity of uranium available to the nuclear power industry far into the future. The development of this technology will also promote science in relation to the extraction of other elements from seawater which could expand the known stockpiles of other highly desirable materials.
| Author | : Masami Hayashi |
| Publisher | : |
| Total Pages | : 20 |
| Release | : 1983 |
| Genre | : Mineral industries |
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| Author | : |
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| Total Pages | : 20 |
| Release | : 2016 |
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Even at a concentration of 3 ?g/L, the world’s oceans contain a thousand times more uranium than currently know terrestrial sources. In order to take advantage of this stockpile, methods and materials must be developed to extract it efficiently, a difficult task considering the very low concentration of the element and the competition for extraction by other atoms in seawater such as sodium, calcium, and vanadium. The majority of current research on methods to extract uranium from seawater are vertical explorations of the grafting of amidoxime ligand which was originally discovered and promoted by Japanese studies in the late 1980s. Our study expands on this research horizontally by exploring the effectiveness of novel uranium extraction ligands grafted to the surface of polymer substrates using radiation. Through this expansion, a greater understanding of uranium binding chemistry and radiation grafting effects on polymers has been obtained. While amidoxime-functionalized fabrics have been shown to have the greatest extraction efficiency so far, they suffer from an extensive chemical processing step which involves treatment with powerful basic solutions. Not only does this add to the chemical waste produced in the extraction process and add to the method’s complexity, but it also significantly impacts the regenerability of the amidoxime fabric. The approach of this project has been to utilize alternative, commercially available monomers capable of extracting uranium and containing a carbon-carbon double bond to allow it to be grafted using radiation, specifically phosphate, oxalate, and azo monomers. The use of commercially available monomers and radiation grafting with electron beam or gamma irradiation will allow for an easily scalable fabrication process once the technology has been optimized. The need to develop a cheap and reliable method for extracting uranium from seawater is extremely valuable to energy independence and will extend the quantity of uranium available to the nuclear power industry far into the future. The development of this technology will also promote science in relation to the extraction of other elements from seawater which could expand the known stockpiles of other highly desirable materials.
| Author | : C. A. Blake |
| Publisher | : |
| Total Pages | : 116 |
| Release | : 1955 |
| Genre | : Uranium |
| ISBN | : |
| Author | : Christine Elizabeth Duval |
| Publisher | : |
| Total Pages | : |
| Release | : 2017 |
| Genre | : Marine mineral resources |
| ISBN | : |
