Your search keyword '"Abney, Carter W."' showing total 8 results

1. Nanospace Decoration with Uranyl-Specific “Hooks” for Selective Uranium Extraction from Seawater with Ultrahigh Enrichment Index

Author

Song, Yanpei, Zhu, Changjia, Sun, Qi, Aguila, Briana, Abney, Carter W., Wojtas, Lukasz, and Ma, Shengqian

Abstract

Mining uranium from seawater is highly desirable for sustaining the increasing demand for nuclear fuel; however, access to this unparalleled reserve has been limited by competitive adsorption of a wide variety of concentrated competitors, especially vanadium. Herein, we report the creation of a series of uranyl-specific “hooks” and the decoration of them into the nanospace of porous organic polymers to afford uranium nanotraps for seawater uranium extraction. Manipulating the relative distances and angles of amidoxime moieties in the ligands enabled the creation of uranyl-specific “hooks” that feature ultrahigh affinity and selective sequestration of uranium with a distribution coefficient threefold higher compared to that of vanadium, overcoming the long-term challenge of the competing adsorption of vanadium for uranium extraction from seawater. The optimized uranium nanotrap (2.5 mg) can extract more than one-third of the uranium in seawater (5 gallons), affording an enrichment index of 3836 and thus presenting a new benchmark for uranium adsorbent. Moreover, with improved selectivity, the uranium nanotraps could be regenerated using a mild base treatment. The synergistic combination of experimental and theoretical analyses in this study provides a mechanistic approach for optimizing the selectivity of chelators toward analytes of interest.

Published

2021

2. Capture of Iodine from Nuclear-Fuel-Reprocessing Off-Gas: Influence of Aging on a Reduced Silver Mordenite Adsorbent after Exposure to NO/NO2

Author

Wiechert, Alexander I., Ladshaw, Austin P., Moon, Jisue, Abney, Carter W., Nan, Yue, Choi, Seungrag, Liu, Jiuxu, Tavlarides, Lawrence L., Tsouris, Costas, and Yiacoumi, Sotira

Abstract

Iodine radioisotopes released during nuclear fuel reprocessing must be removed from the off-gas stream before discharge. One promising material for iodine capture is reduced silver mordenite (Ag0Z). Nevertheless, the adsorbent’s capacity will degrade, or age, over time when the material is exposed to other off-gas constituents. Though the overall impact of aging is known, the underlying physical and chemical processes are not. To examine these processes, Ag0Z samples were prepared and aged in 2% NO2in dry air and in 1% NO in N2gas streams at 150 °C for up to six months. Aged samples were then characterized using scanning electron microscopy, X-ray diffraction, Raman spectroscopy, and X-ray absorption spectroscopy. These techniques show that aging involves two overarching processes: (i) oxidation of the silver nanoparticles present in Ag0Z and (ii) migration of oxidized silver into the mordenite’s inner network. Silver on the nanoparticle’s surface is oxidized through adsorption of O2, NO, and NO2. Raman spectroscopy and X-ray absorption spectroscopy indicate that nitrates are the primary products of this adsorption. Most of these nitrates migrate into the interior of the mordenite and exchange at framework binding sites, returning silver to its unreduced state (AgZ). The remaining nitrates exist at a persistent concentration without aggregating into bulk-phase AgNO3. X-ray absorption spectroscopy results further indicate that iodine adsorption occurs on not just Ag0Z but also on AgZ and a portion of the nitrates in the system. AgZ adsorbs a sizable quantity of iodine early in the aging process, but its capacity drops rapidly over time. For well-aged samples, nitrates are responsible for up to 95% of mordenite’s iodine capacity. These results have enhanced our understanding of the aging process in silver mordenite and are expected to guide the development of superior adsorbents for the capture of radioactive iodine from reprocessing off-gas.

Published

2020

3. Successful Coupling of a Bis-Amidoxime Uranophile with a Hydrophilic Backbone for Selective Uranium Sequestration

Author

Piechowicz, Marek, Abney, Carter W., Thacker, Nathan C., Gilhula, James C., Wang, Youfu, Veroneau, Samuel S., Hu, Aiguo, and Lin, Wenbin

Abstract

The amidoxime group (−RNH2NOH) has long been used to extract uranium from seawater on account of its high affinity toward uranium. The development of tunable sorbent materials for uranium sequestration remains a research priority as well as a significant challenge. Herein, we report the design, synthesis, and uranium sorption properties of bis-amidoxime-functionalized polymeric materials (BAP 1–3). Bifunctional amidoxime monomers were copolymerized with an acrylamide cross-linker to obtain bis-amidoxime incorporation as high as 2 mmol g–1after five synthetic steps. The resulting sorbents were able to uptake nearly 600 mg of uranium per gram of polymer after 37 days of contact with a seawater simulant containing 8 ppm uranium. Moreover, the polymeric materials exhibited low vanadium uptake with a maximum capacity of 128 mg of vanadium per gram of polymer. This computationally predicted and experimentally realized selectivity of uranium over vanadium, nearly 5 to 1 w/w, is one of the highest reported to date and represents an advancement in the rational design of sorbent materials with high uptake capacity and selectivity.

Published

2024

4. Design Strategies to Enhance Amidoxime Chelators for Uranium Recovery

Author

Aguila, Briana, Sun, Qi, Cassady, Harper, Abney, Carter W., Li, Baiyan, and Ma, Shengqian

Abstract

To move nuclear as a primary energy source, uranium resources must be secured beyond what terrestrial reserves can provide. Given the vast quantity of uranium naturally found in the ocean, adsorbent materials have been investigated to recover this vital fuel source. Amidoxime (AO) has been found to be the state-of-the-art functional group for this purpose, however, improvements must still be made to overcome the issues with selectively capturing uranium at such a low concentration found in the ocean. Herein, we report PAF-1 as a platform to study the effects of two amidoxime ligands. The synthesized adsorbents, PAF-1-CH2NHAO and PAF-1-NH(CH2)2AO, with varying chain lengths and grafting degrees, were investigated for their uranium uptakes and kinetic efficiency. PAF-1-NH(CH2)2AO was found to outperform PAF-1-CH2NHAO, with a maximum uptake capacity of 385 mg/g and able to reduce a uranium-spiked solution to ppb level within 10 min. Further studies with PAF-1-NH(CH2)2AO demonstrated effective elution for multiple adsorption cycles and showed promising results for uranium recovery in the diverse composition of a spiked seawater solution. The work presented here moves forward design principles for amidoxime-functionalized ligands and provides scope for strategies to enhance the capture of uranium as a sustainable nuclear fuel source.

Published

2019

5. Functionalized Porous Aromatic Framework for Efficient Uranium Adsorption from Aqueous Solutions

Author

Li, Baiyan, Sun, Qi, Zhang, Yiming, Abney, Carter W., Aguila, Briana, Lin, Wenbin, and Ma, Shengqian

Abstract

We demonstrate the successful functionalization of a porous aromatic framework for uranium extraction from water as exemplified by grafting PAF-1 with the uranyl chelating amidoxime group. The resultant amidoxime-functionalized PAF-1 (PAF-1-CH2AO) exhibits a high uranium uptake capacity of over 300 mg g–1and effectively reduces the uranyl concentration from 4.1 ppm to less than 1.0 ppb in aqueous solutions within 90 min, well below the acceptable limit of 30 ppb set by the US Environmental Protection Agency. The local coordination environment of uranium in PAF-1-CH2AO is revealed by X-ray absorption fine structure spectroscopic studies, which suggest the cooperative binding between UO22+and adjacent amidoxime species.

Published

2017

6. Graphene-Immobilized Monomeric Bipyridine-Mx+(Mx+= Fe3+, Co2+, Ni2+, or Cu2+) Complexes for Electrocatalytic Water Oxidation

Author

Zhou, Xin, Zhang, Teng, Abney, Carter W., Li, Zhong, and Lin, Wenbin

Abstract

Covalent anchoring of 2,2′-bipyridine (L) to a graphene (Gr) modified electrode followed by treatment with an Mx+(NO3)xsolution (M = Fe3+, Co2+, Ni2+, or Cu2+) results in surface-bound catalysts with high redox activity in neutral water at ambient temperature. Raman and IR spectroscopies indicate the successful Lgrafting and Gr deposition onto the electrodes, whereas metal concentration was determined by inductively coupled plasma mass spectrometry (ICP-MS). Cyclic voltammetry measurements were used to investigate catalytic performances, whereas a rotating ring-disk electrode was used to measure the faraday efficiencies of oxygen evolution reaction and determine experimental turnover frequencies (TOFs). Of the four metal-Lcomplexes investigated, Co-Lon a Gr-modified indium tin oxide (ITO) electrode exhibits the best catalytic activity. Washing with a solution containing catalytically inert Zn2+removes Co weakly bound by surface carboxylate functionalities, and ensures the presence of only covalently attached active catalytic species. This process results in an experimental TOF of 14 s–1at an overpotential of 834 mV. Functionalization of Gr-modified electrodes with appropriate metal-binding moieties thus provides a feasible strategy for loading first row transition metals onto conductive surfaces for the generation of highly active water oxidation catalysts.

Published

2014

7. Scalable Formation of Diamine-Appended Metal–Organic Framework Hollow Fiber Sorbents for Postcombustion CO2Capture

Author

Quan, Wenying, Holmes, Hannah E., Zhang, Fengyi, Hamlett, Breanne L., Finn, M. G., Abney, Carter W., Kapelewski, Matthew T., Weston, Simon C., Lively, Ryan P., and Koros, William J.

Abstract

We describe a straightforward and scalable fabrication of diamine-appended metal–organic framework (MOF)/polymer composite hollow fiber sorbent modules for CO2capture from dilute streams, such as flue gas from natural gas combined cycle (NGCC) power plants. A specific Mg-MOF, Mg2(dobpdc) (dobpdc4–= 4,4′-dioxidobiphenyl-3,3′-dicarboxylate), incorporated into poly(ether sulfone) (PES) is directly spun through a conventional “dry-jet, wet-quench” method. After phase separation, a cyclic diamine 2-(aminomethyl)piperidine (2-ampd) is infused into the MOF within the polymer matrix during postspinning solvent exchange. The MOF hollow fibers from direct spinning contain as high as 70% MOF in the total fibers with 98% of the pure MOF uptake. The resulting fibers exhibit a step isotherm and a “shock-wave-shock” breakthrough profile consistent with pure 2-ampd-Mg2(dobpdc). This work demonstrates a practical method for fabricating 2-ampd-Mg2(dobpdc) fiber sorbents that display the MOF’s high CO2adsorption capacity while lowering the pressure drop during operation.

Published

2022

8. CO2Capture Using PIM-1 Hollow Fiber Sorbents with Enhanced Performance by PEI Infusion

Author

Quan, Wenying, Zhang, Fengyi, Hamlett, Breanne L., Finn, M. G., Abney, Carter W., Weston, Simon C., Lively, Ryan P., and Koros, William J.

Abstract

This paper describes hollow fiber sorbents made of the parent polymer of intrinsic microporosity, PIM-1, using a spinning method designed to control the formation of dense barrier layers followed by a simple post treatment with polyethylenimine (PEI) for further improvement of CO2uptake. The overall process involved solvent-moderated sheath-core spinning with a variation of core/bore flow rates and quench bath temperatures. Dope compositions to promote micropore interconnectivity were optimized by controlling the dope nonsolvent concentration. Under optimized conditions, undesirable skin layers were not formed, avoiding associated mass transfer resistance. The resulting PIM-1 hollow fiber sorbents achieved good CO2uptake, with maximum equilibrium capacities of 2.8 mmol-CO2/g-fiber. CO2sorption kinetics were dependent on PEI loading, allowing the designer to balance between capacity and uptake rate, a control feature unavailable with the pure PIM fiber sorbent.

Published

2021