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3. Evaluation of Histidine Reactivity and Byproduct Formation during Peptide Chlorination

Author

Daniel L. McCurry, Jong Kwon Choe, Adam M.-A. Simpson, Lap Cuong Hua, Yukako Komaki, and William A. Mitch

Subjects
Halogenation, chemistry.chemical_element, Peptide, 010501 environmental sciences, 01 natural sciences, Water Purification, polycyclic compounds, Chlorine, Environmental Chemistry, Organic chemistry, Histidine, Reactivity (chemistry), Tyrosine, 0105 earth and related environmental sciences, chemistry.chemical_classification, General Chemistry, Amino acid, Disinfection, Transformation (genetics), chemistry, Covalent bond, Peptides, Water Pollutants, Chemical, Disinfectants, Trihalomethanes
Abstract

The covalent modifications resulting from chlorine reactions with peptide-bound amino acids contribute to pathogen inactivation and disinfection byproduct (DBP) formation. Previous research suggested that histidine is the third most reactive of the seven chlorine-reactive amino acids, leading to the formation of 2-chlorohistidine, 2-oxohistidine, or low-molecular-weight byproducts such as trihalomethanes. This study demonstrates that histidine is less reactive toward formation of chlorine transformation products (transformation time scale of hours to days) than five of the seven chlorine-reactive amino acids, including tyrosine (transformation time scale of minutes). Chlorine targeted tyrosine in preference to histidine within peptides, indicating that chlorine reactions with tyrosine and other more reactive amino acids could contribute more to the structural modifications to proteins over the short time scales relevant to pathogen inactivation. Over the longer time scales relevant to disinfection byproduct formation in treatment plants or distribution systems, this study identified β-cyanoalanine as the dominant transformation product of chlorine reactions with peptide-bound histidine, with molar yields of ∼50% after 1 day. While a chlorinated histidine intermediate was observed at lower yields (maximum ∼5%), the cumulative concentration of the conventional low-molecular-weight DBPs (e.g., trihalomethanes) was ≤7%. These findings support the need to identify the high-yield initial transformation products of chlorine reactions with important precursor structures to facilitate the identification of unknown DBPs.

Published
2021
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4. Unraveling the mystery of ultrafine bubbles: Establishment of thermodynamic equilibrium for sub-micron bubbles and its implications

Author

Jungwon Park, Euna Kim, Byung Hyo Kim, Jong Kwon Choe, Yongju Choi, and Joodeok Kim

Subjects
Supersaturation, Range (particle radiation), Materials science, Thermodynamic equilibrium, Bubble, Mechanics, Surfaces, Coatings and Films, Electronic, Optical and Magnetic Materials, Henry's law, Suspension (chemistry), Biomaterials, Colloid and Surface Chemistry, Dynamic light scattering, Laplace pressure
Abstract

Hypothesis We test the validity of the Young-Laplace equation and Henry’s law for sub-micron bubble suspensions, which has long been a questionable issue. Application of the two theories allows characterization of bubble diameter and gas molecule partitioning between gaseous and dissolved phases using two easily measurable variables: total gas content ( C T ) and bubble volume concentration (BVC). Experiments We measure C T and BVC for sub-micron bubble suspensions generated from three pure gases, which allows calculation of bubble diameter for each suspension using the Young-Laplace equation and Henry’s law. Uncertainties involved in the experimental measurements are assessed. Bubble size for each suspension is also directly measured using a dynamic light scattering (DLS) technique for comparison. Findings Applying the two theories we calculate that the bubble diameters are in the range of 304–518 nm, which correspond very well with the DLS-measured diameters. Sensitivity analyses demonstrate that the correspondence of the calculated and DLS-measured bubble diameters should take place only if the two theories are valid. The gas molecule partitioning analysis shows that >96% of gas molecules in the suspension exist as dissolved phase, which suggests the significance of the dissolved phase for applications of the bubble suspensions.

Published
2020
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5. Enhanced denitrification of contaminated groundwater by novel bimetallic catalysts supported on kaolin-derived zeolite: effects of natural dissolved inorganic and organic matter

Author

Jong Kwon Choe, Sungjun Bae, Sokhee P. Jung, Sunho Yoon, Jaehyeong Park, Minhee Choi, Taehui Nam, Jin Hur, and Yun Kyung Lee

Subjects
inorganic chemicals, chemistry.chemical_classification, Denitrification, organic chemicals, Materials Science (miscellaneous), Inorganic ions, Catalysis, Adsorption, chemistry, Environmental chemistry, Organic matter, Zeolite, Bimetallic strip, Groundwater, General Environmental Science
Abstract

Nitrate (NO3−) contamination has dramatically increased owing to extensive human activities, which may cause severe problems on human health and the environment. Recently, catalytic denitrification of NO3− to N2 has attracted much attention owing to its highly fast reaction with high N2 selectivity. However, only a few studies have investigated the effect of natural substances in real groundwater on catalytic denitrification, particularly the type of natural organic matter (NOM) and combined effect of NOM and ionic ions. Herein, we investigated the effects of natural dissolved inorganic and organic matter on catalytic denitrification of contaminated groundwater using a novel Pd–In bimetallic catalyst supported on kaolin-derived zeolite (ZK). Pd–In/ZK showed a highly enhanced performance for denitrification, resulting in a high turnover frequency (18.9 × 10−3 s−1) and N2 selectivity (98%). Various surface analyses confirmed that the rejuvenation of In by active H on Pd sites is the key factor that controls the enhanced NO3− reduction and high N2 selectivity. Applying the optimized Pd–In/ZK catalyst to NO3− contaminated groundwater revealed that its catalytic activity was significantly affected by various constituents in groundwater. Particularly, the results from fluorescence excitation emission matrix spectroscopy showed that humic-like and fulvic-like organic substances potentially inhibited the catalytic NO3− reduction owing to their adsorption onto the catalyst surface. Furthermore, some inorganic ions inhibited the catalytic NO3− reduction via different inhibitory mechanisms, i.e. the competitive adsorption of Cl− and SO42− with NO3− and catalyst fouling induced by formation of CaCO3(s). The novel findings from this study highlight the potential applicability of ZK as a value-adding support material for catalytic denitrification and emphasize the effect of dissolved organic and inorganic matters in groundwater on the catalytic activity of bimetallic catalysts.

Published
2020
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6. Highly fast and selective removal of nitrate in groundwater by bimetallic catalysts supported by fly ash-derived zeolite Na-X

Author

Sungjun Bae, Jong Kwon Choe, Jaehyeong Park, and Woojin Lee

Subjects
Chemistry, Materials Science (miscellaneous), Inorganic chemistry, Nanoparticle, 02 engineering and technology, 010501 environmental sciences, 021001 nanoscience & nanotechnology, 01 natural sciences, Catalysis, Metal, Chemisorption, visual_art, visual_art.visual_art_medium, 0210 nano-technology, Selectivity, Zeolite, Dispersion (chemistry), Bimetallic strip, 0105 earth and related environmental sciences, General Environmental Science
Abstract

A novel and sustainable Pd–Sn bimetallic catalyst supported by fly ash-derived zeolite Na-X (Zeolite-XF) was developed for highly reactive and N2-selective reduction of nitrate in water. The surface characteristics of Zeolite-XF and Pd–Sn/Zeolite-XF were identified via various surface analyses, which showed formation of zeolite Na-X crystals with high purity and uniform dispersion of Pd and Sn nanoparticles on the surfaces of Pd–Sn/Zeolite-XF. Pd–Sn/Zeolite-XF showed a 43.1 × 10−3 s−1 turnover frequency (TOF) with almost 90% N2 selectivity under optimal conditions, which is 4–92 times higher than those of previously reported Pd based bimetallic catalysts. The great catalytic activity was elucidated by XPS and H2-pulse chemisorption analysis, demonstrating that Zeolite-XF enhanced metal dispersion and increased the active metallic sites of Pd and Sn nanoparticles. Furthermore, the optimized Pd–Sn/Zeolite-XF catalyst was tested for reduction of nitrate in real groundwater, which showed the complete removal with 94% N2 selectivity. The experimental results obtained from this study can provide a new insight that discarded solid waste can be converted to value-added environmental materials for synthesis of highly active catalysts, which surpass other freshly synthesized and commercially produced materials.

Published
2020
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9. Novel ssDNA aptamer-based fluorescence sensor for perfluorooctanoic acid detection in water

Author

Jong Kwon Choe, Yongju Choi, Jun-Young Park, and Kyung-Ae Yang

Subjects
Perfluorooctanoic acid detection, Aptamer, Water monitoring, Dissolved Organic Matter, Fluorescence-based aptasensor, Fluorescence, chemistry.chemical_compound, GE1-350, Binding site, General Environmental Science, Detection limit, Fluorescence sensor, Fluorocarbons, Chemistry, Water, Combinatorial chemistry, Dissociation constant, Environmental sciences, Alkanesulfonic Acids, Functional group, Binding mechanism, Perfluorooctanoic acid, Perfluoroalkyl substance, Caprylates, Water Pollutants, Chemical
Abstract

Per- and polyfluoroalkyl substances (PFAS) are widely detected environmental contaminants, and there is a great need for development of sensor technologies for rapid and continuous monitoring of PFAS. In this study, we have developed fluorescence based aptasensor that can possibly monitor perfluorooctanoic acid (PFOA) in water with limit of detection (LOD) of 0.17 μM. This is first to report the successful isolation of PFAS binding ssDNA aptamers. The obtained aptamer selectively binds PFOA with dissociation constant (KD) of 5.5 μM. Specific aptamer binding sites to PFOA were identified and the length of the fluorinated carbons was a key binding factor rather than the functional group. The aptamer binding to structurally similar PFAS compounds (i.e., perfluorocarboxylic acids and perfluorosulfonic acids with 4–8 carbon chains) was also investigated; the aptamer KD values were 6.5 and 3.3 μM for perfluoroheptanoic acid and perfluorohexanesulfonic acid, respectively, while other analogs did not bind to the aptamer. The presence of major inorganic ions and dissolved organic matter had negligible influences on the aptamer performance (

Published
2021

10. Effect of using powdered biochar and surfactant on desorption and biodegradability of phenanthrene sorbed to biochar

Author

Seju Kang, Yongju Choi, Geunyoung Kim, and Jong Kwon Choe

Subjects
Environmental Engineering, Health, Toxicology and Mutagenesis, 0211 other engineering and technologies, 02 engineering and technology, 010501 environmental sciences, 01 natural sciences, Husk, Surface-Active Agents, chemistry.chemical_compound, Pulmonary surfactant, Desorption, Biochar, Environmental Chemistry, Waste Management and Disposal, 0105 earth and related environmental sciences, 021110 strategic, defence & security studies, Phenanthrenes, Biodegradation, Phenanthrene, Pollution, Biodegradation, Environmental, chemistry, Charcoal, Environmental chemistry, Powders, Pyrolysis, Sludge
Abstract

The present study aimed to investigate the relationship between the desorption and biodegradability of phenanthrene sorbed to biochars by employing two approaches that may change the desorption and biodegradability: the use of powdered biochars and nonionic surfactants. Biochars derived from two feedstocks (rice husk and sewage sludge; pyrolyzed at 500 °C but showing different aromaticity) were used. When the biochars were powdered to obtain particles f d e s ) increased from 0.303 to 0.431 for sewage sludge biochars. On the other hand, f d e s for rice husk biochars remained virtually unchanged (from 0.264 to 0.255). The mass fractions of the biodegraded phenanthrene ( f b i o ) increased from 0.191 to 0.306 for rice husk biochars and from 0.077 to 0.168 for sewage sludge biochars. When a nonionic surfactant was added at the sub-critical micelle concentration (CMC), f b i o increased by 4.7 times and 8.3 times for rice husk and sewage sludge biochars. For both types of biochars, f b i o was larger than f d e s when the surfactant was added. This study suggests that the addition of nonionic surfactants can be considered if the inhibition of microbial activity is of concern in soils and sediments treated by biochar.

Published
2019
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11. Exploring reductive degradation of fluorinated pharmaceuticals using Al

Author

Jaehyeong, Park, Seonyoung, An, Eun Hea, Jho, Sungjun, Bae, Yongju, Choi, and Jong Kwon, Choe

Subjects
Halogenation, Pharmaceutical Preparations, Aluminum Oxide, Hydrogenation, Catalysis
Abstract

Recently, an increasing number of pharmaceutical compounds has become fluorinated. Owing to their pharmacological efficacy, the use of these fluorinated pharmaceuticals continues to grow, and they constitute 20% of the drugs on the current market. However, only a few studies have investigated the fate and transformation of these emerging contaminants in natural and engineered aquatic environments. In the present study, the H

Published
2020

12. Economic and environmental sustainability and public perceptions of rooftop farm versus extensive garden

Author

Miran Lee, Euna Kim, Jong Kwon Choe, Yongju Choi, Gita Hapsari, Mooyoung Han, Seju Kang, Saerom Yoon, Kibeum Kim, and Jihyeun Jung

Subjects
Environmental Engineering, 010504 meteorology & atmospheric sciences, business.industry, Total cost, Geography, Planning and Development, Green roof, Building and Construction, 010501 environmental sciences, 01 natural sciences, Agricultural economics, Flat roof, Geography, Agriculture, Economic cost, Sustainability, business, Roof, Roof garden, 0105 earth and related environmental sciences, Civil and Structural Engineering
Abstract

Green roofs have become popular in urban areas as a solution to restore green space in cities and mitigate urban problems. In this study, the economic and environmental sustainability of using green roofs for rooftop agriculture (i.e., roof farms) is evaluated and compared with that of using green roofs as extensive gardens of flowers and non-edible plants with low maintenance (i.e., roof gardens) based on these two green roofs that were installed and operated for over five years in a university building in Seoul, Korea. The life cycle cost analysis results show that the total cost of the roof garden is 38.9% lower than the flat roof whereas the total cost of the roof farm is 68.3% higher than the roof garden. The environmental impacts of both the roof garden and farm were 2.4–35 times as high as those of the flat roof. The need to frequently replenish the lightweight soil over its lifetime was the main contributor to both the economic cost and environmental impacts of the roof farm, suggesting a need to develop cost-effective and environmentally benign lightweight soil materials. A survey was also conducted to investigate public preferences and perceptions of these two green roof options. Over 80% of the respondents expressed the necessity for green roofs in urban areas, and 79.3% preferred roof gardens over farms. Our results show that roof farms have several merits in urban areas, especially social benefits, but future research should focus on improving their economic and environmental sustainability.

Published
2018
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13. Anionic surfactant modification of activated carbon for enhancing adsorption of ammonium ion from aqueous solution

Author

Yongju Choi, Woo Ram Lee, Jong Kwon Choe, Miran Lee, and Sangwon Yoon

Subjects
021110 strategic, defence & security studies, Environmental Engineering, Aqueous solution, Ion exchange, Chemistry, 0211 other engineering and technologies, 02 engineering and technology, 010501 environmental sciences, 01 natural sciences, Pollution, chemistry.chemical_compound, Adsorption, Pulmonary surfactant, Desorption, medicine, Environmental Chemistry, Ammonium, Sodium dodecyl sulfate, Waste Management and Disposal, 0105 earth and related environmental sciences, Nuclear chemistry, Activated carbon, medicine.drug
Abstract

This study investigates the effect of anionic surfactant modification on activated carbon (AC) to enhance the adsorption of ammonium ion in aqueous solution. Sodium dodecyl sulfate (SDS), sodium dodecyl benzene sulfonate (SDBS) or sodium octanoate (SO) was used for the modification. At the initial aqueous concentration of 55 mg NH4-N/L and the adsorbent dose of 50 g/L, the SDS-modified AC showed the highest ammonium removal efficiency of 82% among the modified ACs studied. The hydrophobic group of SDS was strongly attached to AC showing almost negligible desorption after the modification. At the same time, the sulfate functional group of SDS provided ion exchange sites favorable for the ammonium ion adsorption. By maximizing SDS loading to the AC, ammonium removal efficiency can further be improved (5% increase). When Na+, K+ or Ca2+ coexisted in the ammonium solution at the concentration of 55 mg/L, the inhibition effect of these cations on ammonium removal efficiency was negligible (

Published
2018
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14. Chlorotyrosines versus Volatile Byproducts from Chlorine Disinfection during Washing of Spinach and Lettuce

Author

William A. Mitch, Yukako Komaki, Jong Kwon Choe, Adam M.-A. Simpson, and Michael J. Plewa

Subjects
Halogenation, Disinfectant, chemistry.chemical_element, CHO Cells, 010501 environmental sciences, 01 natural sciences, Water Purification, Cricetulus, Spinacia oleracea, Cricetinae, polycyclic compounds, Chlorine, Animals, Environmental Chemistry, 0105 earth and related environmental sciences, biology, Chemistry, business.industry, 010401 analytical chemistry, General Chemistry, Lettuce, Pulp and paper industry, biology.organism_classification, Food safety, 0104 chemical sciences, Disinfection, Food packaging, Current practice, Tyrosine, Spinach, business, Water Pollutants, Chemical, Disinfectants
Abstract

Following the Food Safety Modernization Act of 2011 in the U.S., guidelines for disinfection washes in food packaging facilities are under consideration to control pathogen risks. However, disinfectant exposures may need optimization because the high concentrations of chlorine disinfectant promote the formation of high levels of disinfection byproducts (DBPs). When chlorine doses up through the 200 mg/L as Cl2 range relevant to the current practice were applied to spinach and lettuce, significant DBP formation was observed, even within 5 min at 7 °C. Concentrations of volatile chlorinated DBPs in washwater were far higher than typically observed in disinfected drinking water (e.g., 350 μg/L 1,1-dichloropropanone). However, these DBPs partitioned to the aqueous phase and so represent a greater concern for the disposal or reuse of washwater than for consumer exposure via food. The volatile DBPs represent the low-yield, final products of chlorination reactions with multiple biomolecular precursors. The initi...

Published
2018
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15. Synthesis of benzaldoxime from benzaldehyde using nanoscale zero-valent iron and dissolved nitrate or nitrite

Author

Woojin Lee, Jong Kwon Choe, Macharla Arun Kumar, and Sukhwan Yoon

Subjects
Zerovalent iron, Reaction mechanism, Materials Science (miscellaneous), Inorganic chemistry, chemistry.chemical_element, 02 engineering and technology, Management, Monitoring, Policy and Law, 010402 general chemistry, 021001 nanoscience & nanotechnology, 01 natural sciences, Pollution, Nitrogen, 0104 chemical sciences, Benzaldehyde, chemistry.chemical_compound, Hydroxylamine, chemistry, Nitrate, Yield (chemistry), Nitrite, 0210 nano-technology, Waste Management and Disposal, Water Science and Technology
Abstract

Surface and ground water contamination with NO 2 − /NO 3 − is one of the most serious environmental issues due to their adverse effects on human health and ecosystem. Various technologies have been investigated for removal of NO 2 − /NO 3 − from surface and ground water; nevertheless, the idea of utilizing NO 2 − /NO 3 − contaminated water and wastewater to produce value-added products has not yet been much explored to date. Here, we have developed a novel method for utilizing NO 2 − /NO 3 − -contaminated water as a source of nitrogen for the synthesis of benzaldoxime from benzaldehyde using ecofriendly nanoscale zero-valent iron (nZVI) as the reductant. Control experiments with NH 4 + and NH 2 OH supported the proposed reaction mechanism that NH 2 OH was generated in situ as a reactive intermediate from NO 2 − /NO 3 − reduction and reacted with benzaldehyde to form benzaldoxime. The benzaldoxime yield was the largest at the highest temperature tested, 100 °C, and an nZVI-to-N ratio of ∼7 was optimal for benzaldoxime synthesis. At 100 °C, O 2 in the headspace did not have any negative effect on the reaction. Benzaldoxime yields up to 0.70 ± 0.04 mmoles and 0.67 ± 0.05 mmoles were observed from reaction of 1 mmole benzaldehyde with 2 mmoles NO 2 − and NO 3 − , respectively. Meanwhile, >95% of NO 2 − /NO 3 − were reduced to either benzaldoxime or NH 4 + . This novel method suggests a promising option for utilization of water contaminated with NO 2 − /NO 3 − for the production of a value-added product.

Published
2017
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16. Serum electrolytes can promote hydroxyl radical-initiated biomolecular damage from inflammation

Author

William A. Mitch, Margaux M. Pinney, Daniel Herschlag, Jong Kwon Choe, Yukako Komaki, Adam M.-A. Simpson, and Yi-Hsueh Chuang

Subjects
0301 basic medicine, Free Radicals, Radical, Carbonates, Protein degradation, medicine.disease_cause, Biochemistry, 03 medical and health sciences, chemistry.chemical_compound, Electrolytes, 0302 clinical medicine, Halogens, Physiology (medical), Carbonic anhydrase, medicine, Humans, chemistry.chemical_classification, Inflammation, Reactive oxygen species, biology, Hydroxyl Radical, Catalase, Kinetics, Oxidative Stress, 030104 developmental biology, Enzyme, chemistry, Proteolysis, biology.protein, Hydroxyl radical, Reactive Oxygen Species, Oxidation-Reduction, 030217 neurology & neurosurgery, Oxidative stress, Water Pollutants, Chemical
Abstract

Chronic inflammatory disorders are associated with biomolecular damage attributed partly to reactions with Reactive Oxygen Species (ROS), particularly hydroxyl radicals (•OH). However, the impacts of serum electrolytes on ROS-associated damage has received little attention. We demonstrate that the conversion of •OH to carbonate and halogen radicals via reactions with serum-relevant carbonate and halide concentrations fundamentally alters the targeting of amino acids and loss of enzymatic activity in catalase, albumin and carbonic anhydrase, three important blood proteins. Chemical kinetic modeling indicated that carbonate and halogen radical concentrations should exceed •OH concentrations by 6 and 2 orders of magnitude, respectively. Steady-state γ-radiolysis experiments demonstrated that serum-level carbonates and halides increased tyrosine, tryptophan and enzymatic activity losses in catalase up to 6-fold. These outcomes were specific to carbonates and halides, not general ionic strength effects. Serum carbonates and halides increased the degradation of tyrosines and methionines in albumin, and increased the degradation of histidines while decreasing enzymatic activity loss in carbonic anhydrase. Serum electrolytes increased the degradation of tyrosines, tryptophans and enzymatic activity in the model enzyme, ketosteroid isomerase, predominantly due to carbonate radical reactions. Treatment of a mutant ketosteroid isomerase indicated that preferential targeting of the active site tyrosine accounted for half of the total tyrosine loss. The results suggest that carbonate and halogen radicals may be more significant than •OH as drivers for protein degradation in serum. Accounting for the selective targeting of biomolecules by these daughter radicals is important for developing a mechanistic understanding of the consequences of oxidative stress.

Published
2019

17. A New Bioinspired Perchlorate Reduction Catalyst with Significantly Enhanced Stability via Rational Tuning of Rhenium Coordination Chemistry and Heterogeneous Reaction Pathway

Author

Timothy J. Strathmann, Xi Chen, Dimao Wu, Jinyong Liu, Mengwei Han, Jong Kwon Choe, and Charles J. Werth

Subjects
chemistry.chemical_element, 010501 environmental sciences, Ligands, 010402 general chemistry, Photochemistry, 01 natural sciences, Catalysis, Coordination complex, Perchlorate, chemistry.chemical_compound, Polymer chemistry, Environmental Chemistry, 0105 earth and related environmental sciences, chemistry.chemical_classification, Perchlorates, Aqueous solution, Chemistry, Ligand, General Chemistry, Rhenium, Decomposition, 0104 chemical sciences, Chlorite dismutase, Oxidation-Reduction
Abstract

Rapid reduction of aqueous ClO4(-) to Cl(-) by H2 has been realized by a heterogeneous Re(hoz)2-Pd/C catalyst integrating Re(O)(hoz)2Cl complex (hoz = oxazolinyl-phenolato bidentate ligand) and Pd nanoparticles on carbon support, but ClOx(-) intermediates formed during reactions with concentrated ClO4(-) promote irreversible Re complex decomposition and catalyst deactivation. The original catalyst design mimics the microbial ClO4(-) reductase, which integrates Mo(MGD)2 complex (MGD = molybdopterin guanine dinucleotide) for oxygen atom transfer (OAT). Perchlorate-reducing microorganisms employ a separate enzyme, chlorite dismutase, to prevent accumulation of the destructive ClO2(-) intermediate. The structural intricacy of MGD ligand and the two-enzyme mechanism for microbial ClO4(-) reduction inspired us to improve catalyst stability by rationally tuning Re ligand structure and adding a ClOx(-) scavenger. Two new Re complexes, Re(O)(htz)2Cl and Re(O)(hoz)(htz)Cl (htz = thiazolinyl-phenolato bidentate ligand), significantly mitigate Re complex decomposition by slightly lowering the OAT activity when immobilized in Pd/C. Further stability enhancement is then obtained by switching the nanoparticles from Pd to Rh, which exhibits high reactivity with ClOx(-) intermediates and thus prevents their deactivating reaction with the Re complex. Compared to Re(hoz)2-Pd/C, the new Re(hoz)(htz)-Rh/C catalyst exhibits similar ClO4(-) reduction activity but superior stability, evidenced by a decrease of Re leaching from 37% to 0.25% and stability of surface Re speciation following the treatment of a concentrated "challenge" solution containing 1000 ppm of ClO4(-). This work demonstrates the pivotal roles of coordination chemistry control and tuning of individual catalyst components for achieving both high activity and stability in environmental catalyst applications.

Published
2016
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18. Exploring reductive degradation of fluorinated pharmaceuticals using Al2O3-supported Pt-group metallic catalysts: Catalytic reactivity, reaction pathways, and toxicity assessment

Author

Yongju Choi, Seonyoung An, Eun Hea Jho, Sungjun Bae, Jong Kwon Choe, and Jaehyeong Park

Subjects
Environmental Engineering, Chemistry, Ecological Modeling, 0208 environmental biotechnology, Selective catalytic reduction, Ether, 02 engineering and technology, 010501 environmental sciences, 01 natural sciences, Pollution, 020801 environmental engineering, Catalysis, Metal, chemistry.chemical_compound, Hydrodefluorination, visual_art, Toxicity, visual_art.visual_art_medium, Organic chemistry, Reactivity (chemistry), Waste Management and Disposal, Bimetallic strip, 0105 earth and related environmental sciences, Water Science and Technology, Civil and Structural Engineering
Abstract

Recently, an increasing number of pharmaceutical compounds has become fluorinated. Owing to their pharmacological efficacy, the use of these fluorinated pharmaceuticals continues to grow, and they constitute 20% of the drugs on the current market. However, only a few studies have investigated the fate and transformation of these emerging contaminants in natural and engineered aquatic environments. In the present study, the H2-based reductive transformation of three fluorinated pharmaceutical compounds (levofloxacin, sitagliptin, and fluoxetine) were investigated using alumina-supported monometallic and bimetallic catalysts of the Pt-group noble metals (i.e., Ru, Rh, Pd, and Pt) under ambient temperature and pressure conditions. Degradation of all three compounds was observed with catalytic reactivity ranging from 4.0 × 10−3 to 2.14 × 102 L/(min·gcat), in which fluoxetine generally showed the highest reactivity, followed by sitagliptin and levofloxacin. The fluorination yields and transformation products were characterized for each fluorinated compound and three different degradation mechanisms were elucidated: 1) hydrodefluorination of C-F bond to C H bond, 2) hydrogenation of aromatic ring, and 3) reductive cleavage of C O bond from phenyl ether. Toxicity assessment using Aliivibrio fischeri showed there were no significant changes in toxicity over levofloxacin and sitagliptin degradation, suggesting the formation of no highly toxic by-products during catalytic reduction. For fluoxetine, an increased toxicity was observed during its degradation while ECOSAR-predicted toxicity values of all identified intermediates were lower than that of fluoxetine, suggesting the formation of unidentified secondary by-products that contribute to the overall toxicity. The study showed that catalytic reduction is a promising remediation process for treating and defluorinating the fluorinated pharmaceutical compounds.

Published
2020
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19. Achieving effective fructose-to-5-hydroxymethylfurfural conversion via facile synthesis of large surface phosphate-functionalized porous organic polymers

Author

Jong Kwon Choe, Seenu Ravi, and Yongju Choi

Subjects
chemistry.chemical_classification, genetic structures, Process Chemistry and Technology, Fructose, 02 engineering and technology, Polymer, 010402 general chemistry, 021001 nanoscience & nanotechnology, Phosphate, 01 natural sciences, Catalysis, 0104 chemical sciences, Solvent, chemistry.chemical_compound, chemistry, 5-hydroxymethylfurfural, Organic chemistry, 0210 nano-technology, Selectivity, Porosity, General Environmental Science
Abstract

Efficient conversion of fructose to 5-hydroxymethylfurfural (HMF) is a key step for producing fuels and value-added chemicals from carbohydrates. Here, we report for the first time the applicability of phosphate-functionalized porous organic polymers (POPs) as a catalyst for fructose conversion. Two catalysts, B-POP and P-POP, were synthesized via a simple one-pot reaction and B-POP showed high surface area (1193 m2 g−1) and high mesoporosity (54.7 %) with 1.7 mmol g−1 of phosphate groups available as surface acid sites. The catalytic activity of the phosphate functionalized POPs was investigated using different solvents, and B-POP yielded 100 % fructose conversion with 85 % HMF selectivity within 30 min (equivalent to a turnover frequency of 32.2 h−1, the highest activity among other previously reported acid-based heterogeneous catalysts) when DMSO/1,4-dioxane dual solvent medium was used at 130 °C. These results suggested that phosphate group-functionalized POPs can be promising heterogeneous catalysts for producing biobased platform chemicals from renewable resources.

Published
2020
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20. Degradation of Amino Acids and Structure in Model Proteins and Bacteriophage MS2 by Chlorine, Bromine, and Ozone

Author

David H. Richards, Jong Kwon Choe, Corey J. Wilson, and William A. Mitch

Subjects
Amino Acid Motifs, Lysine, Antioxidants, chemistry.chemical_compound, Methionine, Ozone, Bacteriophage MS2, Environmental Chemistry, Histidine, Amino Acids, Tyrosine, Levivirus, chemistry.chemical_classification, Chloramine, biology, Bromates, Methionine sulfoxide, Chloramines, Proteins, General Chemistry, Bromine, Oxidants, biology.organism_classification, Amino acid, chemistry, Biochemistry, Chlorine, Oxidation-Reduction, Disinfectants
Abstract

Proteins are important targets of chemical disinfectants. To improve the understanding of disinfectant-protein reactions, this study characterized the disinfectant:protein molar ratios at which 50% degradation of oxidizable amino acids (i.e., Met, Tyr, Trp, His, Lys) and structure were observed during HOCl, HOBr, and O3 treatment of three well-characterized model proteins and bacteriophage MS2. A critical question is the extent to which the targeting of amino acids is driven by their disinfectant rate constants rather than their geometrical arrangement. Across the model proteins and bacteriophage MS2 (coat protein), differing widely in structure, methionine was preferentially targeted, forming predominantly methionine sulfoxide. This targeting concurs with its high disinfectant rate constants and supports its hypothesized role as a sacrificial antioxidant. Despite higher HOCl and HOBr rate constants with histidine and lysine than for tyrosine, tyrosine generally was degraded in preference to histidine, and to a lesser extent, lysine. These results concur with the prevalence of geometrical motifs featuring histidines or lysines near tyrosines, facilitating histidine and lysine regeneration upon Cl[+1] transfer from their chloramines to tyrosines. Lysine nitrile formation occurred at or above oxidant doses where 3,5-dihalotyrosine products began to degrade. For O3, which lacks a similar oxidant transfer pathway, histidine, tyrosine, and lysine degradation followed their relative O3 rate constants. Except for its low reactivity with lysine, the O3 doses required to degrade amino acids were as low as or lower than for HOCl or HOBr, indicating its oxidative efficiency. Loss of structure did not correlate with loss of particular amino acids, suggesting the need to characterize the oxidation of specific geometric motifs to understand structural degradation.

Published
2015
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21. Performance and life cycle environmental benefits of recycling spent ion exchange brines by catalytic treatment of nitrate

Author

Allison M. Bergquist, Jong Kwon Choe, Timothy J. Strathmann, Charles J. Werth, Sangjo Jeong, and Jeremy S. Guest

Subjects
Environmental Engineering, Sodium Chloride, Catalysis, Water Purification, chemistry.chemical_compound, Bioreactors, Nitrate, medicine, Hybrid reactor, Recycling, Waste Management and Disposal, Water Science and Technology, Civil and Structural Engineering, Nitrates, Ion exchange, Waste management, Sulfates, Ecological Modeling, Reproducibility of Results, Selective catalytic reduction, Carbon Dioxide, Hydrogen-Ion Concentration, Pulp and paper industry, Pollution, Ion Exchange, Bicarbonates, Brine, Models, Chemical, chemistry, Carbon dioxide, Salts, Algorithms, Water Pollutants, Chemical, Hydrogen, Activated carbon, medicine.drug
Abstract

Salt used to make brines for regeneration of ion exchange (IX) resins is the dominant economic and environmental liability of IX treatment systems for nitrate-contaminated drinking water sources. To reduce salt usage, the applicability and environmental benefits of using a catalytic reduction technology to treat nitrate in spent IX brines and enable their reuse for IX resin regeneration were evaluated. Hybrid IX/catalyst systems were designed and life cycle assessment of process consumables are used to set performance targets for the catalyst reactor. Nitrate reduction was measured in a typical spent brine (i.e., 5000 mg/L NO3(-) and 70,000 mg/L NaCl) using bimetallic Pd-In hydrogenation catalysts with variable Pd (0.2-2.5 wt%) and In (0.0125-0.25 wt%) loadings on pelletized activated carbon support (Pd-In/C). The highest activity of 50 mgNO3(-)/(min - g(Pd)) was obtained with a 0.5 wt%Pd-0.1 wt%In/C catalyst. Catalyst longevity was demonstrated by observing no decrease in catalyst activity over more than 60 days in a packed-bed reactor. Based on catalyst activity measured in batch and packed-bed reactors, environmental impacts of hybrid IX/catalyst systems were evaluated for both sequencing-batch and continuous-flow packed-bed reactor designs and environmental impacts of the sequencing-batch hybrid system were found to be 38-81% of those of conventional IX. Major environmental impact contributors other than salt consumption include Pd metal, hydrogen (electron donor), and carbon dioxide (pH buffer). Sensitivity of environmental impacts of the sequencing-batch hybrid reactor system to sulfate and bicarbonate anions indicate the hybrid system is more sustainable than conventional IX when influent water contains80 mg/L sulfate (at any bicarbonate level up to 100 mg/L) or20 mg/L bicarbonate (at any sulfate level up to 100 mg/L) assuming 15 brine reuse cycles. The study showed that hybrid IX/catalyst reactor systems have potential to reduce resource consumption and improve environmental impacts associated with treating nitrate-contaminated water sources.

Published
2015
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22. Effect of biochar particle size on hydrophobic organic compound sorption kinetics: Applicability of using representative size

Author

Jong Kwon Choe, Jihyeun Jung, Yongju Choi, Yong Sik Ok, and Seju Kang

Subjects
chemistry.chemical_classification, 021110 strategic, defence & security studies, Range (particle radiation), Environmental Engineering, Inorganic chemistry, Kinetics, 0211 other engineering and technologies, Sorption, 02 engineering and technology, 010501 environmental sciences, Phenanthrene, 01 natural sciences, Pollution, Organic compound, chemistry.chemical_compound, chemistry, Chemical engineering, Particle-size distribution, Biochar, Environmental Chemistry, Particle size, Waste Management and Disposal, 0105 earth and related environmental sciences
Abstract

Particle size of biochar may strongly affect the kinetics of hydrophobic organic compound (HOC) sorption. However, challenges exist in characterizing the effect of biochar particle size on the sorption kinetics because of the wide size range of biochar. The present study suggests a novel method to determine a representative value that can be used to show the dependence of HOC sorption kinetics to biochar particle size on the basis of an intra-particle diffusion model. Biochars derived from three different feedstocks are ground and sieved to obtain three daughter products each having different size distributions. Phenanthrene sorption kinetics to the biochars are well described by the intra-particle diffusion model with significantly greater sorption rates observed for finer grained biochars. The time to reach 95% of equilibrium for phenanthrene sorption to biochar is reduced from 4.6-17.9days for the original biochars to

Published
2017

23. Bioinspired Complex-Nanoparticle Hybrid Catalyst System for Aqueous Perchlorate Reduction: Rhenium Speciation and Its Influence on Catalyst Activity

Author

John R. Shapley, Timothy J. Strathmann, Charles J. Werth, Yin Wang, Jinyong Liu, and Jong Kwon Choe

Subjects
Aqueous solution, Inorganic chemistry, chemistry.chemical_element, Oxyanion, General Chemistry, Rhenium, Catalysis, Perchlorate, chemistry.chemical_compound, Electron transfer, chemistry, Bimetallic strip, Palladium
Abstract

A highly active catalyst for reduction of the inert water contaminant perchlorate (ClO4–) to Cl– with 1 atm H2 at 25 °C is prepared by noncovalently immobilizing the rhenium complex ReV(O)(hoz)2Cl (hoz = 2-(2′-hydroxyphenyl)-2-oxazoline) together with Pd0 nanoparticles on a porous carbon support. Like the Mo complex centers in biological oxyanion reductases, the immobilized Re complex serves as a single site for oxygen atom transfer from ClO4– and ClOx– intermediates, whereas Pd0 nanoparticles provide atomic hydrogen reducing equivalents to sustain redox cycling of the immobilized Re sites, replacing the more complex chain of electron transfer steps that sustain Mo centers within oxyanion reductases. An in situ aqueous adsorption method of immobilization was used to preserve the active ReV(O)(hoz)2 structure during bimetallic catalyst preparation and enable study of Re redox cycling and reactions with ClO4–. Heterogeneous reaction kinetics, X-ray photoelectron spectroscopy, and experiments with homogeneou...

Published
2014
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24. X-ray Spectroscopic Characterization of Immobilized Rhenium Species in Hydrated Rhenium–Palladium Bimetallic Catalysts Used for Perchlorate Water Treatment

Author

Jinyong Liu, Timothy J. Strathmann, Kenneth M. Kemner, Maxim I. Boyanov, Jong Kwon Choe, and Charles J. Werth

Subjects
inorganic chemicals, Aqueous solution, Perrhenate, Inorganic chemistry, chemistry.chemical_element, Electron donor, Rhenium, Surfaces, Coatings and Films, Electronic, Optical and Magnetic Materials, Catalysis, Perchlorate, chemistry.chemical_compound, General Energy, Adsorption, chemistry, Physical and Theoretical Chemistry, Palladium
Abstract

Carbon-supported rhenium–palladium catalysts (Re–Pd/C) effectively transform aqueous perchlorate, a widespread drinking water pollutant, via chemical reduction using hydrogen as an electron donor at ambient temperature and pressure. Previous work demonstrated that catalyst activity and stability are heavily dependent on solution composition and Re content in the catalyst. This study relates these parameters to changes in the speciation and molecular structure of Re immobilized on the catalyst. Using X-ray spectroscopy techniques, we show that Re is immobilized as ReVII under oxic solution conditions, but transforms to a mixture of reduced, O-coordinated Re species under reducing solution conditions induced by H2 sparging. Under oxic solution conditions, extended X-ray absorption fine structure (EXAFS) analysis showed that the immobilized ReVII species is indistinguishable from the dissolved tetrahedral perrhenate (ReO4–) anion, suggesting outer-sphere adsorption to the catalyst surface. Under reducing sol...

Published
2014
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25. Comparative Assessment of the Environmental Sustainability of Existing and Emerging Perchlorate Treatment Technologies for Drinking Water

Author

Timothy J. Strathmann, Jong Kwon Choe, Michelle H. Mehnert, Charles J. Werth, and Jeremy S. Guest

Subjects
Perchlorates, Consumables, Drinking Water, Environmental engineering, General Chemistry, Water Purification, Perchlorate, chemistry.chemical_compound, chemistry, Nitrate, Brining, Sustainability, Environmental Chemistry, Water treatment, Resource consumption, Life-cycle assessment
Abstract

Environmental impacts of conventional and emerging perchlorate drinking water treatment technologies were assessed using life cycle assessment (LCA). Comparison of two ion exchange (IX) technologies (i.e., nonselective IX with periodic regeneration using brines and perchlorate-selective IX without regeneration) at an existing plant shows that brine is the dominant contributor for nonselective IX, which shows higher impact than perchlorate-selective IX. Resource consumption during the operational phase comprises80% of the total impacts. Having identified consumables as the driving force behind environmental impacts, the relative environmental sustainability of IX, biological treatment, and catalytic reduction technologies are compared more generally using consumable inputs. The analysis indicates that the environmental impacts of heterotrophic biological treatment are 2-5 times more sensitive to influent conditions (i.e., nitrate/oxygen concentration) and are 3-14 times higher compared to IX. However, autotrophic biological treatment is most environmentally beneficial among all. Catalytic treatment using carbon-supported Re-Pd has a higher (ca. 4600 times) impact than others, but is within 0.9-30 times the impact of IX with a newly developed ligand-complexed Re-Pd catalyst formulation. This suggests catalytic reduction can be competitive with increased activity. Our assessment shows that while IX is an environmentally competitive, emerging technologies also show great promise from an environmental sustainability perspective.

Published
2013
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26. Structure Sensitivity Study of Waterborne Contaminant Hydrogenation Using Shape- and Size-Controlled Pd Nanoparticles

Author

Jong Kwon Choe, Charles J. Werth, Danmeng Shuai, Dorrell C. McCalman, John R. Shapley, and William F. Schneider

Subjects
Pollutant, Inorganic chemistry, chemistry.chemical_element, Selective catalytic reduction, General Chemistry, Contamination, Catalysis, chemistry.chemical_compound, chemistry, N-Nitrosodimethylamine, Nitrite, Dispersion (chemistry), Palladium
Abstract

Catalytic reduction with Pd has emerged as a promising technology to remove a suite of contaminants from drinking water, such as oxyanions, disinfection byproducts, and halogenated pollutants, but low activity is a major challenge for application. To address this challenge, we synthesized a set of shape- and size-controlled Pd nanoparticles and evaluated the activity of three probe contaminants (i.e., nitrite, N-nitrosodimethylamine (NDMA), and diatrizoate) as a function of facet type (e.g., (100), (110), (111)), ratios of low- to high-coordination sites, and ratios of surface sites to total Pd (i.e., dispersion). Reduction results for an initial contaminant concentration of 100 μM show that initial turnover frequency (TOF0) for nitrite increases 4.7-fold with increasing percent of (100) surface Pd sites (from 0% to 95.3%), whereas the TOF0 for NDMA and for diatrizoate increases 4.5- and 3.6-fold, respectively, with an increasing percent of terrace surface Pd sites (from 79.8% to 95.3%). Results for an in...

Published
2013
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27. Application of a Re–Pd bimetallic catalyst for treatment of perchlorate in waste ion-exchange regenerant brine

Author

Timothy J. Strathmann, Jinyong Liu, Zachary Sasnow, Charles J. Werth, and Jong Kwon Choe

Subjects
Environmental Engineering, Inorganic chemistry, Sodium Chloride, Waste Disposal, Fluid, Chloride, Catalysis, Perchlorate, chemistry.chemical_compound, medicine, Perchloric acid, Waste Management and Disposal, Water Science and Technology, Civil and Structural Engineering, Perchlorates, Ion exchange, Ecological Modeling, Selective catalytic reduction, Pollution, Rhenium, Brine, chemistry, Salts, Palladium, Water Pollutants, Chemical, Activated carbon, medicine.drug
Abstract

Concentrated sodium chloride (NaCl) brines are often used to regenerate ion-exchange (IX) resins applied to treat drinking water sources contaminated with perchlorate (ClO(4)(-)), generating large volumes of contaminated waste brine. Chemical and biological processes for ClO(4)(-) reduction are often inhibited severely by high salt levels, making it difficult to recycle waste brines. Recent work demonstrated that novel rhenium-palladium bimetallic catalysts on activated carbon support (Re-Pd/C) can efficiently reduce ClO(4)(-) to chloride (Cl(-)) under acidic conditions, and here the applicability of the process for treating waste IX brines was examined. Experiments conducted in synthetic NaCl-only brine (6-12 wt%) showed higher Re-Pd/C catalyst activity than in comparable freshwater solutions, but the rate constant for ClO(4)(-) reduction measured in a real IX waste brine was found to be 65 times lower than in the synthetic NaCl brine. Through a series of experiments, co-contamination of the IX waste brine by excess NO(3)(-) (which the catalyst reduces principally to NH(4)(+)) was found to be the primary cause for deactivation of the Re-Pd/C catalyst, most likely by altering the immobilized Re component. Pre-treatment of NO(3)(-) using a different bimetallic catalyst (In-Pd/Al(2)O(3)) improved selectivity for N(2) over NH(4)(+) and enabled facile ClO(4)(-) reduction by the Re-Pd/C catalyst. Thus, sequential catalytic treatment may be a promising strategy for enabling reuse of waste IX brine containing NO(3)(-) and ClO(4)(-).

Published
2013
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28. Evaluation of a hybrid ion exchange-catalyst treatment technology for nitrate removal from drinking water

Author

Allison M. Bergquist, Timothy J. Strathmann, Jong Kwon Choe, and Charles J. Werth

Subjects
Environmental Engineering, Portable water purification, 02 engineering and technology, 010501 environmental sciences, Reuse, 01 natural sciences, Catalysis, Water Purification, chemistry.chemical_compound, Nitrate, medicine, Waste Management and Disposal, 0105 earth and related environmental sciences, Water Science and Technology, Civil and Structural Engineering, Nitrates, Waste management, Ion exchange, Ecological Modeling, Drinking Water, 021001 nanoscience & nanotechnology, Pollution, Ion Exchange, Brine, chemistry, Hybrid system, Water treatment, 0210 nano-technology, Water Pollutants, Chemical, Activated carbon, medicine.drug
Abstract

Ion exchange (IX) is the most common approach to treating nitrate-contaminated drinking water sources, but the cost of salt to make regeneration brine, as well as the cost and environmental burden of waste brine disposal, are major disadvantages. A hybrid ion exchange-catalyst treatment system, in which waste brine is catalytically treated for reuse, shows promise for reducing costs and environmental burdens of the conventional IX system. An IX model with separate treatment and regeneration cycles was developed, and ion selectivity coefficients for each cycle were separately calibrated by fitting experimental data. Of note, selectivity coefficients for the regeneration cycle required fitting the second treatment cycle after incomplete resin regeneration. The calibrated and validated model was used to simulate many cycles of treatment and regeneration using the hybrid system. Simulated waste brines and a real brine obtained from a California utility were also evaluated for catalytic nitrate treatment in a packed-bed, flow-through column with 0.5 wt%Pd-0.05 wt%In/activated carbon support (PdIn/AC). Consistent nitrate removal and no apparent catalyst deactivation were observed over 23 d (synthetic brine) and 45 d (real waste brine) of continuous-flow treatment. Ion exchange and catalyst results were used to evaluate treatment of 1 billion gallons of nitrate-contaminated source water at a 0.5 MGD water treatment plant. Switching from a conventional IX system with a two bed volume regeneration to a hybrid system with the same regeneration length and sequencing batch catalytic reactor treatment would save 76% in salt cost. The results suggest the hybrid system has the potential to address the disadvantages of a conventional IX treatment systems.

Published
2016

29. Influence of Rhenium Speciation on the Stability and Activity of Re/Pd Bimetal Catalysts used for Perchlorate Reduction

Author

John R. Shapley, Charles J. Werth, Jong Kwon Choe, and Timothy J. Strathmann

Subjects
Perrhenate, Surface Properties, Inorganic chemistry, chemistry.chemical_element, Redox, Catalysis, chemistry.chemical_compound, Perchlorate, medicine, Environmental Chemistry, Perchlorates, Air, Photoelectron Spectroscopy, Sorption, General Chemistry, Rhenium, Solutions, Kinetics, chemistry, Charcoal, Adsorption, Leaching (metallurgy), Oxidation-Reduction, Palladium, Activated carbon, medicine.drug
Abstract

Recent work demonstrates reduction of aqueous perchlorate by hydrogen at ambient temperatures and pressures using a novel rhenium-palladium bimetal catalyst immobilized on activated carbon (Re/Pd-AC). This study examines the influence of Re speciation on catalyst activity and stability. Rates of perchlorate reduction are linearly dependent on Re content from 0-6 wt %, but no further increases are observed at higher Re contents. Surface-immobilized Re shows varying stability and speciation both in oxic versus H(2)-reducing environments and as a function of Re content. In oxic solutions, Re immobilization is dictated by sorption of the Re(VII) precursor, perrhenate (ReO(4)(-)), to activated carbon via electrostatic interactions. Under H(2)-reducing conditions, Re immobilization is significantly improved and leaching is minimized by ReO(4)(-) reduction to more reduced species on the catalyst surface. X-ray photoelectron spectroscopy shows two different Re binding energy states under H(2)-reducing conditions that correspond most closely to Re(V)/Re(IV) and Re(I) reference standards, respectively. The distribution of the two redox states varies with Re content, with the latter predominating at lower Re contents where catalyst activity is more strongly dependent on Re content. Results demonstrate that both lower Re contents and the maintenance of H(2)-reducing conditions are key elements in stabilizing the active Re surface species that are needed for sustained catalytic perchlorate treatment.

Published
2010
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30. Hydrothermal catalytic processing of saturated and unsaturated fatty acids to hydrocarbons with glycerol for in situ hydrogen production

Author

Timothy J. Strathmann, Brajendra K. Sharma, Dongwook Kim, Peter N. Ciesielski, Derek R. Vardon, Humberto Jaramillo, and Jong Kwon Choe

Subjects
chemistry.chemical_classification, Inorganic chemistry, Fatty acid, Pollution, chemistry.chemical_compound, Oleic acid, Hydrolysis, chemistry, Saturated fatty acid, Glycerol, Environmental Chemistry, Stearic acid, Deoxygenation, Unsaturated fatty acid, Nuclear chemistry
Abstract

Lipids are a promising feedstock to produce renewable hydrocarbon fuels and H2via catalytic hydrothermal processing. Upon exposure to hydrothermal media (e.g., 300 °C, 8–11 MPa), lipids rapidly hydrolyze to produce saturated and unsaturated free fatty acids in varying ratios, depending on the feedstock, as well as glycerol. This report demonstrates the potential of Pt–Re/C for the hydrothermal conversion of saturated and unsaturated fatty acids to hydrocarbons, using glycerol reforming for in situ H2 production to meet process demands. Experiments showed that deoxygenation of stearic acid, a model saturated fatty acid, was significantly enhanced with Pt–Re/C under a reducing atmosphere compared to Pt/C. The coupled hydrogenation and deoxygenation (HYD–DOX) of oleic aid, a model unsaturated fatty acid, was also moderately enhanced under an inert atmosphere using glycerol for in situ H2 production, with DOX as the rate-limiting step. Characterization of Pt–Re/C showed that Re had a significant effect on CO : H uptake ratio (2.2) compared to commercial Pt/C (1.3), with the metals dispersed as small crystallites (∼3–4 nm) throughout carbon support. Experiments revealed that the initial system H2 headspace loading

Published
2014
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