Dong‐Yeun Koh scite author profile

Liquid-phase separations of similarly sized organic molecules using membranes is a major challenge for energy-intensive industrial separation processes. We created free-standing carbon molecular sieve membranes that translate the advantages of reverse osmosis for aqueous separations to the separation of organic liquids. Polymer precursors were cross-linked with a one-pot technique that protected the porous morphology of the membranes from thermally induced structural rearrangement during carbonization. Permeation studies using benzene derivatives whose kinetic diameters differ by less than an angstrom show kinetically selective organic liquid reverse osmosis. Ratios of single-component fluxes for para- and ortho-xylene exceeding 25 were observed and para- and ortho- liquid mixtures were efficiently separated, with an equimolar feed enriched to 81 mole % para-xylene, without phase change and at ambient temperature.

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Mechanism and Kinetics of Oxidation Reaction of Aqueous Ti₃C₂T_x Suspensions at Different pHs and Temperatures

Doo

Chae

Kim

et al. 2021

ACS Appl. Mater. Interfaces

101

123

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Understanding the oxidation reaction of aqueous Ti3C2T x MXene suspensions is very important for fostering fundamental academic studies as well as widespread industrial applications. Herein, we investigated the mechanism and kinetics of the oxidation reaction of aqueous Ti3C2T x suspensions at various pH and temperature conditions. Through comprehensive analysis, the mechanism of the chemical oxidative degradation of aqueous Ti3C2T x colloids was established. Chemical oxidation produces solid products such as TiO2 and amorphous carbon as well as various gaseous species including CH4, CO, CO2, and HF. Additionally, our comprehensive kinetic study proposes that aqueous Ti3C2T x dispersions are degraded via an acid-catalyzed oxidation reaction, where, under acidic conditions, the protonation of the hydroxyl terminal groups on the Ti3C2T x flakes induces electron localization on titanium atoms and accelerates their oxidation reaction. In contrast, under basic conditions, the electrostatically alkali-metalized hydroxyl intermediates forming a bulky solvent cage results in less electron localization on titanium atoms, and thus retards their oxidative degradation.

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Energy-efficient natural gas hydrate production using gas exchange

et al. 2016

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Recovery of Methane from Gas Hydrates Intercalated within Natural Sediments Using CO₂ and a CO₂/N₂ Gas Mixture

et al. 2012

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The direct recovery of methane from massive methane hydrates (MHs), artificial MH-bearing clays, and natural MH-bearing sediments is demonstrated, using either CO(2) or a CO(2)/N(2) gas mixture (20 mol % of CO(2) and 80 mol % of N(2), reproducing flue gas from a power plant) for methane replacement in complex marine systems. Natural gas hydrates (NGHs) can be converted into CO(2) hydrate by a swapping mechanism. The overall process serves a dual purpose: it is a means of sustainable energy-source exploitation and greenhouse-gas sequestration. In particular, scant attention has been paid to the natural sediment clay portion in deep-sea gas hydrates, which is capable of storing a tremendous amount of NGH. The clay interlayer provides a unique chemical-physical environment for gas hydrates. Herein, for the first time, we pull out methane from intercalated methane hydrates in a clay interlayer using CO(2) and a CO(2)/N(2) gas mixture. The results of this study are expected to provide an essential physicochemical background required for large-scale NGH production under the seabed.

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Water-Soluble Structure H Clathrate Hydrate Formers

et al. 2011

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Hexamethyleneimine, 1-methylpiperidine, 2-methylpiperidine, 3-methylpiperidine, and 4-methylpiperidine as isomers of C6H13N were revealed as new sH clathrate hydrate forming molecules. They show fully soluble characteristics to water, whereas already known sH formers such as methylcyclohexane and 2,2-dimethylbutane (neohexane) are immiscible or very slightly soluble to water. The L–H–V equilibrium P–T behavior of these new sH clathrate hydrates shows a tendency to shift to much milder conditions than already known ones. We particularly note that 1-methylpiperidine appears to be the best for promotion. To verify the distribution of CH4 molecules and crystal structure of clathrate hydrates, 600 MHz solid-state NMR, Raman spectroscopy, and XRD pattern analysis were conducted. These noticeable properties of new formers are expected to open new research fields to the hydrate community and contribute to hydrate-based technological applications with high energy efficiency.

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Dong‐Yeun Koh

Reverse osmosis molecular differentiation of organic liquids using carbon molecular sieve membranes

Mechanism and Kinetics of Oxidation Reaction of Aqueous Ti₃C₂T_x Suspensions at Different pHs and Temperatures

Energy-efficient natural gas hydrate production using gas exchange

Recovery of Methane from Gas Hydrates Intercalated within Natural Sediments Using CO₂ and a CO₂/N₂ Gas Mixture

Water-Soluble Structure H Clathrate Hydrate Formers

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About

Dong‐Yeun Koh

Reverse osmosis molecular differentiation of organic liquids using carbon molecular sieve membranes

Mechanism and Kinetics of Oxidation Reaction of Aqueous Ti3C2Tx Suspensions at Different pHs and Temperatures

Energy-efficient natural gas hydrate production using gas exchange

Recovery of Methane from Gas Hydrates Intercalated within Natural Sediments Using CO2 and a CO2/N2 Gas Mixture

Water-Soluble Structure H Clathrate Hydrate Formers

Contact Info

Product

Resources

About

Mechanism and Kinetics of Oxidation Reaction of Aqueous Ti₃C₂T_x Suspensions at Different pHs and Temperatures

Recovery of Methane from Gas Hydrates Intercalated within Natural Sediments Using CO₂ and a CO₂/N₂ Gas Mixture