Richard I. Masel scite author profile

Electroreduction of carbon dioxide (CO(2))--a key component of artificial photosynthesis--has largely been stymied by the impractically high overpotentials necessary to drive the process. We report an electrocatalytic system that reduces CO(2) to carbon monoxide (CO) at overpotentials below 0.2 volt. The system relies on an ionic liquid electrolyte to lower the energy of the (CO(2))(-) intermediate, most likely by complexation, and thereby lower the initial reduction barrier. The silver cathode then catalyzes formation of the final products. Formation of gaseous CO is first observed at an applied voltage of 1.5 volts, just slightly above the minimum (i.e., equilibrium) voltage of 1.33 volts. The system continued producing CO for at least 7 hours at Faradaic efficiencies greater than 96%.

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Direct formic acid fuel cells

Rice

Masel

et al. 2002

Journal of Power Sources

820

531

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The effect of electrolyte composition on the electroreduction of CO₂to CO on Ag based gas diffusion electrodes

Verma

et al. 2016

Phys. Chem. Chem. Phys.

422

429

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The electroreduction of CO2 to C1-C2 chemicals can be a potential strategy for utilizing CO2 as a carbon feedstock. In this work, we investigate the effect of electrolytes on the electroreduction of CO2 to CO on Ag based gas diffusion electrodes. Electrolyte concentration was found to play a major role in the process for the electrolytes (KOH, KCl, and KHCO3) studied here. Several fold improvements in partial current densities of CO (jCO) were observed on moving from 0.5 M to 3.0 M electrolyte solution independent of the nature of the anion. jCO values as high as 440 mA cm(-2) with an energy efficiency (EE) of ≈ 42% and 230 mA cm(-2) with EE ≈ 54% were observed when using 3.0 M KOH. Electrochemical impedance spectroscopy showed that both the charge transfer resistance (Rct) and the cell resistance (Rcell) decreased on moving from a 0.5 M to a 3.0 M KOH electrolyte. Anions were found to play an important role with respect to reducing the onset potential of CO in the order OH(-) (-0.13 V vs. RHE) < HCO3(-) (-0.46 V vs. RHE) < Cl(-) (-0.60 V vs. RHE). A decrease in Rct upon increasing electrolyte concentration and the effect of anions on the cathode can be explained by an interplay of different interactions in the electrical double layer that can either stabilize or destabilize the rate limiting CO2˙(-) radical. EMIM based ionic liquids and 1 : 2 choline Cl urea based deep eutectic solvents (DESs) have been used for CO2 capture but exhibit low conductivity. Here, we investigate if the addition of KCl to such solutions can improve conductivity and hence jCO. Electrolytes containing KCl in combination with EMIM Cl, choline Cl, or DESs showed a two to three fold improvement in jCO in comparison to those without KCl. Using such mixtures can be a strategy for integrating the process of CO2 capture with CO2 conversion.

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Sustainion Imidazolium‐Functionalized Polymers for Carbon Dioxide Electrolysis

et al. 2017

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CO2 electrolysis is a key step in CO2 conversion into fuels and chemicals as a way of mitigating climate change. We report the synthesis and testing of a series of new anion‐conductive membranes (tradenamed Sustainion™) for use in CO2 electrolysis. These membranes incorporate the functional character of imidazolium‐based ionic liquids as co‐catalysts in CO2 reduction into a solid membrane with a styrene backbone. We find that the addition of an imidazolium group onto the styrene side‐chains increases the selectivity of the reaction from approximately 25 % to approximately 95 %. The current at 3 V is increased by a factor of 14. So far we have been able to tune these parameters to achieve stable cells that provide current densities higher than 100 mA cm−2 at 3 V cell potential with a CO product selectivity over 98 %. Stable performance was observed for 6 months of continuous operation (>150 000 000 turnovers). These results demonstrate that imidazolium polymers are ideal membranes for CO2 electrolysis.

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Rapid Production of Metal−Organic Frameworks via Microwave-Assisted Solvothermal Synthesis

2006

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This paper describes a very rapid technique for the production of metal-organic frameworks (MOF). The method uses a conventional microwave to nucleate crystal growth. A MOF synthesis that used to take hours or days can now be completed in 30 s to 2 min. The yield goes from approximately 30% to over 90%. Novel MOFs can be made, since the growth process is no longer dependent on the walls or dust particles for nucleation. Particle sizes have a narrower distribution. Further, the particle size can be controlled by varying the precursor concentration.

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Richard I. Masel

Ionic Liquid–Mediated Selective Conversion of CO ₂ to CO at Low Overpotentials

Direct formic acid fuel cells

The effect of electrolyte composition on the electroreduction of CO₂to CO on Ag based gas diffusion electrodes

Sustainion Imidazolium‐Functionalized Polymers for Carbon Dioxide Electrolysis

Rapid Production of Metal−Organic Frameworks via Microwave-Assisted Solvothermal Synthesis

Contact Info

Product

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About

Richard I. Masel

Ionic Liquid–Mediated Selective Conversion of CO 2 to CO at Low Overpotentials

Direct formic acid fuel cells

The effect of electrolyte composition on the electroreduction of CO2to CO on Ag based gas diffusion electrodes

Sustainion Imidazolium‐Functionalized Polymers for Carbon Dioxide Electrolysis

Rapid Production of Metal−Organic Frameworks via Microwave-Assisted Solvothermal Synthesis

Contact Info

Product

Resources

About

Ionic Liquid–Mediated Selective Conversion of CO ₂ to CO at Low Overpotentials

The effect of electrolyte composition on the electroreduction of CO₂to CO on Ag based gas diffusion electrodes