Steady-state macroscale voltammetry in a supercritical carbon dioxide medium

The electrochemical oxidation and reduction of decamethylferrocene is demonstrated in supercritical carbon dioxide at a macro gold disc electrode at 100 bar and 313 K. Fast mass transport effects were exhibited and the corresponding steady-state voltammetry was observed at high scan rates. A highly lipophilic room temperature ionic liquid that readily dissolved in supercritical CO2 with acetonitrile as a co-solvent was used as an electrolyte, allowing for a conducting supercritical single phase. Experimental observations along with simulation results confirmed the hypothesis that a thin layer of liquid-like phase of co-solvent is formed at the electrode surface and is restricted by a more supercritical phase of high natural convection and bulk concentration.

Steady-state macroscale voltammetry in a supercritical carbon dioxide medium

Rate-Determining Step for Electrochemical Reduction of Carbon Dioxide into Carbon Monoxide at Silver Electrodes

Polydopamine-coated photoautotrophic bacteria for improving extracellular electron transfer in living photovoltaics

Monitoring and understanding Cu catalyst dissolution during CO2 electroreduction

Monitoring and understanding Cu catalyst dissolution during CO2 electroreduction

Rate-Determining Step for Electrochemical Reduction of Carbon Dioxide into Carbon Monoxide at Silver Electrodes

Polydopamine-coated photoautotrophic bacteria for improving extracellular electron transfer in living photovoltaics