Jackson Crane scite author profile

Electrochemical carbon dioxide (CO2) conversion to hydrocarbon fuels, such as methane (CH4), offers a promising solution for the long-term and large-scale storage of renewable electricity. To enable this technology, CO2-to-CH4 conversion must achieve high selectivity and energy efficiency at high currents. Here, we report an electrochemical conversion system that features proton-bicarbonate-CO2 mass transport management coupled with an in-situ copper (Cu) activation strategy to achieve high CH4 selectivity at high currents. We find that open matrix Cu electrodes sustain sufficient local CO2 concentration by combining both dissolved CO2 and in-situ generated CO2 from the bicarbonate. In-situ Cu activation through alternating current operation renders and maintains the catalyst highly selective towards CH4. The combination of these strategies leads to CH4 Faradaic efficiencies of over 70% in a wide current density range (100 – 750 mA cm-2) that is stable for at least 12 h at a current density of 500 mA cm-2. The system also delivers a CH4 concentration of 23.5% in the gas product stream.

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Isolating the effect of induction length on detonation structure: Hydrogen–oxygen detonation promoted by ozone

Crane

Shi

Singh

et al. 2019

Combustion and Flame

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Three-dimensional detonation structure and its response to confinement

Crane

Lipkowicz

Shi

et al. 2023

Proceedings of the Combustion Institute

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Geometric modeling and analysis of detonation cellular stability

Crane

Shi

Lipkowicz

et al. 2021

Proceedings of the Combustion Institute

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Jackson Crane

High-rate and selective conversion of CO2 from aqueous solutions to hydrocarbons

Isolating the effect of induction length on detonation structure: Hydrogen–oxygen detonation promoted by ozone

Three-dimensional detonation structure and its response to confinement

Geometric modeling and analysis of detonation cellular stability

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