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A recent study, affiliated with UNIST has unveiled a novel system, capable of producing hydrogen and electricity quickly and effectively while cutting carbon dioxide (CO2) emissions significantly.
Published in the January 2021 issue ofNano Energy, this breakthrough has been carried out by Professor GunTae Kim and his research team in the School of Energy and Chemical Engineering at UNIST. In this study, the research team succeeded in developing a membrane-free aqueous metal-CO2电池。与现有的aqueous metal-CO2systems, the new battery is not only easier to manufacture, but also allows continuous operation with one type of electrolyte.
The research team designed a membrane-free (MF) Mg-CO2battery, as an advanced approach to sequester CO2emissions by generating electricity and value-added chemicals without any harmful by-products. According to the research team, their MF Mg-CO2battery operates based on the indirect utilization of CO2with facile hydrogen generation process. It has been also found that the new battery exhibits high faradaic efficiency of 92.0%.
"In order to translate the newly-developed laboratory-scale MF Mg-CO2battery technology into a commercial reality, we have envisioned an operational prototype system that produces electricity and value-added chemicals, as a cornerstone to better support sustainable human life from CO2and earth-abundant renewable power (e.g., wind, solar, seawater)," noted the research team.
The MF Mg-CO2battery system has a structure similar to that of hydrogen fuel cells for use in cars, since it only requires a Mg-metal negative electrode, an aqueous electrolyte, and a positive-electrode catalyst. However, unlike the existing fuel cells, they are based on aqueous electrolytes. As a result, the newly-developed MF Mg-CO2battery had successfully sequestered CO2emissions by generating electricity and value-added chemicals without any harmful by-products.
"Our findings indicate great benefits for the newly-developed MF Mg-CO2battery technology to produce various value-added chemicals of practical significance and electricity from CO2without any wasted by-products," noted the research team. "Through this we have opened the door to electrochemical utilization of CO2with indirect circulation for future alternative technologies."
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Materialsprovided byUlsan National Institute of Science and Technology(UNIST). Original written by JooHyeon Heo.注意:内容可能被编辑风格d length.
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