Converting carbon dioxide (CO 2 ) from industrial point sources to chemicals and fuels utilizing renewable energy can help to tackle the climate crisis. CO 2 electrolysis is one promising route.
Previous studies were generally performed with pure or highly concentrated CO 2 feeds, while the CO 2 concentration in flue gas from the combustion of fossil fuels was very low, typically from 5% to 15%. The energy and capital costs associated with capturing and purifying CO 2 from flue gas point sources are very high. The direct utilization of industrial flue gas bypassing the capture and purification steps for producing pure CO 2 feeds is still challenging.
Recently, a research team led by Profs. WANG Guoxiong and GAO Dunfeng from the Dalian Institute of Chemical Physics (DICP) of the Chinese Academy of Sciences (CAS), in collaboration with Prof. AN Qingda from the Dalian Polytechnic University, have proposed a molecular enhancement strategy for direct electrolysis of dilute CO 2 to CO. This study was published in ACS Energy Letters .
To deal with the unfavorable mass transport, reaction thermodynamics, and kinetics of direct electrolysis of dilute CO 2 , the researchers constructed reaction microenvironment surrounding catalytically active sites by molecularly modifying CoPc electrodes with a poly(4-vinylpyridine) (P4VP) molecule. The formed reaction microenvironment effectively integrated the capture and conversion of CO 2 from dilute feed streams.
With a home-made alkaline membrane electrode assembly (MEA) electrolyzer, the researchers obtained a remarkable CO partial current density of 252 mA cm -2 with a CO Faradaic efficiency of 90% under the dilute feed with a typical CO 2 concentration (10%) in flue gas, which was 2.24-fold higher than that of bare CoPc electrode.
Physicochemical and electrochemical structural characterization results indicated that the abundant pyridine groups of the P4VP modifier improved sequentially the physical adsorption and chemical activation of CO 2 over Co sites of CoPc catalysts, resulting in the impressive performance for direct electrolysis of dilute CO 2 to CO.
This molecular enhancement strategy, with further precise control in catalyst structures and reaction microenvironments, will hold great promise for the direct electrolysis of industrial flue gas and the selective production of multicarbon chemicals such as ethylene.
ACS Energy Letters
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Molecular Enhancement of Direct Electrolysis of Dilute CO2
9-Feb-2024