Enhanced electrochemical conversion of CO2 into formic acid using PbSO4/AtSn electrode: Catalyst synthesis and process optimization
Author | Muhammad, Arsalan |
Author | Ewis, Dina |
Author | Mahmud, Nafis |
Author | Ba-Abbad, Muneer M. |
Author | Khaled, Mazen |
Author | El-Naas, Muftah H. |
Available date | 2024-03-20T07:54:44Z |
Publication Date | 2023-11-02 |
Publication Name | Journal of Environmental Chemical Engineering |
Identifier | http://dx.doi.org/10.1016/j.jece.2023.111352 |
Citation | Arsalan, M., Ewis, D., Mahmud, N., Ba-Abbad, M. M., Khaled, M., & El-Naas, M. H. (2023). Enhanced electrochemical conversion of CO2 into formic acid using PbSO4/AtSn electrode: Catalyst synthesis and process optimization. Journal of Environmental Chemical Engineering, 11(6), 111352. |
ISSN | 2213-2929 |
Abstract | Electrochemical carbon dioxide (CO2) reduction is among the most promising and effective methods for producing valuable fuels while simultaneously addressing global warming. Numerous metal-based materials showed promising potential for CO2 conversion due to their distinct physical, mechanical, and electrical capabilities. However, there is often a continuous challenge to fabricating stable electrode systems with high Faradaic efficiency %. In this study, an electrochemical catalyst consisting of lead sulphate was synthesized, deposited on acid treated tin foil (PbSO4/AtSn) and tested for the CO2 ECR. The prepared Pb-based catalyst demonstrated a high faradaic efficiency of 79.8% at − 26 mA in a 0.11 M CO2-saturated NaHCO3 aqueous solution, which was significantly higher than both the acid treated and untreated blank Sn foil. The catalyst also exhibited lower energy consumption (0.0695 kWh.mol−1) compared to the most commonly used formic acid-producing electrocatalyst. At a constant current of − 26 mA, the catalyst continued to function after 20 h of continuous CO2 electrochemical reduction. Experimental design was used to optimize the fabricated catalyst performance at different operating conditions. Optimum performance was obtained at − 26 mA current, 0.11 M electrolyte concentration, and 1.42 mg of catalyst to obtain the highest faradic efficiency. According to the experimental findings, the Pb-based catalyst's superior catalytic performance could be attributed to its larger electrochemical active surface area and reduced charge-transfer resistance. These promising results suggest that the prepared Pb-based catalyst can be highly effective for electrochemical reduction of CO2 with promising potential for commercialization. |
Sponsor | This work was funded by Qatar National Research Fund (a member of Qatar Foundation) through Grant # NPRP 12C-33923-SP-102 (NPRP12 C-0821-190017). Open Access funding is provided by the Qatar National Library. |
Language | en |
Publisher | Elsevier |
Subject | Electrochemical conversion Lead catalyst CO2 Reduction Formic acid |
Type | Article |
Issue Number | 6 |
Volume Number | 11 |
ESSN | 2213-3437 |
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