Experimental investigation of electrochemical carbon dioxide reduction reaction for C1 products with diatomic copper manganese electrocatalyst
Using copper as a homonuclear single-atom catalyst, or SAC, as a cathode in an electrochemical cell, increases the selectivity and faradaic efficiency. However, it does not produce enough CO2 reduction reaction activity, or CO2 RR. A higher activity of CO2RR means higher amount of CO2 gas used in th...
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2023
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sg-ntu-dr.10356-1666302023-05-13T16:45:42Z Experimental investigation of electrochemical carbon dioxide reduction reaction for C1 products with diatomic copper manganese electrocatalyst Hee, Zachary An Alex Yan Qingyu School of Materials Science and Engineering AlexYan@ntu.edu.sg Engineering::Materials Using copper as a homonuclear single-atom catalyst, or SAC, as a cathode in an electrochemical cell, increases the selectivity and faradaic efficiency. However, it does not produce enough CO2 reduction reaction activity, or CO2 RR. A higher activity of CO2RR means higher amount of CO2 gas used in the reaction to produce chemical products such as formic acid. Substituting a homonuclear SAC with a hetero-diatomic catalyst, it produces unique catalytic properties like higher faradaic efficiency and performance. Adding manganese with copper as a hetero-diatomic catalyst, manganese can suppress the water reduction reaction for more CO2 reduction activity to occur. Gas chromatography, or GC, will be used to evaluate the gas products, and nuclear magnetic resonance spectroscopy, or NMR Spectroscopy, will be used to test the liquid products. Each catalyst will be applied with a different potential for a specific duration. With the lab test results, it will reveal that heteronuclear copper-manganese-nitrogen-carbon (Cu-Mn-N-C) catalyst is the best at producing higher activity and products’ selectivity among nitrogen-carbon (N-C), copper-nitrogen-carbon (Cu-N-C), and manganese-nitrogen-carbon (Mn-N-C) catalyst samples. Producing the highest carbon monoxide (CO) partial current density at 33.68 mA cm-2 at -0.875 VRHE, with an average of 20.63 mA cm-2 over a range of -0.475 to -1.175 VRHE. The SEM images which have shown no difference in geometry structure can be proven that it is not a mechanism behind the hetero-diatomic Cu-Mn-N-C’s high performance when compared to the other SAC samples. Bachelor of Engineering (Materials Engineering) 2023-05-08T04:05:56Z 2023-05-08T04:05:56Z 2023 Final Year Project (FYP) Hee, Z. A. (2023). Experimental investigation of electrochemical carbon dioxide reduction reaction for C1 products with diatomic copper manganese electrocatalyst. Final Year Project (FYP), Nanyang Technological University, Singapore. https://hdl.handle.net/10356/166630 https://hdl.handle.net/10356/166630 en application/pdf Nanyang Technological University |
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Engineering::Materials Hee, Zachary An Experimental investigation of electrochemical carbon dioxide reduction reaction for C1 products with diatomic copper manganese electrocatalyst |
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Using copper as a homonuclear single-atom catalyst, or SAC, as a cathode in an electrochemical cell, increases the selectivity and faradaic efficiency. However, it does not produce enough CO2 reduction reaction activity, or CO2 RR. A higher activity of CO2RR means higher amount of CO2 gas used in the reaction to produce chemical products such as formic acid. Substituting a homonuclear SAC with a hetero-diatomic catalyst, it produces unique catalytic properties like higher faradaic efficiency and performance. Adding manganese with copper as a hetero-diatomic catalyst, manganese can suppress the water reduction reaction for more CO2 reduction activity to occur.
Gas chromatography, or GC, will be used to evaluate the gas products, and nuclear magnetic resonance spectroscopy, or NMR Spectroscopy, will be used to test the liquid products. Each catalyst will be applied with a different potential for a specific duration.
With the lab test results, it will reveal that heteronuclear copper-manganese-nitrogen-carbon (Cu-Mn-N-C) catalyst is the best at producing higher activity and products’ selectivity among nitrogen-carbon (N-C), copper-nitrogen-carbon (Cu-N-C), and manganese-nitrogen-carbon (Mn-N-C) catalyst samples. Producing the highest carbon monoxide (CO) partial current density at 33.68 mA cm-2 at -0.875 VRHE, with an average of 20.63 mA cm-2 over a range of -0.475 to -1.175 VRHE. The SEM images which have shown no difference in geometry structure can be proven that it is not a mechanism behind the hetero-diatomic Cu-Mn-N-C’s high performance when compared to the other SAC samples. |
| author2 |
Alex Yan Qingyu |
| author_facet |
Alex Yan Qingyu Hee, Zachary An |
| format |
Final Year Project |
| author |
Hee, Zachary An |
| author_sort |
Hee, Zachary An |
| title |
Experimental investigation of electrochemical carbon dioxide reduction reaction for C1 products with diatomic copper manganese electrocatalyst |
| title_short |
Experimental investigation of electrochemical carbon dioxide reduction reaction for C1 products with diatomic copper manganese electrocatalyst |
| title_full |
Experimental investigation of electrochemical carbon dioxide reduction reaction for C1 products with diatomic copper manganese electrocatalyst |
| title_fullStr |
Experimental investigation of electrochemical carbon dioxide reduction reaction for C1 products with diatomic copper manganese electrocatalyst |
| title_full_unstemmed |
Experimental investigation of electrochemical carbon dioxide reduction reaction for C1 products with diatomic copper manganese electrocatalyst |
| title_sort |
experimental investigation of electrochemical carbon dioxide reduction reaction for c1 products with diatomic copper manganese electrocatalyst |
| publisher |
Nanyang Technological University |
| publishDate |
2023 |
| url |
https://hdl.handle.net/10356/166630 |
| _version_ |
1770565548551176192 |