Gas-phase electrocatalytic conversion of CO2 to chemicals on sputtered Cu and Cu–C catalysts electrodes

“…Although the proportion of acetone in all products has been increased, acetaldehyde is still the main product with a FE of ~8 %. The yield of acetaldehyde leaps to 70 nmol•cm -2 •h -1 , which is higher than those reported in literatures as shown in Table S2 [18][19][20] , indicating the promoted activities for both C 2 and C 3 products with few deposited SnO 2 nanoparticles on Cu HF electrode surface (0.1 wt.%).…”

“…Acetaldehyde is the main reduction product at all conditions, which is in agreement with previous studies of gasphase CO 2 electroreduction. [18][19][20] At the potential of -1.4 V vs CE, the total FE for all products is about 10 %, while ~25 nmol•cm -2 •h -1 acetaldehyde is formed with a FE of around 6 %. •h -1 with a catalyst loading of 0.5 mg•cm -2 ) at a higher temperature and penitential (90 o C, -2.75 V, -1.6 mA•cm -2 ), the FE of acetaldehyde is only 1 %.…”

“…Acetaldehyde could be observed as one of the main products for all electrodes with several other C 1~C3 products, while no H 2 from competitive H 2 evolution reaction could be detected in examined conditions, which is consistent with the results of former gas-phase CO 2 electroreduction studies. [16][17][18][19][20] The gasphase electrocatalytic reduction of CO 2 is a complex multistep reaction involving shared intermediates and multiple reaction pathways. 19,20 The formation of the different products can be described by a general reaction as shown in Scheme 1 for the cathodic reaction of CO 2 and H + with e -.…”

“…17 Recent studies from Gutiérrez-Guerra et al used polybenzimidazoles (PBI) and Sterion® as the solid electrolyte for gas-phase CO 2 electroreduction at 90 o C, obtaining methanol and acetaldehyde with yields of 40 and 110 µmol•g cat -1 •h -1 over Cu catalysts. [18][19][20] However, these works are all based on conventional types of Cu-based electrodes, with unsatisfying overall efficiencies and insufficient value-added multicarbon products for the electroreduction of gas-phase CO 2 .…”

Gas-phase CO₂ electroreduction over Sn–Cu hollow fibers

“…Although the proportion of acetone in all products has been increased, acetaldehyde is still the main product with a FE of ~8 %. The yield of acetaldehyde leaps to 70 nmol•cm -2 •h -1 , which is higher than those reported in literatures as shown in Table S2 [18][19][20] , indicating the promoted activities for both C 2 and C 3 products with few deposited SnO 2 nanoparticles on Cu HF electrode surface (0.1 wt.%).…”

“…Acetaldehyde is the main reduction product at all conditions, which is in agreement with previous studies of gasphase CO 2 electroreduction. [18][19][20] At the potential of -1.4 V vs CE, the total FE for all products is about 10 %, while ~25 nmol•cm -2 •h -1 acetaldehyde is formed with a FE of around 6 %. •h -1 with a catalyst loading of 0.5 mg•cm -2 ) at a higher temperature and penitential (90 o C, -2.75 V, -1.6 mA•cm -2 ), the FE of acetaldehyde is only 1 %.…”

“…Acetaldehyde could be observed as one of the main products for all electrodes with several other C 1~C3 products, while no H 2 from competitive H 2 evolution reaction could be detected in examined conditions, which is consistent with the results of former gas-phase CO 2 electroreduction studies. [16][17][18][19][20] The gasphase electrocatalytic reduction of CO 2 is a complex multistep reaction involving shared intermediates and multiple reaction pathways. 19,20 The formation of the different products can be described by a general reaction as shown in Scheme 1 for the cathodic reaction of CO 2 and H + with e -.…”

“…17 Recent studies from Gutiérrez-Guerra et al used polybenzimidazoles (PBI) and Sterion® as the solid electrolyte for gas-phase CO 2 electroreduction at 90 o C, obtaining methanol and acetaldehyde with yields of 40 and 110 µmol•g cat -1 •h -1 over Cu catalysts. [18][19][20] However, these works are all based on conventional types of Cu-based electrodes, with unsatisfying overall efficiencies and insufficient value-added multicarbon products for the electroreduction of gas-phase CO 2 .…”

Gas-phase CO₂ electroreduction over Sn–Cu hollow fibers

“…The increasing accumulation of carbon dioxides (CO 2 ) in atmosphere results in serious environmental issues, such as globe warming [1] . To address these issues, the electrochemical reduction of CO 2 into valuable chemicals and fuels is a highly promising route for the sustainable energy applications [2,3] .…”

Well-dispersed SnO2 nanocrystals on N-doped carbon nanowires as efficient electrocatalysts for carbon dioxide reduction

Recent Advances in Electrochemical CO₂‐to‐Multicarbon Conversion: From Fundamentals to Industrialization