Research progress on electrochemical CO2 reduction for Cu-based single-atom catalysts

“…11–13 Experimental evidence has demonstrated their high activity and selectivity for C 1 products, 14,15 but their performance in generating higher value C 2+ products is unsatisfactory. 16,17 This is attributed to the multi-step, complex electron–proton coupling processes and the crucial C–C coupling steps required for the C 2+ products, whereby either slow kinetic steps can impact the overall catalytic efficiency. 18,19 Moreover, metal single-atom catalysts may lack a sufficient number of adjacent active sites to provide a suitable C–C coupling platform, thus lacking an advantage in generating C 2+ products.…”

Mechanistic insights into high-throughput screening of tandem catalysts for CO₂ reduction to multi-carbon products

“…11–13 Experimental evidence has demonstrated their high activity and selectivity for C 1 products, 14,15 but their performance in generating higher value C 2+ products is unsatisfactory. 16,17 This is attributed to the multi-step, complex electron–proton coupling processes and the crucial C–C coupling steps required for the C 2+ products, whereby either slow kinetic steps can impact the overall catalytic efficiency. 18,19 Moreover, metal single-atom catalysts may lack a sufficient number of adjacent active sites to provide a suitable C–C coupling platform, thus lacking an advantage in generating C 2+ products.…”

Mechanistic insights into high-throughput screening of tandem catalysts for CO₂ reduction to multi-carbon products

Atomically Dispersed Metal Catalysts for the Conversion of CO₂ into High‐Value C₂₊ Chemicals

A Stable Copper-based Metal-Azolate Framework for Efficient Electroreduction of CO2 to C2+ Products