Introducing Cu2O (111) phase on Cu(OH)2 nanorods integrated Pd-cocatalyst for boosting acetone selectivity via photoelectrochemical CO2RR

Photoelectrochemical CO2 reduction reaction (PEC-CO2RR) into multicarbon (C-2 and C-3) products is one of the most favorable paths for converting and utilizing atmospheric CO2. Although Cu-based photocathodes have unique features that can convert CO2 into value-added products, they have limited selectivity. In this study, we established the Cu-based heterostructure by introducing the Cu2O (111) phase on the surface of Cu/Cu(OH)(2) nanorods array (CNA) while integrating Pd cocatalyst to improve the selectivity of the C-3 products via PEC-CO2RR. The acetone is recognized as a major C-3 product with a Faradaic efficiency of similar to 40 % and a production rate of 323.3 mu g/h at a negative applied potential of -0.6 V-RHE. The high selectivity of the CNA/Cu2O/Pd2 photocathode is achieved owing to the superior electrochemical active area of 132 mu F/cm(2), electrochemical double layer capacitance of 5.28 mF/cm(2), and high charge transfer at the electrode/electrolyte interface. Notably, the Pd co-catalyst facilitates supplying an adequate level of & lowast;CO intermediate at the Cu2O (111) active sites to enable the C-C coupling leading to the formation of multicarbon products with 77% stability retention. During PEC-CO2RR, the formation of critical intermediates such as & lowast;CO and & lowast;COCH3 are responsible for acetone's selectivity through the hydroxyacetone pathway. Thus, the optimized heterostructure design of the CNA/Cu2O/Pd photocathodes holding Pd cocatalyst along with the Cu2O (111) phase is suitable for improving the selectivity of C-3 products via PEC-CO2RR.