Hierarchical flower-like ternary composite of NiFeCr/PCN/CeO2 towards efficient photocatalytic reduction of CO2

Searching for semiconductor heterostructures with efficient photocatalytic activity and selectivity towards CO2 reduction is highly desired to lessen the speedy depletion of energy resources. Herein, a hierarchical flower-like ternary layered double hydroxides (LDHs) of NiFeCr-LDH-(PCN/CeO2-15%) was fabricated via in situ intro-duction of polymeric carbon nitride/cerium oxide (PCN/CeO2) and applied for photocatalytic CO2 reduction. The hierarchical flower-like heterostructure makes available more exposed surface-active sites to substantially enhance the light-harvesting capability. The charge transfer among the individual components stimulates the separation of photogenerated charge carriers and reduces their recombination rate, thus promoting the photo -catalytic conversion towards CO2 reduction. The as-prepared NiFeCr-LDH-(PCN/CeO2-15%) heterostructure exhibits an exceptional photocatalytic CO formation rate of 52.1 mu mol g-1 h-1, which is 7.1, 2.9, and 4.6 times than that of pristine PCN, PCN/CeO2, and pure NiFeCr-LDH, respectively. The magnificent photocatalytic ac-tivities are verified by the XPS and HRTEM evaluations, which demonstrate strong electronic interactions amongst heterostructure components. The present work not only achieves enhanced photocatalytic performance of NiFeCr-LDH-(PCN/CeO2-15%) heterostructure but also could provide a new approach to explore different LDHs-based semiconductors towards efficient CO2 reduction.

Automated summary

Hierarchical flower-like NiFeCr-LDH-(PCN/CeO2-15%) structure shows enhanced photocatalytic CO2 reduction efficiency due to increased light-harvesting capability and improved charge transfer. The exceptional CO formation rate highlights the potential of LDHs-based semiconductors for efficient CO2 reduction.