The suitable interfacial combination of CeO2 and oxidized carbon nanohorns (CeO2@oxCNHs) is instrumental to the control of the activity and selectivity in CO2 reduction reaction (CO2RR). This study presents a newly developed synthetic approach that integrates the CeO2 and CNH to form extended interfacial domains, resulting in a higher performance for CO2RR as compared with previously reported ceria-nanocarbon catalysts. In particular, detailed electrochemical characterization reveals that the CeO2@oxCNHs nanocomposite synthesized with this newly developed solvothermal method exhibits up to ten times higher current density (j) than its counterpart prepared by conventional sol-gel method and can be effectively integrated into a state-of-the-art gas diffusion electrode (GDE) device. The combination of high-surface area oxCNH with the gas diffusion electrode configuration boosts the CeO2 efficiency in converting CO2 to products involving C─C couplings as ethanol and acetaldehyde, even at very low overpotentials, offering a promising pathway for developing nanocomposite materials for CO2 reduction.
Pollice, A., Cacioppo, M., Marchi, M., Moro, M., Paolucci, F., Bonchio, M., et al. (2025). Exploiting the Functionality of Cerium Oxide‐Modified Carbon Nanohorns Catalysts Toward Enhanced CO2 Reduction Performance. ADVANCED FUNCTIONAL MATERIALS, e09299, 1-8 [10.1002/adfm.202509299].
Exploiting the Functionality of Cerium Oxide‐Modified Carbon Nanohorns Catalysts Toward Enhanced CO2 Reduction Performance
Pollice, Alessia;Moro, Miriam;Paolucci, Francesco;Valenti, Giovanni;
2025
Abstract
The suitable interfacial combination of CeO2 and oxidized carbon nanohorns (CeO2@oxCNHs) is instrumental to the control of the activity and selectivity in CO2 reduction reaction (CO2RR). This study presents a newly developed synthetic approach that integrates the CeO2 and CNH to form extended interfacial domains, resulting in a higher performance for CO2RR as compared with previously reported ceria-nanocarbon catalysts. In particular, detailed electrochemical characterization reveals that the CeO2@oxCNHs nanocomposite synthesized with this newly developed solvothermal method exhibits up to ten times higher current density (j) than its counterpart prepared by conventional sol-gel method and can be effectively integrated into a state-of-the-art gas diffusion electrode (GDE) device. The combination of high-surface area oxCNH with the gas diffusion electrode configuration boosts the CeO2 efficiency in converting CO2 to products involving C─C couplings as ethanol and acetaldehyde, even at very low overpotentials, offering a promising pathway for developing nanocomposite materials for CO2 reduction.I documenti in IRIS sono protetti da copyright e tutti i diritti sono riservati, salvo diversa indicazione.
