Stabilizing Ni catalysts in biogas reforming via in situ carbon deposit removal by CeO2 oxygen vacancies†
Abstract
Ni-based catalysts face significant challenges of carbon deposition during biogas reforming to syngas. Herein, we propose leveraging the in situ consumption of carbon deposits generated during biogas reforming through oxygen vacancies (Ov) on the surface of CeO2, ensuring enhanced activity and stability of the Ni3Fe/CeO2-rod structure catalyst. The catalyst exhibits an initial CH4 conversion of 80.4% and a CO2 conversion of 97.2%, with a mere 3.9% decline in CO2 conversion after 720 min.