Energy-efficient biogas reforming process to produce syngas: the enhanced methane conversion by O₂

We report an energy-efficient biogas reforming process with high and stable methane conversions by O₂ presence. During this biogas reforming process, the effects of various O₂ concentrations in biogas on initial conversions and stability at various temperatures on a Ni/SiO₂ catalyst were detailed investigated. In addition, theoretical energy consumption and conversions were calculated based on the Gibbs energy minimization method to compare with experimental results. Carbon formation and sintering during the reforming process were characterized by thermal gravity analysis, the Brunauer-Emmett-Teller method, X-ray diffraction, and high-resolution transmission electron microscopy to investigate the feasibility of applying this process to an inexpensive nickel catalyst. The results showed that 5% O₂ in biogas improved the CH₄ conversion and stability of biogas reforming. The enhancement of stability was attributed to the inhibited sintering, our first finding, and the reduced carbon deposition at the same time, which sustained a stable conversion of CH₄, and proved the applicability of base Ni catalyst to this process. Higher O₂ concentrations (⩾10%) in biogas resulted in severe decrease in CO₂ conversion and greater H₂O productivity. Our proposed biogas reforming process, with a high and stable conversion of CH₄, reduced energy input, and the applicability to inexpensive base metal catalyst, offers a good choice for biogas reforming with low O₂ concentrations (⩽5%) to produce syngas with high energy efficiency.