In situ study of low-temperature dry reforming of methane over La2Ce2O7 and LaNiO3 mixed oxides

Dry reforming of methane (DRM) is a promising process to generate synthetic gas with a low H-2/CO ratio. The main issues in DRM are the deposition of carbon over the catalyst and active metal sintering. Pyrochlores and perovskites are stable materials with properties that can overcome these challenges due to the presence of well dispersed active metal and oxygen vacancies. La2Ce2O7 and LaNiO3 mixed oxides containing 5 wt% of nickel were synthesized by modified Pechini and hydrothermal methods. The reduction of the La2Ce2O7 and LaNiO3 mixed materials was followed by in situ X-ray diffraction, ambient pressure X-ray photoelectron spectroscopy (APXPS), and X-ray absorption near edge structure. An oxygen-deficient perovskite La2Ni2O5 was identified already at room temperature. Both catalysts were stable during the performance test at low-(600 degrees C) and high-(850 degrees C) temperature DRM reaction, thanks to a negligible carbon accumulation on the catalyst surface. The high amount of electrophilic oxygen species, oxygen vacancies and basic sites detected correlates with the high catalytic activity. The material synthesized by hydrothermal method showed the highest conversion and yield. The better performance in this catalyst was related to higher amount of intermediate basic sites, oxygen vacancies and greater interaction between nickel and cerium. The reaction mechanism proposed in these materials takes into account the intermediates CHx and adsorbed O/OH, which were observed by means of APXPS.

Automated summary

Dry reforming of methane (DRM) is a promising process for generating synthetic gas with a low H-2/CO ratio. The main challenges in DRM, carbon deposition and active metal sintering, can be overcome by using stable materials like pyrochlores and perovskites. By synthesizing La2Ce2O7 and LaNiO3 mixed oxides using modified Pechini and hydrothermal methods, this study demonstrated their stability and high catalytic activity during low-temperature and high-temperature DRM reactions. The catalyst synthesized through the hydrothermal method showed the best performance, attributed to its abundant basic sites, oxygen vacancies, and strong interaction between nickel and cerium.