Effect of Ni-Co addition on Pd promoted Al₂O₃ catalysts for dry reforming of methane

This study investigates the effectiveness of x Ni – (5 – x) Co / 5 Pd – Al₂O₃ (where x=0, 1.25, 2.5, 3.75, and 5) bimetallic catalysts and the influence of the Pd on their activity in the dry reforming of methane. Comprehensive characterization techniques including XRD, TPR, TPD, SEM, TGA, and Raman analysis are employed to examine the catalysts. XRD analysis of the calcined catalysts reveals the presence of multiple oxides such as NiO, CoO, Co₃O₄, and PdO. The metal-support interaction and the particle sintering of the catalysts depend on the amount of Co loading, for higher Co loadings (> 2.5 wt%) resulted in weakened metal-support interaction as indicated by TPR analysis. Also, the particle sintering was observed with an increase in Co loading observed from SEM and TEM analysis. The activity analysis demonstrates that the 5 Ni / 5 Pd – Al₂O₃ catalysts exhibit superior performance in terms of both CH₄ (59%) and CO₂ (64%) conversions, as well as stability, compared to the Ni-Co bimetallic catalyst. The addition of Co leads to decreased activity, Furthermore, TGA analysis indicates minimal carbon deposition on the 5 Ni / 5 Pd – Al₂O₃ catalyst during the 7-hour activity study. Notably, Raman analysis reveals a lower presence of graphitic carbon on the catalyst, which contributes to its stable catalytic activity. The presence of Pd in the 5 Ni catalyst reduces carbon deposition and enhances its activity. However, in the case of the Ni-Co bimetallic catalyst, the promotional effect of Pd appears to be negligible. Overall, these findings emphasize the promising potential of the 5 Ni / 5 Pd – Al₂O₃ catalyst for efficient and stable dry reforming of methane.