Utilization of laterite ore as an oxygen carrier in chemical looping reforming of methane for syngas production.

Growing energy demands in various sectors have resulted in overusing fossil fuel sources and rise in greenhouse gases in the atmosphere. This necessitates the need for reducing greenhouse gases and shifting to cleaner, renewable energy sources like H 2. Chemical looping is one such renewable method to produce clean H 2. The efficiency of this process depends on the oxygen carrier. Generally, oxygen carriers (OC) are transition metal oxides (Fe 2 O 3 or NiO) or some complex metal oxides like spinel or perovskites, but usage of these OCs are restricted due to their availability and redox performance. One solution for selecting OCs can be using industrial waste like slag or low-grade ores because of their composition, which consists of metal oxides. One such low-grade ore is Ni-laterite ore or chromite overburden, a mining waste found in the chromite mines of Sukinda (India). In this work, we have focused on utilizing this laterite ore as an OC for the chemical looping reforming of methane to produce syngas. The reactivity analysis of laterite ore with CH 4 was performed in DSC-TG and the reaction products were analyzed in gas chromatography along with microscopy and spectroscopic techniques. Results showed the formation of H 2 and CO gases along with reduced metallic phases. The total H 2 yield at 750 °C is determined to 53.67 (±1.09) ml/g of OC which is comparable or even higher than existing CeO 2 based OCs. Further, thermodynamic calculations are presented to calculate the theoretical yield for our process and compared with the experimental H 2 yield. This study effectively demonstrates the performance of laterite ore as an OC for generating clean and renewable energy through chemical looping technique. [Display omitted] • Utilization of laterite ore as an oxygen carrier and reactivity study in TGA of laterite ore in presence of methane. • Theoretical study of reaction with CH 4 and predicting the reaction products of laterite ore reaction with methane. • Comparison of hydrogen yield obtained in experiments (53.67 ± 1.09 ml/g of OC) and theoretical calculation (61.96 ml/g of OC). [ABSTRACT FROM AUTHOR]