Application of manganese-containing soil as novel catalyst for low-temperature NH3-SCR of NO

Manganese-containing soil (M-S) is a solid waste generated from the mining and extraction of manganese ore. In this study, the low-temperature denitration performance of Mn-S was investigated via XRF, XRD, XPS, H-2-TPR, NH3-TPD and DRIFTS, aiming at exploring its utilization approach as low-temperature NH3-SCR catalyst. The results showed that Mn-S exhibited a relatively high catalytic activity reaching over 75% NO conversion from 150 degrees C to 200 degrees C. The physical and chemical properties of Mn-S were studied, indicating that the manganese content of Mn-S reached 8.2% with mainly surface Mn atomic valence state of Mn3+. In situ DRIFTS results revealed the SCR reaction mechanism of Mn-S, suggesting that Mn-S obeyed the E-R reaction mechanism. The Ce/Mn-S catalyst was synthesized by impregnation method. The denitration activity improved and reached 92.4% at 200 degrees C. A series of characterizations were studied to investigate the strengthening mechanism after doping Ce. It's found that introducing of Ce could increase the content of Mn4+ and chemisorbed oxygen, NH3 adsorption capacity and reducibility. It was found from in situ DRIFTS experiments that doping of Ce changed the reaction mechanism due to the conversion of inactive substance, which was mainly affected by E-R and L-H.

Automated summary

Manganese-containing soil was studied as a low-temperature NH3-SCR catalyst, showing high catalytic activity with over 75% NO conversion at 150-200 degrees Celsius. The physical and chemical properties of Mn-S were explored, providing insights into its catalytic mechanism and potential for further improvement.