Evolution mechanism of transition metal in NH3-SCR reaction over Mn-based bimetallic oxide catalysts: Structure-activity relationships

The unexpected phenomenon in which different transition metals (Co, Ni and Cu) presented significant variation of participation levels as the auxiliaries in Mn-based bimetallic oxide catalysts were reported here. It is found that the Co element more easily to form Mn enriched surface bimetallic oxides with Mn than Ni and Cu, resulting in Co-MnOx exhibited the best deNO(x) activity and SO2 tolerance, followed by Ni-MnOx and Cu-MnOx . The role of different transition metal and structure-activity relationships were systematically investigated by advanced techniques including Synchrotron XAFS and in situ DRIFTs analysis. The excellent activity of Co-MnO x was related to its unique Mn-enriched surface (Co2+)tet(Mn3+ Co3+)octO(4) structure with Mn cations occupying the octahedral sites, which is superior to the Ni-MnOx and Cu-MnOx with Mn-lean surface. In addition, the reaction energy barrier of Co-MnOx is weakened due to the lower electron cloud density around the Mn atom as compared to Ni-MnOx and Cu-MnOx . Moreover, Co-MnOx benefiting from the rapid electron migration between Mn and Co, more active bidentate/bridged nitrates could react with adsorbed NH 3 in faster reaction rates following the L-H mechanism.

Automated summary

The study found that cobalt is more easily enriched on the surface of manganese-based bimetallic oxide catalysts, exhibiting the best deNO(x) activity and SO2 tolerance. The role of different transition metals and the structure-activity relationships were systematically investigated using advanced techniques.