Cr-doping regulates Mn3O4 spinel structure for efficient total oxidation of propane: Structural effects and reaction mechanism determination

The exploration of enhancing the low-temperature oxidation performance of catalysts by element doping is desirable but still challenging. Herein, a series of Cr-doping Mn3O4 spinel catalysts (MnxCr3_xO4) were prepared through MOF-74 as precursors and tested for propane total oxidation. Due to the synergy between Cr and Mn, MnxCr3_ xO4 with rich surface-active Mn4+, notable low-temperature reducibility and excellent oxygen migration capability displays notable catalytic activity for propane oxidation. The constructed Mn2.70Cr0.30O4 exhibited superior propane catalytic activity and notable thermal stability. The T90 of Mn2.70Cr0.30O4 is 264 degrees C under humid condition, that 51 degrees C lower than that of Mn3O4. Meanwhile, in-situ spectroscopy and DFT calculations revealed that the addition of Cr can convert propane into propylene in the initial stage thus to reduce the reaction energy barrier. This work provides an element doping strategy to effectively enhance spinel catalysts perfor-mance, and can be provided with bright prospect for efficient VOCs catalysts.

Automated summary

In this study, a series of Cr-doping Mn3O4 spinel catalysts were prepared and tested for propane total oxidation. MnxCr3_xO4 with rich surface-active Mn4+, notable low-temperature reducibility and excellent oxygen migration capability displays notable catalytic activity for propane oxidation. The constructed Mn2.70Cr0.30O4 exhibited superior propane catalytic activity and notable thermal stability.