Abstract
Chemical looping methane partial oxidation provides an energy and cost effective route for methane utilization. However, there is considerable CO2 co-production in current chemical looping systems, rendering a decreased productivity in value-added fuels or chemicals. In this work, we demonstrate that the co-production of CO2 can be dramatically suppressed in methane partial oxidation reactions using iron oxide nanoparticles embedded in mesoporous silica matrix. We experimentally obtain near 100% CO selectivity in a cyclic redox system at 750–935 °C, which is a significantly lower temperature range than in conventional oxygen carrier systems. Density functional theory calculations elucidate the origins for such selectivity and show that low-coordinated lattice oxygen atoms on the surface of nanoparticles significantly promote Fe–O bond cleavage and CO formation. We envision that embedded nanostructured oxygen carriers have the potential to serve as a general materials platform for redox reactions with nanomaterials at high temperatures.
Highlights
Chemical looping methane partial oxidation provides an energy and cost effective route for methane utilization
We report an approach to metal oxide oxygen carrier engineering for Chemical looping methane partial oxidation5 (CLPO) by designing and synthesizing nanoscale iron oxide carriers[8] embedded in mesoporous silica SBA-15 (Fe2O3@SBA-15)
We demonstrate that Fe2O3@SBA-15 enables near 100% CO selectivity in chemical looping methane partial oxidation, which is so far the highest value in product selectivity observed for chemical looping systems
Summary
Chemical looping methane partial oxidation provides an energy and cost effective route for methane utilization. We find that cyclic methane partial oxidation with nanoscale oxygen carrier materials can be performed with high selectivity at temperatures as low as 750 °C.
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