Mesoporous zirconia nanobelts: Preparation, characterization and applications in catalytical methane combustion

Mesoporous ZrO2 nanobelts (MZNs) have been prepared by a calcination route of ZrS3 nanobelts in air. The nanobelts prepared at 400–600 °C are the mixtures of tetragonal and monoclinic phases, and have well-distributed mesopores (pore diameter of about 3.4–3.6 nm). As the calcination temperature increased from 400 to 1200 °C, the structures changed from tetragonal to monoclinic phase, while the morphologies turned from regular nanobelts to bead-like nanowires, and the mesopores disappeared bit by bit. Fe-doped and Fe2O3-loaded MZNs have been prepared to compare the catalytic activities of Fe-doped, Fe2O3-loaded, and pure MZNs for methane combustion. The results showed that Fe2O3-loaded MZNs have rather high catalytic activity, suggesting its potential application in practice. Methane combustion data over the catalysts are well fitted by a first-order kinetic expression.

Graphical abstractMesoporous ZrO2 nanobelts (MZNs) have been prepared by a calcination route of ZrS3 nanobelts in air. Fe-doped and Fe2O3-loaded MZNs have been prepared to compare the catalytic activities of Fe-doped, Fe2O3-loaded, and pure MZNs for methane combustion. The results showed that Fe2O3-loaded MZNs have rather high catalytic activity.Figure optionsDownload full-size imageDownload as PowerPoint slideHighlights► Novel method preparing mesoporous zirconia nanobelts (MZNs) was introduced. ► Fe-doped, Fe2O3-loaded, and pure MZNs were used as catalysts for methane combustion. ► Fe2O3-loaded MZNs showed enhancing catalytic activity. ► Kinetic data over the catalysts were well fitted by a first-order kinetic equation.