Manganese oxides have wide application in the ambient decomposition of ozone, although their activities are affected by many parameters. Morphology engineering and metal doping are, together, one of the most… Click to show full abstract
Manganese oxides have wide application in the ambient decomposition of ozone, although their activities are affected by many parameters. Morphology engineering and metal doping are, together, one of the most effective methods to enhance catalytic activity for O3 decomposition. Herein, a topochemical transformation route to Mn3O4 nanospheres composed of 2D nanosheets is first provided by using layered β-MnOOH as the precursor. Then, silver nanoparticles are deposited over the Mn3O4 nanosheets via a redox reaction without any extra reducing agents. In comparison with Mn3O4 with a conventional octahedral morphology, the prepared Mn3O4 nanosphere (Mn3O4-NF), and its Ag-doped composite, Mn3O4@Ag (Mn3O4@Ag-NF), both retain the morphology of β-MnOOH, and display better reducibility and higher oxygen vacancies. The best catalytic performance for O3 decomposition is found over Mn3O4@Ag-NF, which exhibits ∼88.5% removal efficiency within 24 h at a space velocity of 600 L g-1 h-1 and a relative humidity of 50% at room temperature. This work emphasizes the advantages of nanosheet morphology and metal doping in optimizing the catalytic activity for O3 elimination of manganese oxide.
               
Click one of the above tabs to view related content.