A sample of sulfated anatase TiO2 with high‐energy(001)facets(TiO2‐001)was prepared by a simple one‐step hydrothermal route using SO42-as a morphology‐controlling agent.After doping ceria,Ce/TiO2‐001 was used as the catalyst for selective catalytic reduction(SCR)of NO with NH3.Compared with Ce/P25(Degussa P25 TiO2)and Ce/P25‐S(sulfated P25)catalysts,Ce/TiO2‐001 was more suitable for medium‐and high‐temperature SCR of NO due to the high surface area,sulfation,and the excellent properties of the active‐energy(001)facets.All of these facilitated the generation of abundant acidity,chemisorbed oxygen,and activated NOx‐adsorption species,which were the important factors for the SCR reaction.
α‐,β‐,γ‐andδ‐MnO2catalysts were synthesized by a one‐step hydrothermal method,and were utilized for the catalytic oxidation of toluene in a combined plasma‐catalytic process.The relationship between catalytic performance and MnO2crystal structures was investigated.It was noted that the toluene removal efficiency was32.5%at the specific input energy of160J/L when non‐thermal plasma was used alone.Theα‐MnO2catalyst showed the best activity among the investigated catalysts,yielding a toluene conversion of78.1%at the specific input energy of160J/L.Forβ‐MnO2,γ‐MnO2andδ‐MnO2,removal efficiencies of47.4%,66.1%and50.0%,respectively,were achieved.By powder X‐ray diffraction,Raman spectroscopy,transmission electron microscopy,scanning electron microscopy,Brunauer‐Emmett‐Teller,H2temperature‐programmed reduction and X‐ray photoelectron spectroscopy analyses,it was concluded that the tunnel structure,the stability of the crystal in plasma,the Mn-O bond strength of MnO2and the surface‐chemisorbed oxygen species played important roles in the plasma‐catalytic degradation of toluene.Additionally,the degradation routes of toluene in non‐thermal plasma and in the plasma‐catalytic process were also studied.It was concluded that the introduction of MnO2catalysts enabled O3,O2,electrons and radical species in the gas to be adsorbed on the MnO2surface via a facile interconversion among the Mn4+,Mn3+and Mn2+states.These four species could then be transported to the toluene or intermediate organic by‐products,which greatly improved the toluene removal efficiency and decreased the final output of by‐products.
