Low-temperature selective catalytic reduction of NO with NH(3) over an FeO(x)/β-MnO(2) composite

A series of Fe-modified β-MnO(2) (FeO(x)/β-MnO(2)) composite catalysts were prepared by an impregnation method with β-MnO(2) and ferro nitrate as raw materials. The structures and properties of the composites were systematically characterized and analyzed by X-ray diffraction, N(2) adsorption–desorption, high-resolution electron microscopy, temperature-programmed reduction of H(2), temperature-programmed desorption of NH(3), and FTIR infrared spectroscopy. The deNO(x) activity, water resistance, and sulfur resistance of the composite catalysts were evaluated in a thermally fixed catalytic reaction system. The results indicated that the FeO(x)/β-MnO(2) composite (Fe/Mn molar ratio of 0.3 and calcination temperature of 450 °C) had higher catalytic activity and a wider reaction temperature window compared with β-MnO(2). The water resistance and sulfur resistance of the catalyst were enhanced. It reached 100% NO conversion efficiency with an initial NO concentration of 500 ppm, a gas hourly space velocity of 45 000 h(−1), and a reaction temperature of 175–325 °C. The appropriate Fe/Mn molar ratio sample had a synergistic effect, affecting the morphology, redox properties, and acidic sites, and helped to improve the low-temperature NH(3)-SCR activity of the composite catalyst.