Abstract
Direct decomposition of NO into N2 and O2 (2NO→N2 + O2) is recognized as the “ideal” reaction for NOx removal because it needs no reductant. It was reported that the spinel Co3O4 is one of the most active single-element oxide catalysts for NO decomposition at higher reaction temperatures, however, activity remains low below 650 °C. The present study aims to investigate new promoters for Co3O4, specifically PdO vs. PtO. Interestingly, the PdO promoter effect on Co3O4 was much greater than the PtO effect, yielding a 4 times higher activity for direct NO decomposition at 650 °C. Also, Co3O4 catalysts with the PdO promoter exhibit higher selectivity to N2 compared to PtO/Co3O4 catalysts. Several characterization measurements, including X-ray diffraction (XRD), X-ray photoelectron spectroscopy (XPS), H2-temperature programmed reduction (H2-TPR), and in situ FT-IR, were performed to understand the effect of PdO vs. PtO on the properties of Co3O4. Structural and surface analysis measurements show that impregnation of PdO on Co3O4 leads to a greater ease of reduction of the catalysts and an increased thermal stability of surface adsorbed NOx species, which contribute to promotion of direct NO decomposition activity. In contrast, rather than remaining solely as a surface species, PtO enters the Co3O4 structure, and it promotes neither redox properties nor NO adsorption properties of Co3O4, resulting in a diminished promotional effect compared to PdO.
Highlights
Nitrogen oxides (NOx) formed by combustion from fixed and mobile sources cause severe detrimental environmental problems, such as acid rain and photochemical smog [1,2,3]
The direct NO decomposition measurements show that PdO promotes the activity of Co3 O4 and is 4 times more active compared to PtO at 650 ◦ C
Surface area measurements indicated that both PdO and PtO have little to no influence on the surface area of Co3 O4, except for a decrease in surface area for 4 wt% PdO/Co3 O4
Summary
Nitrogen oxides (NOx) formed by combustion from fixed and mobile sources cause severe detrimental environmental problems, such as acid rain and photochemical smog [1,2,3]. NO decomposition takes place slowly, if at all, over pure Co3 O4 at temperatures below 650 ◦ C [18] They reported that the presence of small amounts of alkali metals were essential to activate NO decomposition over Co3 O4 oxide by enhancing NO adsorption [18,19,20]. Haneda et al [25] found that the addition of Pt improved the direct NO decomposition performance of rare earth oxides They [26,27] compared the activity of [Pd(NH3 )4 ] (NO3 ) , Pd(NO3 ) , Pd(CH3 COO) , and (NH4 )2 -[PdCl4 ] as palladium precursors for NO decomposition in a Pd/Al2 O3 catalyst at 700 ◦ C, and the activity was found to decrease in the order of. Several characterization techniques such as X-ray diffraction (XRD), X-ray photoelectron spectroscopy (XPS), H2 -Temperature programmed reduction (H2 -TPR), and in situ FT-IR are employed to understand the influence of PdO and PtO on the structural and surface properties of Co3 O4
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