采用沉积沉淀法制备了CO低温氧化Au/α-Fe2O3催化剂,利用X射线衍射(XRD)、X射线光电子能谱(XPS)、BET比表面测定、程序升温还原( H2-TPR)等表征技术,对比了制备过程pH值的微小变化、焙烧及光线照射对催化剂结构及催化性能的影响,探明了Au/α-Fe2O3催化剂的活性物种.结果表明,110℃处理的Au/α-Fe2O3催化剂表面同时存在Au3+、Au0以及过渡态Auδ+(0<δ<1),它们对CO氧化的活性顺序为Au3+>Auδ+>Au0;pH值为8条件下制备的催化剂Au3+含量高、比表面积大,催化性能最好;高温焙烧使氧化态金还原的同时也使载体比表面积严重缩小,催化活性显著下降;紫外线照射可以引起Au3+的逐渐还原以及Au0颗粒的生长,其催化失活作用弱于高温焙烧.
Au/α-Fe2O3 catalysts for CO oxidation were prepared by chemical coprecipitation at different pH values, and the as-prepared samples were calcined or UV (λ=254 nm) irradiated, respectively. The structure was characterized by X-ray diffraction (XRD), X-ray photoelectron spectroscopy (XPS), N2 adsorption and desorption analysis (BET) and temperature programmed reduction (H2-TPR), and the active Au species on the catalysts was investigated. The results show that Au3+, Auδ+ (0≤δ≤1) and Au0 coexist on the surface of Au/α-Fe2O3 catalysts treated at 110℃, and their activity order is Au3+> Auδ+> Au0. The sample prepared at pH=8 shows the best catalytic performance since it has more Au3+ species and high specific surface area. High temperature calcination can cause serious deactivation due to the reduction of Au3+ and Auδ+ species, together with the decrease of the specific surface area ofα-Fe2O3. UV irradiation can also cause the reduction of oxidative Au species and the growth of Au particle.
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