苯乙酮氢转移反应中ZrO2 /MCM-41和 ZrO2 /AC的催化性能对比

doi:10.3969/j.issn.0251-0790.2012.06.034

摘要/Abstract

摘要： 采用浸渍法制备了分别以活性炭(AC)和全硅MCM-41介孔分子筛负载的ZrO₂催化剂, 并对其进行了XRD、氮气吸附-脱附、X射线光电子能谱、差热-热重分析和吡啶吸附原位红外光谱等表征, 考察了其在以异丙醇为氢源还原苯乙酮为α-苯乙醇的Meerwein-Ponndorf-Verley(MPV)反应中的催化活性, 并与水合ZrO₂进行对比. 研究了载体对催化剂活性的影响. 结果表明, ZrO₂经MCM-41负载后, 与载体发生强相互作用, 可能形成Si-O-Zr键, ZrO₂在载体表面呈高分散的无定形态, Zr-OH数目显著增加, L酸性增强, 并形成B酸中心, 使催化剂活性显著高于水合ZrO₂; ZrO₂负载在AC上后, 与载体未发生强相互作用, ZrO₂在载体表面未呈高分散状态, 增加的Zr-OH数目相对较少, L酸性较弱, 未形成B酸中心, 催化活性未明显增加, 但在较高焙烧温度(400~600 ℃)下, 其仍能保持稳定的催化活性, 这可归因于ZrO₂/ AC中AC孔道疏通及AC石墨层对苯乙酮上苯环的吸附作用, 使活性位附近的反应底物浓度显著增大.

关键词: 氧化锆, MCM-41介孔分子筛, 活性炭, 苯乙酮, 氢转移反应

Abstract: Zirconia(ZrO₂) was supported on active carbon(AC) or siliceous MCM-41 mesoporous materials(ZrO₂/MCM-41) respectively through the impregnation method, At the same time, these samples were cha-racterized by XRD, N₂ adsorption-desorption, XPS, TG-DSC and FTIR spectra of adsorbed pyridine methods. Their catalytic activities in the Meerwein-Ponndorf-Verley(MPV) reduction of acetophenone with α-propanol as a hydrogen donor were investigated, and compared to that of hydrous zirconia to study the support effect on their catalytic activities. The results showed that catalytic activity was significantly improved upon loading zirconia on MCM-41 support, due to the formation of Si-O-Zr bond between zirconia and MCM-41 supported, which resulted in the formation of highly dispersed amorphous zirconia in the catalyst, consequently a marked increase of the amount of the Zr-OH group, the strengthening of Lewis acidity and an appearance of Brnsted acid sites. In contrast to ZrO₂/MCM-41, no obvious increase of catalytic activity was observed after loading zirconia on AC support owing to the weak interaction between zirconia and AC support, which resulted in the lower dispersion of zirconia on AC support, consequently a less increase of number of Zr-OH groups and weak Lewis acidity. However, ZrO₂/AC calcined at higher temperature(400-600 ℃) still retained steady activity, which may be due to the dredging of pores in AC during the calcination, and the increase of concentration of acetophenone near the active sites via the π-π electron interaction between the benzene ring in the acetophenone and graphite layer of AC support.

Key words: Zirconia, MCM-41 mesoporous molecular sieve, Active carbon(AC), Acetophenone, Hydrogen transfer reaction

中图分类号:

O643.32⁺2

TrendMD:

袁剑, 张波, 汤明慧, 卢晗锋, 陈银飞. 苯乙酮氢转移反应中ZrO₂ /MCM-41和 ZrO₂ /AC的催化性能对比. 高等学校化学学报, 2012, 33(06): 1326.

YUAN Jian, ZHANG Bo, TANG Ming-Hui, LU Han-Feng, CHEN Yin-Fei. Comparison of ZrO₂/MCM-41 and ZrO₂/AC Catalysts in Hydrogen Transfer Reaction of Acetophenone. Chem. J. Chinese Universities, 2012, 33(06): 1326.

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苯乙酮氢转移反应中ZrO₂ /MCM-41和 ZrO₂ /AC的催化性能对比

Comparison of ZrO₂/MCM-41 and ZrO₂/AC Catalysts in Hydrogen Transfer Reaction of Acetophenone

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