Nanopowder-Supported Ultra-Low Content Co–Rh Bimetallic Catalysts for Hydroformylation of Monoformyltricyclodecenes to Value-Added Fine Chemicals

IF 2.1 4区化学 Q3 CHEMISTRY, PHYSICAL Progress in Reaction Kinetics and Mechanism Pub Date : 2018-10-01 DOI:10.3184/146867818X15319903829173

Chengyang Li, Libo Zhang, Yubo Ma, Tianfu Wang

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Abstract

The hydroformylation of monoformyltricyclodecenes (MFTD) to diformyltricyclodecanes (DFTD) was studied systematically. A series of 0.006 wt% Rh–0.006 wt% Co catalysts supported on commercially available nanopowders such as Al2O3, ZnO, TiO2 and CeO2 was prepared by the incipient wetness method and used to catalyse the hydroformylation of MFTD to DFTD. The 0.006 wt% Rh–0.006 wt% Co/ZnO catalyst showed the highest catalytic performance among the catalysts investigated, thus 41.8% DFTD yield with 100% DFTD selectivity could be achieved. This suggested that there may be a key role of the carrier on the catalytic performance in MFTD hydroformylation. Furthermore, the kinetic profiles for MFTD hydroformylation over the 0.006 wt% Rh–0.030 wt% Co/ZnO catalyst have been examined systematically to explore the effect of reaction temperature on the catalytic performance. These results collectively suggested that a particular reaction temperature might benefit MFTD hydroformylation. There may be some agglomeration of the active sites at higher reaction temperatures.

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纳米粉体负载的超低含量Co-Rh双金属催化剂用于单甲酰三环癸烯氢甲酰化制备高附加值精细化学品

系统地研究了单甲酰基三环癸烯(MFTD)的氢甲酰化反应生成二甲酰基三环癸烷(DFTD)。以Al2O3、ZnO、TiO2和CeO2为载体，采用初始湿法制备了一系列0.006 wt% Rh-0.006 wt% Co催化剂，用于催化MFTD的氢甲酰化合成DFTD。在所研究的催化剂中，0.006 wt% Rh-0.006 wt% Co/ZnO催化剂的催化性能最高，DFTD收率为41.8%，选择性为100%。这表明载体可能对MFTD氢甲酰化的催化性能起关键作用。此外，在0.006 wt% Rh-0.030 wt% Co/ZnO催化剂上系统地考察了MFTD氢甲酰化的动力学分布，探讨了反应温度对催化性能的影响。这些结果共同表明，特定的反应温度可能有利于MFTD氢甲酰化。在较高的反应温度下，活性位点可能会发生团聚。

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来源期刊

Progress in Reaction Kinetics and Mechanism 化学-物理化学

CiteScore

2.10

自引率

0.00%

发文量

审稿时长

2.3 months

期刊介绍： The journal covers the fields of kinetics and mechanisms of chemical processes in the gas phase and solution of both simple and complex systems.