在甲醇钠的存在下，钨羰基配合物[(CO)5WCl]−均相催化合成甲醛

Q4 Chemical Engineering

分子催化 Pub Date : 1994-10-13 DOI:10.1016/0304-5102(94)00099-9

Cesar Ovalles , Carolina Fernández , Donald J. Darensbourg

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引用次数: 1

摘要

以阴离子钨羰基络合物[(CO)5WCl] -为前驱物，NaOMe/W的摩尔比小于8，在125℃、400 psi的CO2条件下，24小时内，甲氧基钠和二氧化碳可合成甲醛(周转率=10)。最可能的机制是通过[(CO)5WCl]−与NaOMe反应生成[(CO)5WOCH3]−。甲氧基配合物通过β-抽氢生成甲醛和末端氢化物[(CO)5WH]−，末端氢化物在反应条件下分解生成桥接氢化物[(μ-H)W2(CO)10]−。将二氧化碳插入配合物[(CO)5WH]−中，NaOMe反应生成醇氧化合物[(CO)5WOCH3]−和甲酸钠。[(CO)5WCl]−与NaOMe反应的动力学研究表明，该反应机制涉及碱对金属中心的亲核攻击，并根据碱/金属的摩尔比通过两种不同的途径进行。对于比率NaOMe/W <β-氢反应发生，生成[(μ-H)W2(CO)10]−和甲醛。对于较高的碱/金属比(>8)，观察到金属团簇的形成。

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Homogeneous catalytic synthesis of formaldehyde using the tungsten carbonyl complex [(CO)5WCl]− in the presence of sodium methoxide

Formaldehyde can be synthesized (Turnover number=10) from sodium methoxide and carbon dioxide using the anionic tungsten carbonyl complex [(CO)₅WCl]⁻ as catalyst precursor and a molar ratio NaOMe/W lower than 8 at 125°C, 400 psi of CO₂ for a 24-h period. The most probable mechanism involves the generation of the [(CO)₅WOCH₃]⁻ species by the reaction of [(CO)₅WCl]⁻ with NaOMe. The methoxide complex can undergo β-hydrogen abstraction to yield formaldehyde and the terminal hydride [(CO)₅WH]⁻, which in turn, decomposes under reaction conditions to provide the bridging hydride [(μ-H)W₂(CO)₁₀]⁻. Carbon dioxide insertion into the complex [(CO)₅WH]⁻, followed by reaction of NaOMe regenerates the alkoxide compound [(CO)₅WOCH₃]⁻ and sodium formate. A kinetic study of the reaction of [(CO)₅WCl]⁻ with NaOMe suggests that the mechanism involves nucleophilic attack of the base on the metal center, and proceeds by two different pathways depending on the molar ratio base/metal. For a ratio NaOMe/W < 8 the β-hydrogen reaction takes place with the formation of [(μ-H)W₂(CO)₁₀]⁻ and formaldehyde. For higher base/metal ratio (>8) the formation of metal cluster is observed.

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来源期刊

分子催化 Chemical Engineering-Catalysis

CiteScore

1.50

自引率

0.00%

发文量

2959

期刊介绍： Journal of Molecular Catalysis (China) is a bimonthly journal, founded in 1987. It is a bimonthly journal, founded in 1987, sponsored by Lanzhou Institute of Chemical Physics, Chinese Academy of Sciences, under the supervision of Chinese Academy of Sciences, and published by Science Publishing House, which is a scholarly journal openly circulated both at home and abroad. The journal mainly reports the latest progress and research results on molecular catalysis. It contains academic papers, research briefs, research reports and progress reviews. The content focuses on coordination catalysis, enzyme catalysis, light-ribbed catalysis, stereochemistry in catalysis, catalytic reaction mechanism and kinetics, the study of catalyst surface states and the application of quantum chemistry in catalysis. We also provide contributions on the activation, deactivation and regeneration of homogeneous catalysts, solidified homogeneous catalysts and solidified enzyme catalysts in industrial catalytic processes, as well as on the optimisation and characterisation of catalysts for new catalytic processes. The main target readers are scientists and postgraduates working in catalysis in research institutes, industrial and mining enterprises, as well as teachers and students of chemistry and chemical engineering departments in colleges and universities. Contributions from related professionals are welcome.