One-step preparation of efficient cuprous chloride catalyst for direct synthesis of trimethoxysilane

doi:10.1016/j.cjche.2024.05.001

Abstract

Abstract: CuCl-based catalysts are the most commonly used catalysts for the “direct synthesis” of trimethoxysilane (M3). CuCl species are sensitive to air and water, and are prone to oxidation deactivation. When CuCl is directly used as a catalyst, it needs to be purified before the utilization, and the operating conditions for the catalyst preparation are relatively harsh, requiring the inert gas environment. Considering a high-temperature activation step required for CuCl-based catalysts used for catalyzing synthesis of M3 to form active phase Cu–Si alloys (Cu_xSi) with Si powder, in this work, a series of catalysts for the “direct synthesis” of M3 were obtained by a one-step high-temperature activation of the mixture of stable CuCl₂ precursors, activated carbon-reducing agent, and Si powder, simultaneously achieving the reduction of CuCl₂ to CuCl and the formation of active phase Cu_xSi alloys of CuCl with Si powder. The prepared samples were characterized through various characterization techniques, and investigated for the catalytic performance for the “direct synthesis” of M3. Moreover, the operation conditions were optimized, including the activation temperature, catalyst dosage, Si powder particle size, and reaction temperature. The characterization results indicate that during the one-step activation process, the CuCl₂ precursor is reduced to CuCl, and the resulting CuCl simultaneously reacts with Si powder to form active phases Cu₃Si and Cu₁₅Si₄ alloys. The optimal catalyst S_acm(250, 0.8:10) exhibits a good catalytic activity with selectivity of 95% and yield of 77% for M3, and shows a good universality for various alcohol substrates. Furthermore, the catalytic mechanism of the prepared catalyst for the “direct synthesis” of M3 was discussed.

Key words: Trimethoxysilane, Cuprous chloride, Catalysis, Catalyst activation, Reduction, Active phase formation

摘要： CuCl-based catalysts are the most commonly used catalysts for the “direct synthesis” of trimethoxysilane (M3). CuCl species are sensitive to air and water, and are prone to oxidation deactivation. When CuCl is directly used as a catalyst, it needs to be purified before the utilization, and the operating conditions for the catalyst preparation are relatively harsh, requiring the inert gas environment. Considering a high-temperature activation step required for CuCl-based catalysts used for catalyzing synthesis of M3 to form active phase Cu–Si alloys (Cu_xSi) with Si powder, in this work, a series of catalysts for the “direct synthesis” of M3 were obtained by a one-step high-temperature activation of the mixture of stable CuCl₂ precursors, activated carbon-reducing agent, and Si powder, simultaneously achieving the reduction of CuCl₂ to CuCl and the formation of active phase Cu_xSi alloys of CuCl with Si powder. The prepared samples were characterized through various characterization techniques, and investigated for the catalytic performance for the “direct synthesis” of M3. Moreover, the operation conditions were optimized, including the activation temperature, catalyst dosage, Si powder particle size, and reaction temperature. The characterization results indicate that during the one-step activation process, the CuCl₂ precursor is reduced to CuCl, and the resulting CuCl simultaneously reacts with Si powder to form active phases Cu₃Si and Cu₁₅Si₄ alloys. The optimal catalyst S_acm(250, 0.8:10) exhibits a good catalytic activity with selectivity of 95% and yield of 77% for M3, and shows a good universality for various alcohol substrates. Furthermore, the catalytic mechanism of the prepared catalyst for the “direct synthesis” of M3 was discussed.

关键词: Trimethoxysilane, Cuprous chloride, Catalysis, Catalyst activation, Reduction, Active phase formation

Jiaxin Zhang, Lu Wang, Zhiqiang Ma, Chuanjun Di, Guanghui Chen, Jipeng Dong, Jianlong Li, Fei Gao. One-step preparation of efficient cuprous chloride catalyst for direct synthesis of trimethoxysilane[J]. Chinese Journal of Chemical Engineering, 2024, 71(7): 161-171.

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