Creating a Heterohomogeneous Catalytic System for the Alkylation of Benzene with Ethylene through the Reaction beteen Carbon Tetrachloride and Aluminum Alloys

IF 0.7 Q4 ENGINEERING, CHEMICAL

Catalysis in Industry Pub Date : 2022-12-16 DOI:10.1134/S207005042204002X

A. B. Arbuzov, V. A. Drozdov, A. V. Lavrenov, N. N. Leont’eva

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Abstract

The in situ formation of a catalytic heterohomogeneous system containing Al–M alloy (M is Ni, Co, Cu) and Al(M)/Cl complex in a benzene–ethylene medium at a temperature of 80°C and a pressure of 0.2–0.3 MPa is studied. The characteristic patterns of interaction between Al–M alloys activated with a liquid metal Ga–In eutectic and a chlorinating agent (CCl₄) with the formation of catalytically active metal–aluminum chloride Al(M)/Cl complexes are established. Results from spectrokinetic measurements show the order of the reactivity of activated alloys with respect to excess CCl₄ is Al–Cu ≈ Al–Ni > Al > Al–Co. The highest catalytic activity is displayed by nickel–aluminum chloride complexes whose selectivity toward ethylbenzene is 48%. Data from IR and UV-VIS spectroscopy show that the structure and composition of metal chloride complexes formed in situ in the aromatic reaction medium is determined by a combination of coupled ionic pairs \([{\text{AlC}}{{{\text{l}}}_{4}}]_{{{\text{tetr}}}}^{ - }{\text{/[NiC}}{{{\text{l}}}_{{\text{6}}}}]_{{{\text{oct}}}}^{{4-}}\) and \(\left[ {{\text{AlC}}{{{\text{l}}}_{{\text{4}}}}} \right]_{{{\text{tetr}}}}^{ - }/\left[ {{\text{CuC}}{{{\text{l}}}_{{\text{2}}}}} \right]_{{{\text{lin}}}}^{ - }\), which are stabilized by (C₆H₅)₃C⁺ carbocation.

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通过四氯化碳与铝合金反应建立苯与乙烯烷基化的非均相催化体系

研究了Al - M合金(M为Ni、Co、Cu)和Al(M)/Cl配合物在苯-乙烯介质中，在温度为80℃、压力为0.2 ～ 0.3 MPa的条件下原位形成催化非均相体系的过程。建立了Al - M合金与液态金属Ga-In共晶和氯化剂(CCl4)相互作用形成具有催化活性的金属-氯化铝Al(M)/Cl配合物的特征模式。光谱动力学测量结果表明，活性合金对过量CCl4的反应性顺序为:Al-Cu≈Al-Ni ＆gt;Al ＆gt;铝业公司。氯化镍铝配合物的催化活性最高，对乙苯的选择性为48%. Data from IR and UV-VIS spectroscopy show that the structure and composition of metal chloride complexes formed in situ in the aromatic reaction medium is determined by a combination of coupled ionic pairs \([{\text{AlC}}{{{\text{l}}}_{4}}]_{{{\text{tetr}}}}^{ - }{\text{/[NiC}}{{{\text{l}}}_{{\text{6}}}}]_{{{\text{oct}}}}^{{4-}}\) and \(\left[ {{\text{AlC}}{{{\text{l}}}_{{\text{4}}}}} \right]_{{{\text{tetr}}}}^{ - }/\left[ {{\text{CuC}}{{{\text{l}}}_{{\text{2}}}}} \right]_{{{\text{lin}}}}^{ - }\), which are stabilized by (C6H5)3C+ carbocation.

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来源期刊

Catalysis in Industry ENGINEERING, CHEMICAL-

CiteScore

1.30

自引率

14.30%

发文量

期刊介绍： The journal covers the following topical areas: Analysis of specific industrial catalytic processes: Production and use of catalysts in branches of industry: chemical, petrochemical, oil-refining, pharmaceutical, organic synthesis, fuel-energetic industries, environment protection, biocatalysis; technology of industrial catalytic processes (generalization of practical experience, improvements, and modernization); technology of catalysts production, raw materials and equipment; control of catalysts quality; starting, reduction, passivation, discharge, storage of catalysts; catalytic reactors.Theoretical foundations of industrial catalysis and technologies: Research, studies, and concepts : search for and development of new catalysts and new types of supports, formation of active components, and mechanochemistry in catalysis; comprehensive studies of work-out catalysts and analysis of deactivation mechanisms; studies of the catalytic process at different scale levels (laboratory, pilot plant, industrial); kinetics of industrial and newly developed catalytic processes and development of kinetic models; nonlinear dynamics and nonlinear phenomena in catalysis: multiplicity of stationary states, stepwise changes in regimes, etc. Advances in catalysis: Catalysis and gas chemistry; catalysis and new energy technologies; biocatalysis; nanocatalysis; catalysis and new construction materials.History of the development of industrial catalysis.

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