Polymerization Mechanism of α-Linear Olefin 被引量：3

α-直链烯烃的聚合机理

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摘要 The density functional theory on the level of B3LYP/6-31G was empolyed to study the chain growth mechanism in polymerization process of α-linear olefin in TiCl3/AlEt2Cl catalytic system to synthesize drag reduction agent. Full parameter optimization without symmetry restrictions for reactants, products, the possible transition states, and intermediates was calculated. Vibration frequency was analyzed for all of stagnation points on the potential energy surface at the same theoretical level. The internal reaction coordinate was calculated from the transition states to reactants and products respectively. The results showed as flloes：（i） Coordination compounds were formed on the optimum configuration of TiCl3/AlEt2Cl.（ii） The transition states were formed. The energy di？erence between transition states and the coordination compounds was 40.687 kJ/mol. （iii） Double bond opened and Ti-C（4） bond fractured, and the polymerization was completed. The calculation results also showed that the chain growth mechanism did not essentially change with the increase of carbon atom number of α-linear olefin. From the relationship between polymerization activation energy and carbon atom number of the α-linear olefin, it can be seen that the α-linear olefin monomers with 6-10 carbon atoms had low activation energy and wide range. It was optimum to synthesize drag reduction agent by polymerization.

作者邢文国张长桥于萍刘成卜魏云鹤

机构地区山东大学化学与化工学院

出处《Chinese Journal of Chemical Physics》 SCIE CAS CSCD 2010年第1期39-44,I0001,共7页 化学物理学报（英文）

关键词 Density functional theory Polymerization mechanism α-Linear olefin Drag reduction agent Ziegler-Natta catalyst 线性关系 α-烯烃聚合机理配位化合物产品形态坐标计算聚合合成过渡态

分类号 O151.21 [理学—基础数学] TQ221.2 [化学工程—有机化工]

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Polymerization Mechanism of α-Linear Olefin 被引量：3

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