优化镍苯氧亚胺催化剂中的阳离子结合袋可提高乙烯聚合效率

IF 2.5 3区 化学 Q2 CHEMISTRY, INORGANIC & NUCLEAR Organometallics Pub Date : 2024-09-17 DOI:10.1021/acs.organomet.4c00260
Lorenzo C. Ruiz De Castilla, Tuhin Ganguly, Babak Tahmouresilerd, Croix J. Laconsay, Judy I. Wu, Loi H. Do
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引用次数: 0

摘要

阳离子调节是调节聚合催化剂反应活性的一种简单而强大的策略,但实现最大阳离子效应的设计规则却不甚明了。本研究证明,在镍苯氧亚胺复合物和 M-聚乙二醇(PEG)(其中 M = Li+、Na+、K+ 或 Cs+)单元之间插入亚甲基间隔物,可使乙烯聚合活性比第一代催化剂提高 70 倍,聚合物分子量提高 6 倍。据推测,这些效应是由于 1:1 比 2:1 镍:碱物种的独家形成,以及 M-PEG 分子更接近镍中心。这些结果表明,要成功制备阳离子响应型催化剂,就必须了解阳离子结合的化学计量学以及与其主客体相互作用相关的结构和电子变化。
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Optimizing the Cation Binding Pocket in Nickel Phenoxyimine Catalysts Improves Ethylene Polymerization Efficiency
Cation tuning is a simple yet powerful strategy to modulate the reactivity of polymerization catalysts, but the design rules to achieve maximum cation effects are not well understood. In the present work, it was demonstrated that inserting a methylene spacer between a nickel phenoxyimine complex and an M-polyethylene glycol (PEG) (where M = Li+, Na+, K+, or Cs+) unit led up to >70-fold increase in ethylene polymerization activity and 6-fold higher polymer molecular weight relative to that of the first-generation catalysts. It is hypothesized that these effects are due to the exclusive formation of 1:1 over 2:1 nickel:alkali species and closer proximity of the M-PEG moiety to the nickel center. These results suggest that the successful creation of cation-responsive catalysts requires an understanding of the cation binding stoichiometry as well as the structural and electronic changes associated with its host–guest interactions.
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来源期刊
Organometallics
Organometallics 化学-无机化学与核化学
CiteScore
5.60
自引率
7.10%
发文量
382
审稿时长
1.7 months
期刊介绍: Organometallics is the flagship journal of organometallic chemistry and records progress in one of the most active fields of science, bridging organic and inorganic chemistry. The journal publishes Articles, Communications, Reviews, and Tutorials (instructional overviews) that depict research on the synthesis, structure, bonding, chemical reactivity, and reaction mechanisms for a variety of applications, including catalyst design and catalytic processes; main-group, transition-metal, and lanthanide and actinide metal chemistry; synthetic aspects of polymer science and materials science; and bioorganometallic chemistry.
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