Yu Shu-Yang, Wang Xiao-Yan, Sun Xiu-Li, Gao Yanshan, Zhao Yanan, Ning Xiao-Shan, Ji Gang, Lu Yuan, Yang Jie, Liu Zhi-Pan, Tang Yong
State Key Laboratory of Organometallic Chemistry, Shanghai Institute of Organic Chemistry, Chinese Academy of Sciences, Shanghai, China.
Nat Commun. 2025 Mar 12;16(1):2461. doi: 10.1038/s41467-025-57489-z.
Synthesizing functionalized polyethylenes via ethylene coordination copolymerization with fundamental low-cost vinyl polar monomers provides a very attractive approach. However, it is also very challenging as the functional group (FG) to be introduced onto the polyolefin chain is directly derived from the corresponding vinyl polar monomers (CH = CH-FG), which often cause catalyst poisoning due to the FG coordination to active metal center and β-X elimination during catalysis, etc. It is especially true for the synthesis of cyano-functionalized polyethylenes (PEs) via ethylene/acrylonitrile copolymerization, which can only rely on Pd catalysis with low activity. Here we present an approach utilizing binuclear Ni catalysis for ethylene/acrylamide copolymerization and the synthesis of cyano-functionalized PEs (>99%) with great activity up to 4.1 × 10 g/(mol cat·h). Extensive polymer characterizations (NMR, GPC, model experiments, etc) confirm significant chain transfer and the conversion of amide to nitrile during catalysis. Mechanistic investigations, including comprehensive control experiments, deuterium labeling and computational studies, support an isomerization-mediated chain transfer polymerization (ICTP) mechanistic pathway, which include tandem acrylamide enchainment, amido group conversion into CN group, and active catalyst regeneration by EtAlCl. Catalyst poisoning could be largely circumvented by this catalyst system.
通过乙烯与基本低成本的乙烯基极性单体进行配位共聚来合成功能化聚乙烯提供了一种非常有吸引力的方法。然而,这也极具挑战性,因为要引入到聚烯烃链上的官能团(FG)直接源自相应的乙烯基极性单体(CH = CH-FG),在催化过程中,这些单体常常由于官能团与活性金属中心的配位以及β-X消除等原因导致催化剂中毒。对于通过乙烯/丙烯腈共聚合成氰基功能化聚乙烯(PEs)而言尤其如此,该过程只能依靠活性较低的钯催化。在此,我们提出一种利用双核镍催化进行乙烯/丙烯酰胺共聚以及合成氰基功能化聚乙烯(>99%)的方法,其活性高达4.1×10 g/(mol cat·h)。广泛的聚合物表征(核磁共振、凝胶渗透色谱、模型实验等)证实了催化过程中显著的链转移以及酰胺向腈的转化。机理研究,包括全面的对照实验、氘标记和计算研究,支持了一种异构化介导的链转移聚合(ICTP)机理途径,该途径包括串联丙烯酰胺链增长、酰胺基团转化为氰基基团以及通过EtAlCl实现活性催化剂再生。这种催化剂体系能够在很大程度上避免催化剂中毒。
