Hydroaminoalkylation for Amine Functionalization of Vinyl-Terminated Polyethylene Enables Direct Access to Responsive Functional Materials

Dr. Saeed Ataie, Amir Malmir, Sabrina S. Scott, Dr. James T. Goettel, Steven N. Clemens, Dr. Darryl J. Morrison, Cyrus Mackie, Prof. Belinda Heyne, Prof. Savvas G. Hatzikiriakos, Prof. Laurel L. Schafer
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Abstract

While functionalized polyethylenes (PEs) exhibit valuable characteristics, the constraints of existing synthetic approaches limit the variety of readily incorporated functionality. New methods to generate functionalized PEs are required to afford new applications of this common material. We report 100 % atom economic tantalum-catalyzed hydroaminoalkylation of vinyl-terminated polyethylene (VTPE) as a method to produce amine-terminated PE. VTPEs with molecular weights between 2200–16800 g/mol are successfully aminated using solvent-free conditions. Our catalytic system is efficient for the installation of both aromatic and aliphatic amines, and can be carried out on multigram scale. The associating amine functional groups afford modified material properties, as measured by water contact angle, differential scanning calorimetry (DSC) and polymer rheology. The basic amine functionality offers the opportunity to convert inert PE into stimuli-responsive materials, such that the protonation of aminated PE affords the generation of functional antibacterial PE films.

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羟基氨烷基化技术实现乙烯基端聚乙烯的胺官能化,可直接获得响应性功能材料
虽然功能化聚乙烯(PE)表现出了宝贵的特性,但现有合成方法的局限性限制了可随时加入功能的多样性。需要采用新方法生成官能化聚乙烯,以便为这种常见材料提供新的应用领域。我们报告了 100%原子经济钽催化乙烯基封端聚乙烯(VTPE)的氢氨基烷基化,这是一种生产胺封端聚乙烯的方法。在无溶剂条件下,分子量在 2200-16800 g/mol 之间的 VTPE 被成功胺化。我们的催化系统对芳香族和脂肪族胺的安装都很有效,而且可以在多克级规模上进行。根据水接触角、差示扫描量热法(DSC)和聚合物流变学的测量,关联胺官能团可改变材料的特性。基本胺官能团提供了将惰性聚乙烯转化为刺激响应材料的机会,例如,胺化聚乙烯的质子化可生成功能性抗菌聚乙烯薄膜。
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Angewandte Chemie
Angewandte Chemie 化学科学, 有机化学, 有机合成
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