Polyethylene Building Blocks by Catalyzed Chain Growth and Efficient End Functionalization Strategies, Including Click Chemistry

Abstract: A means to an end: Polyethylene chains obtained by catalyzed chain growth on magnesium and exhibiting molar masses up to 5000 g mol−1 have been end‐functionalized in high yield with iodide, azide, and amine reactive end groups (see scheme). The functionalized polyethylenes can be used to generate a range of reactive polyolefins; for example, the azide‐functionalized chain can undergo “click” reactions to afford macromonomers.

“…However, this problem has been successfully solved for oligo-and polyethylene with a terminal functional group being a good reactive site for versatile applications. One of possible solutions to the mentioned problem can be achieved by applying neodymium cyclopentadienyl complexes as pre-catalysts along with Alkyl 2 Mg on a stage of catalytic ethylene polymerization followed by replacing the Mg atom at the end of polyethylene chain with a functional group [4][5][6].…”

Catalytic activity of phenyl substituted cyclopentadienyl neodymium complexes in the ethylene oligomerization process

“…However, this problem has been successfully solved for oligo-and polyethylene with a terminal functional group being a good reactive site for versatile applications. One of possible solutions to the mentioned problem can be achieved by applying neodymium cyclopentadienyl complexes as pre-catalysts along with Alkyl 2 Mg on a stage of catalytic ethylene polymerization followed by replacing the Mg atom at the end of polyethylene chain with a functional group [4][5][6].…”

Catalytic activity of phenyl substituted cyclopentadienyl neodymium complexes in the ethylene oligomerization process

“…[1][2][3][4] Potentially,t he macromolecular engineering of PE through the control of its primary structure (that is,c haracteristics such as average molar mass,m olarmass distribution (MMD), [5][6][7][8] branching density,a nd the introduction of functional groups [9][10][11][12][13] )isexpected to fabricate new polyolefin-based high value-added materials.T he development of new catalysts for coordination polymerizations led to significant advances for high-density PE synthesis,enabling living polymerizations,end-group functionalities,and copolymerization with polar monomers.I nc ontrast, similar advances for low-density PE remain aformidable challenge,despite the continuous developments in the field of controlled radical polymerizations (CRPs,o rr eversible-deactivation radical polymerizations,RDRPs).…”

Controlled Radical Polymerization of Ethylene Using Organotellurium Compounds

“…The RAFT process can easily be adapted by covalently attaching the RAFT agent to endfunctional polymers such as poly(ethyleneoxide), [24,[28][29][30][31][32][33][34][35][36] kraton, [37] polyethylene [38][39][40] and poly(dimethylsiloxane). [41] In these cases, the RAFT agent was reacted with the already existing polymer.…”

Hairy Core–Shell Nanoparticles via RAFT: Where are the Opportunities and Where are the Problems and Challenges?