Issue 7, 2022

Chain-growth click copolymerization for the synthesis of branched copolymers with tunable branching densities

Abstract

In this work, we reported a facile synthesis of (hyper)branched copolymers with a tunable degree of branching (DB) via one-pot chain-growth copper-catalyzed azide–alkyne cycloaddition (CuAAC) reactions. By using a tri-azido core molecule as an initiator, a variety of difunctional AB monomers with different linkers were designed for CuAAC copolymerization with a trifunctional AB2 monomer to produce a series of branched copolymers with tunable compositions and low dispersity. Kinetics studies and chain-extension experiments confirmed the features of the chain-growth mechanism and living polymerization. Although AB2 monomers showed a higher homopropagation rate than AB monomers, their copolymerization consumed AB monomers slightly faster than AB2 monomers probably due to their steric difference. The incorporation of pH-responsive and redox-responsive linkages into AB monomers allowed the stimuli-responsive degradation of branched copolymer structures into fragments. Preliminary studies indicated that branched polymers with lower DBs showed a higher loading capacity than hyperbranched polymers from the homopolymerization of AB2, demonstrating the dependence of the payload encapsulation efficiency on polymer structure compactness. This exploration expanded our toolbox to tune the composition and structures of (hyper)branched polymers for their potential application as unimolecular nanocontainers.

Graphical abstract: Chain-growth click copolymerization for the synthesis of branched copolymers with tunable branching densities

Supplementary files

Article information

Article type
Paper
Submitted
09 N’w 2021
Accepted
10 Sun 2022
First published
11 Sun 2022

Polym. Chem., 2022,13, 891-897

Author version available

Chain-growth click copolymerization for the synthesis of branched copolymers with tunable branching densities

K. Ma, X. Jin, W. Gan, C. Fan and H. Gao, Polym. Chem., 2022, 13, 891 DOI: 10.1039/D1PY01635K

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