Tuneable N‐Substituted Polyamides with High Biomass Content via Ugi 4 Component Polymerization

Inside Cover: In article number 2100408 by C. Remzi Becer and co‐workers, N‐substituted polyamides with high biomass content and tunable physical properties, such as glass transition temperature and hydrophobicity, are prepared via an efficient catalyst‐free Ugi 4‐component reaction polymerization i...

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Veröffentlicht in:	Macromolecular chemistry and physics 2022-07, Vol.223 (13), p.n/a
Hauptverfasser:	MacKinnon, Daniel, Zhao, Tieshuai, Becer, C. Remzi
Format:	Artikel
Sprache:	eng
Schlagworte:	Biomass Chemical synthesis Glass transition temperature Hydrophobicity Physical properties Polyamide resins Polymerization Room temperature Substitutes Thermal stability
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creator	MacKinnon, Daniel Zhao, Tieshuai Becer, C. Remzi
description	Inside Cover: In article number 2100408 by C. Remzi Becer and co‐workers, N‐substituted polyamides with high biomass content and tunable physical properties, such as glass transition temperature and hydrophobicity, are prepared via an efficient catalyst‐free Ugi 4‐component reaction polymerization in an optimized solvent system. The obtained polyamides, which show excellent thermal stability and near‐room temperature glass transitions, highlight the potential of the Ugi reaction in the synthesis of tunable polyamides from biomass.
doi_str_mv	10.1002/macp.202270028
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subjects	Biomass Chemical synthesis Glass transition temperature Hydrophobicity Physical properties Polyamide resins Polymerization Room temperature Substitutes Thermal stability
title	Tuneable N‐Substituted Polyamides with High Biomass Content via Ugi 4 Component Polymerization
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