A novel copper(I)-anchored covalent organic polymer (Cu+@COP) is presented as a robust, heterogeneous catalyst for copper-catalyzed azide–alkyne cycloaddition (CuAAC), operating without the need for external reducing agents or observable copper leaching. Cu+ stabilization is achieved via multidentate N,O-ligand coordination within the polymer matrix, enabling high catalytic efficiency (up to 95% yield) and recyclability. Structural, spectroscopic, and ICP-OES analyses confirm Cu presence, offering an alternative to traditional CuAAC protocols. This system combines operational simplicity, reduced waste, and green chemistry principles, positioning Cu+@COP as a practical catalyst for applications in synthetic and materials chemistry.
Copper(I)-Anchoring Covalent Organic Polymer for Heterogeneous CuAAC Reaction without Reducing Agents and Copper Leaching / Guarducci, Maria Aurora; Manetto, Simone; Marrani, Andrea Giacomo; Amato, Francesco; Guglielmi, Paolo; Coluccia, Michele; Fontana, Antonella; Pilato, Serena; Villani, Claudio; Ciogli, Alessia; Mazzoccanti, Giulia. - In: ACS ORGANIC & INORGANIC AU.. - ISSN 2694-247X. - 5:6(2025), pp. 507-517. [10.1021/acsorginorgau.5c00067]
Copper(I)-Anchoring Covalent Organic Polymer for Heterogeneous CuAAC Reaction without Reducing Agents and Copper Leaching
Maria Aurora Guarducci;Simone Manetto;Andrea Giacomo Marrani;Francesco Amato;Paolo Guglielmi;Michele Coluccia;Claudio Villani;Alessia Ciogli;Giulia Mazzoccanti
2025
Abstract
A novel copper(I)-anchored covalent organic polymer (Cu+@COP) is presented as a robust, heterogeneous catalyst for copper-catalyzed azide–alkyne cycloaddition (CuAAC), operating without the need for external reducing agents or observable copper leaching. Cu+ stabilization is achieved via multidentate N,O-ligand coordination within the polymer matrix, enabling high catalytic efficiency (up to 95% yield) and recyclability. Structural, spectroscopic, and ICP-OES analyses confirm Cu presence, offering an alternative to traditional CuAAC protocols. This system combines operational simplicity, reduced waste, and green chemistry principles, positioning Cu+@COP as a practical catalyst for applications in synthetic and materials chemistry.| File | Dimensione | Formato | |
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