解聚
聚合物
共价键
材料科学
纳米技术
催化作用
热的
化学工程
动态共价化学
化学工业
碳酸盐
化石燃料
离子
绿色化学
碳纤维
有机化学
增韧
作者
Xiaoyue Zeng,Shiguang Zhang,Huiya Li,Chun Liu,Liang Chen
标识
DOI:10.1038/s41467-026-70046-6
摘要
The polymer industry is confronting an urgent sustainability trilemma: accelerating plastic pollution, substantial CO2 emissions from production processes, and dependence on diminishing fossil resources. Upcycling CO2 into polymers presents a promising solution to these interconnected issues; however, existing CO2-to-polymer technologies face significant challenges: dependence on concentrated CO2 sources rather than direct air capture (DAC), reliance on complex catalysts and energy-intensive conditions (elevated temperatures/pressures), and generation of polymers with limited self-healing and recyclability. Herein, we propose a catalyst-free strategy of converting atmospheric CO2 into carbonate ions (CO32-) as intermediates for the synthesis of dynamic covalent polymers. This approach is based on a dynamic bond system, termed the CO32--bridged dynamic covalent bond, enabling catalyst-free synthesis of polymers from ambient air at room temperature and pressure. The resultant polymers show excellent mechanical properties, rapid self-healing, and versatile circularity through three distinct pathways: thermal reprocessing, closed-loop chemical recycling via acid-triggered depolymerization at room temperature, and upcycling of mixed CO2-derived polymers into hybrid materials with enhanced properties. This study provides a platform for both low-energy-consuming CO2 valorization and the development of sustainable polymers.
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