材料科学
纳米技术
生物量(生态学)
工作(物理)
仿生学
可持续发展
生化工程
可持续生产
资源(消歧)
聚酯纤维
木质纤维素生物量
仿生材料
智能材料
可持续设计
循环经济
可持续社会
资源枯竭
工艺工程
资源效率
废物管理
天然材料
耐久性
环境友好型
磁导率
单位(环理论)
细胞通透性
作者
Yao Li,Xing‐Liang Li,Teng Fu,Zhengming Li,Xiaofeng Xu,Rui‐Zhi Wu,Zhen Zhou,Xiuli Wang,Yu‐Zhong Wang
标识
DOI:10.1002/adfm.202521437
摘要
Abstract Biomass materials offer a promising sustainable development strategy amid escalating global resource and environmental issues caused by plastics. However, incumbent materials suffer from aging when exposed to environmental factors, and their non‐recyclability exacerbates ecological challenges. Inspired by plant self‐repair mechanisms, a self‐reinforcing, recyclable, multifunctional, sustainable polyester material derived from lignocellulosic biomass through a “one stone for multiple birds” strategy is presented. Unlike conventional materials that progressively age under practical environmental conditions, by mimicking plant cell wall structures, this material incorporates an aromatic π‐conjugated cinnamene unit that undergoes [2+2]‐cycloaddition reactions under UV or hygrothermal conditions, significantly enhancing barrier efficiency (O 2 permeability 0.026 barrer, +115%), mechanical properties (Young's modulus 319.3 MPa, +21%), and UV resistance (99.6%, +2%). Additionally, it demonstrates superior solvent resistance, fluorescent anti‐counterfeiting capabilities, and recyclability, enabling a fully sustainable life cycle. This work provides a viable strategy for developing next‐generation biomass plastics that support sustainable development.
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