气凝胶
材料科学
纤维素
吸附
解吸
化学工程
木质素
蜂巢
氢氧化物
纳米花
复合材料
蜂窝结构
纳米纤维素
环境修复
环境污染
氢
复合数
使用寿命
纳米技术
原材料
智能材料
工艺工程
半纤维素
结构材料
可持续设计
纳米颗粒
抗剪强度(土壤)
动力学
剪切(地质)
模块化设计
解耦(概率)
作者
Wanting Su,Ruimeng Wang,Pengfei Yan,Zuxue Bai,Xuehui Jia,Xu Fan,Liqin Zhou,Zhenxia Zhao
标识
DOI:10.1002/adfm.202526566
摘要
ABSTRACT Nanoplastic (NPs) pollution represents one of the most persistent environmental crises of our time, requiring breakthrough material technologies for effective remediation. In this study, we engineer a semi‐flexible micro‐nano structured N‐modified cellulose nanofibers@layered double hydroxide (N‐CNF@LDH) composite aerogel through a dynamic hydrogen bonding and coordination interactions to achieve efficient removal of NPs, in which the LDH nanoflower clusters are uniformly anchored on the nitrogen‐modified cellulose honeycomb skeleton. Under the action of dynamic hydrogen bonds, the structure undergoes spontaneous reorganization at new equilibrium positions upon release of external force, leading to a reversible opening‐closing motion within the floral clusters. This design enables ultrahigh NPs adsorption (3648 mg·g −1 ) through reversible inter‐petal channel opening, while compression‐triggered petal contraction achieves instantaneous release (96% within only 10 s), exhibiting a desorption kinetics rate nearly three orders of magnitude higher than conventional adsorbents. Besides, the dynamic network enables rapid structural reconstruction of N‐CNF@LDH through H‐bond assembly, maintaining 80.4% NPs capacity and 95.2% shape recovery after 100 cycles. Exhibiting outstanding NPs removal performance in various real‐world water systems while remaining cost‐effective, this material breaks through the fundamental capacity‐regeneration compromise in environmental remediation.
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