材料科学
两亲性
介观物理学
纳米技术
介孔材料
共价键
成核
部分
纳米颗粒
自组装
化学工程
单体
多孔性
杰纳斯粒子
皮克林乳液
纳米结构
表面改性
纳米尺度
星团(航天器)
共价有机骨架
形态学(生物学)
胶体
作者
Hao Chen,Gaijuan Guo,Wenda Li,Shanzhe Ke,Hongyi Zhang,Jianwei Fu,Chengbin Jing,S. Liu
标识
DOI:10.1002/anie.202517356
摘要
Abstract Interfaces serve as powerful, versatile platforms that have significantly advanced the development of novel materials. However, bottom‐up construction of reactive interfaces for controlled synthesis of crystalline porous materials still remains a substantial challenge. Here, we constructed a stable, morphology‐tunable reactive interface by spontaneous self‐assembly of amphiphilic moiety derived from Schiff base reactions, featuring the surfactant‐free stabilization and versatile interface morphology readily adjusted by hydrophobic chain length (C4–C12) of aliphatic amines. Such interface confinement lowers nucleation barriers while the localized monomer enrichment speeds reactions, thus enabling a mild, facile, and controlled synthesis of covalent organic frameworks (COFs) with diverse mesoscopic architectures (spherical/ribbon/sheet). Further introducing colloidal SiO 2 nanospheres on the interfaces can co‐assemble and form stable nanoscale Pickering emulsions, yielding hierarchical porous COFs with tunable, large mesopores (17‐40 nm) beyond the intrinsic pore size limitation. The resulting asymmetric hemispherical hollow mCOF PEA (BET surface area of 561.9 m 2 g −1 ) as a potential iodine host (30.18 wt.% loading) delivered remarkable electrochemical performance with an initial capacity of 202.9 mAh g −1 (96.16% of theoretical value) and retained 132.8 mAh g −1 after 2500 cycles, profited from their mesoporosity and asymmetric morphology with an increased surface area, exposed more active sites and enhanced ion transport ability.
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