Molecular-level imaging of hydrogen-bonded organic frameworks by cryogenic low-dose electron microscopy

IF 7.6 Q1 ENGINEERING, CHEMICAL

Green Chemical Engineering Pub Date : 2025-06-08 DOI:10.1016/j.gce.2025.06.004

Yikuan Liu , Yanbin Chen , Liwei Xia , Shuo Zhang, Zhangnan Zhong, Liwei Wang, Yujie Huang, Xinru Jiang, Mengru Bu, Qunfeng Zhang, Xiaonian Li, Yihan Zhu

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Abstract

The fundamental problems associated with structural inhomogeneities of hydrogen-bonded organic frameworks (HOFs), such as surface terminations and host-guest heterostructures that govern their functionalities and growth mechanisms, remain a critical gap in knowledge. This arises from the lack of advanced real-space structural characterization tools with molecular precision. By leveraging state-of-the-art cryogenic low-dose electron microscopy, this work overcomes the beam damage limitations of traditional techniques and elucidates the crystal structures, surface terminations, and host-guest structures of HOFs at molecular-level. Real-space observations confirm lateral crystal growth consistent with the terrace-ledge-kink (TLK) model, but deviate from the classical monomer-addition mechanism. Instead, we propose a nonclassical cooperative multisite monomer-addition mechanism, where simultaneous monomer addition at both framework and guest sites eventually drives crystal faceting.

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低温低剂量电子显微镜下氢键有机框架的分子水平成像

与氢键有机框架（HOFs）结构不均质性相关的基本问题，如控制其功能和生长机制的表面末端和主客体异质结构，仍然是一个关键的知识缺口。这源于缺乏先进的具有分子精度的实空间结构表征工具。通过利用最先进的低温低剂量电子显微镜，这项工作克服了传统技术的光束损伤限制，并在分子水平上阐明了hof的晶体结构、表面末端和主客体结构。实空间观测证实了横向晶体生长符合梯田-边缘-扭结（TLK）模型，但偏离了经典的单体加成机制。相反，我们提出了一种非经典的合作多位点单体添加机制，其中在框架和客体位点同时添加单体最终驱动晶体饰面。

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