化学
吸附
分子间力
化学物理
氢气储存
疏水效应
蒙特卡罗方法
氢键
分子
灵敏度(控制系统)
氢
分解
化学工程
纳米技术
配体(生物化学)
聚类分析
结晶学
二十面体对称
金属有机骨架
水溶液
衍射
弹性(材料科学)
作者
Mingyu Gu,Radhakrishnan Anbarasan,Ho-Jun Cho,Jinhyuk Choi Jinhyuk Choi,Cheongwon Bae,Duckjong Kim,Sang Yong Nam,Seth M. Cohen,Jae Hyun Park,Juyeong Kim
摘要
Hydrophobic metal–organic frameworks (MOFs) are typically overlooked for ammonia storage due to weak host–guest interactions. Here, we demonstrate that four structurally analogous aluminum-based MOFs exhibit a counterintuitive behavior whereby framework geometry, rather than ligand hydrophilicity, determines high-pressure NH3 adsorption performance. The hydrophobic CAU-23 achieved an exceptional capacity matching hydrophilic analogs despite its poor low-pressure uptake. This pressure-dependent enhancement stems from the unique 4-cis-4-trans geometry of CAU-23 compared to the purely cis arrangement of MIL-160 and KMF-1 and the alternating cis-trans configuration of MOF-303. Critically, CAU-23 retained 95% capacity over three high-pressure cycles, whereas hydrophilic MOFs suffered 39–46% irreversible losses due to strong NH3-framework interactions that compromise structural integrity. Grand canonical Monte Carlo simulations reveal that high pressure enables NH3 clustering through intermolecular hydrogen bonding, bypassing the need for strong host–guest interactions. High-pressure powder X-ray diffraction measurements confirm the exceptional mechanical resilience of CAU-23, showing complete structural recovery upon decompression despite exhibiting the highest pressure sensitivity among the studied MOFs. An extended analog, HE-CAU-23, validates this design principle with further enhanced capacity. These findings reveal a paradigm shift toward hydrophobic MOFs with optimized geometry for high-performance and regenerable gas storage applications.
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