吸附
三元运算
材料科学
甲烷
化学工程
多孔性
水溶液
天然气
体积热力学
纳米技术
金属有机骨架
土壤孔隙空间特征
气体分离
多孔介质
极地的
化学稳定性
微型多孔材料
密闭空间
科技与社会
作者
Shaocheng Zhang,Nianqiao Qin,Hengcong Huang,Yifan Gu
出处
期刊:Small
[Wiley]
日期:2026-01-19
卷期号:: e13848-e13848
标识
DOI:10.1002/smll.202513848
摘要
The development of efficient methane (CH4) separation and purification technologies is essential for optimizing the efficiency of natural gas. Compared to conventional cryogenic distillation, adsorptive separation using porous materials offers significant advantages in terms of energy efficiency and operational simplicity. The construction of highly connected cage-like metal-organic frameworks (MOFs) provides suitable pore volume and functional space to enhance both adsorption capacity and selectivity, although their design and synthesis remain challenging. In this work, four MOFs featuring polyhedral cage-like cavities are synthesized via an isoreticular design strategy. Single-component adsorption experiments demonstrate that all prepared MOFs exhibit substantial uptake capacities for C3H8 and C2H6, while showing markedly lower adsorption for CH4. Theoretical calculations and structural analysis elucidate the selective adsorption mechanisms, emphasizing the critical role of appropriate cage dimensions and polar pore surfaces. Breakthrough experiments confirm that the prepared MOFs effectively separate ternary natural gas mixtures (C3H8/C2H6/CH4, 5/10/85, v/v/v) at 298 K, yielding CH4 with a high purity exceeding 99.9%. Furthermore, these MOFs maintain good crystalline stability after 24-hour immersion in aqueous solutions across a pH range of 2-10. The combination of high adsorption capacity, exceptional selectivity, and remarkable stability renders these MOFs highly efficient adsorbents for natural gas upgrading.
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