Designing metal organic framework/ionic liquid composite materials to enhance CH₄/N₂ selectivity via computational and experimental approaches

IF 3.2 3区化学 Q2 CHEMISTRY, INORGANIC & NUCLEAR

Journal of Solid State Chemistry Pub Date : 2024-08-29 DOI:10.1016/j.jssc.2024.124984

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引用次数: 0

Abstract

In this work, we propose a computational and experimental approach to systematically select pyridine-based ionic liquids (IL) and examine their impact on the pore structure of CH₄/N₂ adsorption materials. Our objective is to design novel MIL-53(Al)@IL composites, with MIL-53(Al) as the parent metal organic framework (MOF), for efficient CH₄/N₂ separation. The optimal addition of pyridine-based ionic liquids resulted in the MIL-53(Al)@BH-3 (N-butylpyridinium hydrogen sulfate abbreviated as BH-3) composite, which features an ultramicropore structure and a large specific surface area of 1204 cm² g⁻¹. The MIL-53(Al)@BH-3 composite achieved a high CH₄ capacity of 28.21 cm³(STP) g⁻¹ and a selectivity of 7.7 at 298K and 1 bar in pure-component equilibrium adsorption. In breakthrough experiments, CH₄ breakthrough occurred significantly later than N₂ (approximately 2 min). Therefore, the strategy of manufacturing porous MIL-53(Al)@BH-3 composites effectively enhances the overall adsorption performance for CH₄/N₂ separation.

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通过计算和实验方法设计金属有机框架/离子液体复合材料，提高 CH₄/N₂ 选择性

在这项工作中，我们提出了一种计算和实验方法来系统地选择吡啶基离子液体 (IL)，并研究它们对 CH4/N2 吸附材料孔隙结构的影响。我们的目标是设计新型的 MIL-53(Al)@IL 复合材料，以 MIL-53(Al) 作为母体金属有机框架 (MOF)，实现高效的 CH4/N2 分离。通过优化添加吡啶基离子液体，得到了 MIL-53(Al)@BH-3（N-丁基吡啶硫酸氢盐，简称 BH-3）复合材料，它具有超微孔结构和 1204 cm2 g-1 的大比表面积。在 298K 和 1 bar 条件下，MIL-53(Al)@BH-3 复合材料在纯组分平衡吸附中实现了 28.21 cm³(STP) g-1 的高 CH4 容量和 7.7 的选择性。在突破实验中，CH4 的突破明显晚于 N2（约 2 分钟）。因此，制造多孔 MIL-53(Al)@BH-3复合材料的策略可有效提高 CH4/N2 分离的整体吸附性能。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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来源期刊

Journal of Solid State Chemistry 化学-无机化学与核化学

CiteScore

6.00

自引率

9.10%

发文量

848

审稿时长

25 days

期刊介绍： Covering major developments in the field of solid state chemistry and related areas such as ceramics and amorphous materials, the Journal of Solid State Chemistry features studies of chemical, structural, thermodynamic, electronic, magnetic, and optical properties and processes in solids.