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引用次数: 0
摘要
金属有机框架(MOF)材料疏水微孔中的水分子在吸附平衡中表现出不同的行为。从在低相对压力下发生的大量 V 型吸附行为,到几乎不吸附水的 III 型平衡,这种现象给先验预测带来了挑战。为了阐明吸附机制,本研究通过伊辛模型分析(IMA)的新颖应用,推进了对疏水性的定量描述。它被用于仔细研究由 III 型吸附所显示的疏水性,以及因微孔过大而导致 V 型水吸附平衡所显示的疏水性。确定了两类疏水性,并将其分为结构疏水性和表面疏水性。此外,通过分析 25 种材料的数据集,确定了纳米毛细管和纳米润湿概念在改良开尔文分析 (MKA) 中对 MOF 系统中水的实用性。该方法和分析适用于 MOF 微孔中的这些现象,可帮助进行筛选研究,用于评估合作、润湿和类似凝结机制的存在,并可进一步用于评估其他微孔材料的疏水性。
Analysis of Hydrophobicity in Micropores of Metal-Organic Framework Materials
Water molecules in hydrophobic micropores of Metal Organic Framework (MOF) materials show disparate behavior in adsorption equilibrium. Ranging from behavior indicative of large, Type V uptakes occurring at low relative pressure, to Type III equilibrium where little water is adsorbed, this phenomenon provides a challenge for a priori prediction. In an effort to elucidate adsorption mechanisms, this study advances a quantitative description of hydrophobicity through novel application of Ising model analysis (IMA). It is applied to scrutinize hydrophobicity indicated by Type III adsorption and displayed by micropores that are too large to induce a Type V water adsorption equilibrium. Two types of hydrophobicity are identified and partitioned into structural hydrophobicity and surface hydrophobicity. Additionally, through analysis of a data set for 25 materials, the utility of the concepts of nanocapillarity and nanowetting in a modified Kelvin analysis (MKA) are established for water in MOF systems. The method and analysis are applied to these phenomena in MOF micropores and could foreseeably aid in screening studies, be used to assess the presence of cooperative, wetting, and condensation-like mechanisms and be further employed to assess hydrophobicity in other microporous materials.
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