从分子水平洞察封闭在 MXene 膜中的离子液体分离 CO2/CH4 的过程

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摘要

在 MXene 中加入离子液体(ILs)的复合膜具有分离二氧化碳的巨大潜力。然而,利用 MXene 封闭 ILs 膜分离 CO2/CH4 的研究还很有限,尤其是在了解分子水平的机制方面。本研究通过分子动力学模拟研究了 MXene 封闭 ILs 膜中 CO2/CH4 的体系。数密度结果表明,MXene 将层间的 IL 分层,靠近 MXene 的层间 IL 浓度较高,而中间层的浓度较低。值得注意的是,与阴离子相比,MXene 对阳离子分布的影响更大。随着 MXene 的层间距从 1.5 纳米扩大到 3 纳米,MXene 和 IL 之间的相互作用减弱,而阳离子和阴离子之间的相互作用增强。封闭的绝缘层增强了气体溶解能力,但阻碍了气体扩散。二氧化碳更靠近阴离子,而 CH4 则更靠近阳离子,CH4 与阳离子之间的距离随着层间距的增加而减小。此外,随着层间距的增大,封闭的 IL 所占比例逐渐减小,气体扩散系数逐渐增大。此外,与 1-乙基-3-甲基咪唑鎓四氟硼酸盐([EMIM][BF4])和 1-乙基-3-甲基咪唑鎓六氟磷酸盐([EMIM][PF6])相比、由于 1-乙基-3-甲基咪唑鎓双(三氟甲基磺酰基)亚胺([EMIM][TF2N])具有优异的二氧化碳溶解性和最高的扩散选择性,因此被认为是最有效的二氧化碳/四氯化碳分离剂。
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Insight into CO2/CH4 separation by ionic liquids confined in MXene membrane from molecular level

Composite membranes incorporating ionic liquids (ILs) within MXene demonstrate promising potential for CO2 separation. However, studies on the separation of CO2/CH4 using MXene-confined ILs membranes are limited, especially in terms of understanding the mechanisms at the molecular level. In this work, the system of CO2/CH4 in MXene-confined ILs membranes was studied by molecular dynamic simulations. The number density results reveal that MXene stratifies the ILs between the layers, with higher concentrations of ILs near MXene and lower concentrations in the middle layer. Notably, MXene has a greater impact on cations distribution compared to anions. As the layer spacing of MXene expands from 1.5 to 3 nm, the interaction between MXene and IL weakens, while that between the cations and anions strengthens. The confined ILs enhance gas solubility capability but impede gas diffusion. CO2 is distributed closer to anions, while CH4 tends to be closer to cations, with the distance between CH4 and cations decreasing as the layer spacing increases. Additionally, with the increase of layer distance, the proportion of confined ILs gradually decreases, and the gas diffusion coefficient gradually increases. Furthermore, compared to 1-Ethyl-3-methylimidazolium tetrafluoroborate ([EMIM][BF4]) and 1-Ethyl-3-methylimidazolium hexafluorophosphate ([EMIM][PF6]), MXene-confined 1-Ethyl-3-methylimidazolium bis(trifluoromethylsulfonyl)imide ([EMIM][TF2N]) is identified as the most effective for CO2/CH4 separation, owing to its superior CO2 solubility and highest diffusion selectivity.

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