Harnessing Pore Size in COF Membranes: A Concentration Gradient-Driven Molecular Dynamics Study on Enhanced H2/CH4 Separation

IF 8.2 2区材料科学 Q1 MATERIALS SCIENCE, MULTIDISCIPLINARY

ACS Applied Materials & Interfaces Pub Date : 2025-03-01 DOI:10.1021/acsami.4c20420

Parivash Jamshidi Ghaleh, Zeynep Pinar Haslak, Merdan Batyrow, Ilknur Erucar

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Abstract

This work presents a novel approach for accurately predicting the gas transport properties of covalent organic framework (COF) membranes using a nonequilibrium molecular dynamics (NEMD) methodology called concentration gradient-driven molecular dynamics (CGD-MD). We first simulated the flux of hydrogen (H₂) and methane (CH₄) across two distinct COF membranes, COF-300 and COF-320, for which experimental data are available in the literature. Our CGD-MD simulation results aligned closely with the experimentally measured gas permeability and selectivity of these COF membranes. Leveraging the same methodology, we discovered promising COF candidates for H₂/CH₄ separation, including NPN-1, NPN-2, NPN-3, TPE-COF-I, COF-303, DMTA-TPB2, 3D-Por-COF, COF-921, COF-IM AA, TfpBDH, and PCOF-2. We then compared our findings with simulations utilizing the well-known approach that merges grand canonical Monte Carlo (GCMC) and equilibrium molecular dynamics (EMD) to predict gas adsorption and diffusion parameters in COFs. Our results showed that when the pore sizes of COF membranes are below 10 Å, the choice of the method plays a significant role in determining the performance of the membranes. The GCMC+EMD approach suggested that COFs tend to exhibit CH₄ selectivity when their pore limiting diameters are below 10 Å, whereas the CGD-MD results reveal a preference for H₂. Density functional theory calculations indicate that H₂ has a lower affinity for three promising COFs, NPN-1, NPN-2, and NPN-3, compared to CH₄, which results in H₂ remaining unbound, while CH₄ occupies all of the adsorption sites, thereby facilitating the selective recovery of H₂ at the end of the separation process. We proposed a relationship between adsorption time and diffusion time, highlighting the critical role of selecting an appropriate simulation method. This relationship underscores how adsorption and diffusion processes interplay, impacting material performance. Overall, these insights not only improve the accuracy of predictive models but also guide the development of more efficient COF-based membrane applications for future research and industrial applications.

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利用 COF 膜的孔径：关于增强 H2/CH4 分离的浓度梯度驱动分子动力学研究

本研究提出了一种利用浓度梯度驱动分子动力学（CGD-MD）的非平衡分子动力学（NEMD）方法准确预测共价有机框架（COF）膜的气体输运特性的新方法。我们首先模拟了氢（H2）和甲烷（CH4）通过两种不同的COF膜（COF-300和COF-320）的通量，这两种膜的实验数据可在文献中获得。我们的CGD-MD模拟结果与实验测量的COF膜的透气性和选择性非常接近。利用同样的方法，我们发现了有希望用于H2/CH4分离的候选COF，包括NPN-1、NPN-2、NPN-3、tpe -COF- 1、COF-303、dta - tpb2、3D-Por-COF、COF-921、COF- im AA、TfpBDH和PCOF-2。然后，我们将我们的发现与利用众所周知的方法（结合了大正则蒙特卡罗（GCMC）和平衡分子动力学（EMD）来预测COFs中气体吸附和扩散参数的方法）的模拟进行了比较。我们的研究结果表明，当COF膜的孔径小于10 Å时，方法的选择对膜的性能起着重要的作用。GCMC+EMD方法表明，当孔极限直径小于10 Å时，COFs倾向于表现出对CH4的选择性，而CGD-MD结果则显示出对H2的选择性。密度功能理论计算表明，与CH4相比，H2对NPN-1、NPN-2和NPN-3三种有前途的COFs具有较低的亲和力，导致H2保持未结合状态，而CH4占据了所有的吸附位点，从而有利于H2在分离过程结束时的选择性回收。我们提出了吸附时间和扩散时间之间的关系，强调了选择合适的模拟方法的关键作用。这种关系强调了吸附和扩散过程如何相互作用，影响材料性能。总的来说，这些见解不仅提高了预测模型的准确性，而且还指导了未来研究和工业应用中更高效的cof基膜应用的发展。

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

ACS Applied Materials & Interfaces 工程技术-材料科学：综合

CiteScore

16.00

自引率

6.30%

发文量

4978

审稿时长

1.8 months

期刊介绍： ACS Applied Materials & Interfaces is a leading interdisciplinary journal that brings together chemists, engineers, physicists, and biologists to explore the development and utilization of newly-discovered materials and interfacial processes for specific applications. Our journal has experienced remarkable growth since its establishment in 2009, both in terms of the number of articles published and the impact of the research showcased. We are proud to foster a truly global community, with the majority of published articles originating from outside the United States, reflecting the rapid growth of applied research worldwide.