Unraveling the relationship between microstructure of CMS membrane and gas transport property using molecular simulation

IF 3.5 3区 工程技术 Q2 ENGINEERING, CHEMICAL
AIChE Journal Pub Date : 2024-08-07 DOI:10.1002/aic.18561
Mengjie Hou, Lin Li, Ruisong Xu, Zilong He, Yunhua Lu, Tonghua Wang, Xigao Jian
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Abstract

Carbon molecular sieve (CMS) membranes are attractive for energy-efficient gas separations. A challenge with the fabrication of a high-performance CMS membrane is fine-tuning its microstructure for precise and efficient separation. This necessitates a molecular-scale analysis to understand its microstructure–performance relationship. Herein, molecular simulations were performed to unravel the relationships between four similar-sized CMS matrices with different microstructural characteristics (e.g., chemical composition and micromorphology) and their gas transport properties. Results show that the disordered packing of carbon layers, leading to the formation of ultramicropore (2–7 Å), originates from stereoscopic sp3 hybridized carbon atoms rather than non-carbon (oxygen) atoms. The size-sieving ability of CMS depends positively on ultramicroporosity; the adsorption capacity is strengthened and then weakened with the increase of ultramicroporosity. Competitive effects are observed in binary-mixture transport, and it is expected that the separation performance can be optimized by a reasonable distribution of ultramicropores combined with the affinity of oxygen-containing species.

利用分子模拟揭示 CMS 膜微观结构与气体传输特性之间的关系
碳分子筛(CMS)膜对高能效气体分离具有吸引力。制造高性能 CMS 膜的一个挑战是微调其微观结构,以实现精确高效的分离。这就需要进行分子尺度的分析,以了解其微观结构与性能之间的关系。在此,我们进行了分子模拟,以揭示具有不同微观结构特征(如化学成分和微观形态)的四种类似大小的 CMS 基质与其气体传输性能之间的关系。结果表明,碳层的无序堆积导致了超微孔(2-7 Å)的形成,这种堆积源于立体sp3杂化碳原子而非非碳原子(氧原子)。CMS 的尺寸筛分能力与超微孔呈正相关;随着超微孔的增加,吸附能力先增强后减弱。在二元混合物传输过程中观察到了竞争效应,预计通过合理的超微孔分布结合含氧物种的亲和力,可以优化分离性能。
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来源期刊
AIChE Journal
AIChE Journal 工程技术-工程:化工
CiteScore
7.10
自引率
10.80%
发文量
411
审稿时长
3.6 months
期刊介绍: The AIChE Journal is the premier research monthly in chemical engineering and related fields. This peer-reviewed and broad-based journal reports on the most important and latest technological advances in core areas of chemical engineering as well as in other relevant engineering disciplines. To keep abreast with the progressive outlook of the profession, the Journal has been expanding the scope of its editorial contents to include such fast developing areas as biotechnology, electrochemical engineering, and environmental engineering. The AIChE Journal is indeed the global communications vehicle for the world-renowned researchers to exchange top-notch research findings with one another. Subscribing to the AIChE Journal is like having immediate access to nine topical journals in the field. Articles are categorized according to the following topical areas: Biomolecular Engineering, Bioengineering, Biochemicals, Biofuels, and Food Inorganic Materials: Synthesis and Processing Particle Technology and Fluidization Process Systems Engineering Reaction Engineering, Kinetics and Catalysis Separations: Materials, Devices and Processes Soft Materials: Synthesis, Processing and Products Thermodynamics and Molecular-Scale Phenomena Transport Phenomena and Fluid Mechanics.
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