A Computational Study of the Adsorptive Separation of Methane and Hydrogen in Zeolite Templated Carbons

Gazi University Journal of Science Part A: Engineering and Innovation Pub Date : 2022-12-31 DOI:10.54287/gujsa.1205356

C. U. Deniz

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Abstract

Combustion of conventional energy sources produces pollutants such as SOx, NOx, and CO; the use of hydrogen and methane can eliminate these harmful emissions. In fuel cell technology and other uses, hydrogen must be refined by extracting methane from the methane/hydrogen combination, produced via dry or steam reforming. This study investigates the adsorption and separation capabilities of recently discovered zeolite-templated carbons (ZTCs) for binary mixtures consisting of hydrogen and methane. To assess the adsorption and separation performances of these carbon-based nanostructures, grand canonical Monte Carlo (GCMC) simulations were used. The simulation results revealed that AFY (|(C6H15N)3(H2O)7|[Co3Al5P8O32]) and RWY (|(C6H18N4)16| [Ga32Ge16S96]) structures could be viable alternatives for applications involving adsorptive gas separation based on selectivity and the CH4 uptake capacity. The selectivity of AFY was calculated to be 176, while its capacity to uptake CH4 was found to be 2.57 mmol/g, the selectivity of RWY was calculated to be 132, and its CH4 uptake was 3.49 mmol/g.

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沸石模板炭吸附分离甲烷和氢的计算研究

传统能源的燃烧会产生SOx、NOx和CO等污染物;使用氢气和甲烷可以消除这些有害排放物。在燃料电池技术和其他应用中，必须通过干燥或蒸汽重整产生的甲烷/氢混合物中提取甲烷来精炼氢。本文研究了新发现的沸石模板碳(ztc)对氢和甲烷二元混合物的吸附和分离能力。为了评估这些碳基纳米结构的吸附和分离性能，使用了大正则蒙特卡罗(GCMC)模拟。模拟结果表明，基于选择性和CH4吸收能力，AFY (|(C6H15N)3(H2O)7|[Co3Al5P8O32])和RWY (|(C6H18N4)16| [Ga32Ge16S96])结构可以作为吸附气体分离应用的可行选择。AFY的选择性为176，对CH4的吸收率为2.57 mmol/g; RWY的选择性为132，对CH4的吸收率为3.49 mmol/g。

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Gazi University Journal of Science Part A: Engineering and Innovation

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