Quantum chemical simulation of hydrogen adsorption in pores: A study by DFT, SAPT0 and IGM methods

I. K. Petrushenko
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引用次数: 2

Abstract

Hydrogen as a versatile energy carrier continues to attract research attention in the field of applied chemistry. One of the fundamental issues on the way to hydrogen economy is the difficulty of hydrogen storage. Physical adsorption of hydrogen in pores is a feasible and effective method of hydrogen storage. Among existing hydrogen-adsorbing materials, carbon nanostructures possess a number of advantages due to their high adsorption capacity, significant strength and low weight. In this work, we use the modern methods of quantum chemistry (DFT, SAPT0 and IGM) to study the adsorption of molecular hydrogen in a series of simulated slit-like carbon micropores with a distance between the walls of d = 4–10 Å, including the introduction of an H2 molecule into a pore, filling pores with these molecules and investigating the interactions between H2 molecules inside the pores. It was found that, depending on the value of parameter d, adsorbed hydrogen molecules form one (d = 6, 7 Å) or two layers (d = 8, 9, 10 Å) inside the pore. At the same time, for pores with small d values, high potential barriers to the introduction of H2 into a pore were observed. The decomposition of the interaction energy into components showed dispersion interactions to make a major contribution to the energy of attraction (72–82%). Moreover, an increase in the number of H2 molecules adsorbed in the pore decreases the significance of dispersion interactions (up to 61%) and increases the contribution of electrostatic and induction interactions to intermolecular attraction. Gravimetric density (GD) values were determined for pores with d = 6, 7, 8, 9, 10 Å, comprising 1.98, 2.30, 2.93, 3.25 and 4.49 wt%, respectively. It is assumed that the revealed peculiarities of hydrogen adsorption in pores will contribute to the use of carbon porous structures as a medium for hydrogen storage.
孔隙中氢吸附的量子化学模拟:基于DFT、SAPT0和IGM方法的研究
氢作为一种多功能的能量载体,在应用化学领域不断受到研究的关注。氢经济的根本问题之一是氢的储存困难。孔隙中氢的物理吸附是一种可行有效的储氢方法。在现有的吸氢材料中,碳纳米结构具有吸附量大、强度大、重量轻等优点。在这项工作中,我们使用现代量子化学方法(DFT, SAPT0和IGM)研究了分子氢在一系列模拟的狭缝状碳微孔中的吸附,其壁距为d = 4-10 Å,包括将H2分子引入孔中,用这些分子填充孔以及研究孔内H2分子之间的相互作用。结果发现,根据参数d的取值,吸附的氢分子在孔内形成一层(d = 6,7 Å)或两层(d = 8,9,10 Å)。同时,对于d值较小的孔隙,H2进入孔隙的势垒较高。相互作用能的分解表明,色散相互作用对吸引能的贡献最大(72-82%)。此外,孔隙中吸附H2分子数量的增加降低了分散相互作用的重要性(高达61%),并增加了静电和感应相互作用对分子间吸引力的贡献。测定了d = 6、7、8、9、10 Å孔隙的重量密度(GD)值,分别为1.98、2.30、2.93、3.25和4.49 wt%。人们认为,氢在孔隙中的吸附特性将有助于碳多孔结构作为储氢介质的使用。
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