Two‐dimensional ammonia‐linked COF structures with different substituents for the adsorption and separation of sulfur hexafluoride: A theoretical study

Author:

Shen Kun1,Ning Junjie1,Zhao Rui2ORCID,Gao Kunqi3,Yin Xiangyu1,Hou Linxi124

Affiliation:

1. Department of Materials‐Oriented Chemical Engineering, College of Chemical Engineering Fuzhou University Fuzhou People's Republic of China

2. Departmente of Electronic Chemicals Qingyuan Innovation Laboratory Quanzhou People's Republic of China

3. School of Science, College of Art and Science Shanghai Polytechnic University Shanghai People's Republic of China

4. Fujian Key Laboratory of Advanced Manufacturing Technology of Specialty Chemicals Fuzhou University Fuzhou People's Republic of China

Abstract

AbstractAs one of the most potent greenhouse gases, SF6 has a significant economic and environmental impact on the purification and recovery of exhaust gases from the semiconductor industry. The adsorption and separation performance of SF6 on a two‐dimensional covalent organic framework TAT‐COFs‐1‐AB with different functional groups (SO3H, Et, NH2, OMe, OH, H) was investigated by using grand canonical Monte Carlo (GCMC) simulations and density functional theory (DFT) calculations. The results show that the adsorption at low pressure depends on the interactions between the SF6 and COF frameworks, while at high pressure it is mainly affected by the porosity. The highest adsorption capacity of 8.44 mmol/g (298 K, 100 kPa) is exhibited by TAT‐COF‐1‐AB‐H, which has the highest porosity. Chemical functionalization was found to be effective in enhancing the SF6/N2 selectivity. Among all the functionalized COFs, TAT‐COF‐1‐AB‐NH2, with the highest specific surface area and strong heat of adsorption, showed the highest selectivity. The simulation of self‐diffusion also shows consistent results with the GCMC simulation. The findings highlight that the adsorption capacity is influenced by substituent and porosity, with SF6 showing a consistent preference for adsorption at hollow sites, as evidenced by binding energy and charge transfer analyses.

Publisher

Wiley

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