Journal of Liaoning Petrochemical University
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Study on Mechanism of Thiophene Alkylation Reaction on Hβ Zeolites by In⁃Situ Infrared Spectroscopy
Xiangbo Sun, Yu Hui, Jingwei Zhang, Zhiying Li, Yucai Qin, Lijuan Song
Abstract222)   HTML13)    PDF (2974KB)(315)      

The adsorption competitive adsorption and conversion behaviors of thiophene and 1?hexene on Hβ molecular sieve have been studied by using the method of in?situ infrared spectroscopyThe roles of different acidic sites in the alkylation reaction of thiophene and olefin molecule were systematically discussed. The results show that 1?hexene is preferentially adsorbed on the B acid sites, and it s easy to dimerize through protonation activation. Thus,there is a significant competitive relationship between the adsorption of thiophene molecules and the protonation reaction process. Moreover, it can be confirmed that the adsorbed thiophene molecule on non?framework aluminum on zeolite are more likely to its alkylation with a protonation 1?hexene molecule near the center of the B acidThis results can provide basic theoretical guidance for the development of zeolite catalysts for alkylation desulfurization processes.

2023, 43 (4): 66-71. DOI: 10.12422/j.issn.1672-6952.2023.04.010
Grand Canonical Monte Carlo Simulation of Adsorption and Separation Performances of CO 2/CH 4 by NaX Zeolite
Jing Zhao, Tianyi Liu, Qiang Li, Xiaoxin Zhang, Yucai Qin, Lijuan Song
Abstract381)   HTML11)    PDF (2432KB)(464)      

In this paper, the method of combining Grand Canonical Monte Carlo simulation and Ideal Adsorption Solution Theory was used to study the adsorption performance of CO2 and CH4 on NaX zeolite. By comparing the fitting results of simulation data under different adsorption theoretical models and calculating the adsorption heat, a description of the adsorption and separation process of CO2 and CH4 gas was obtained. The results show that the adsorption strength of CH4 molecules is weaker than that of CO2 molecules, and its adsorption is closer to the ideal adsorption. The adsorption selectivity of CO2 molecules is decreases with the increase of its content in the air, and decreases with the increase of temperature under low pressure conditions. Therefore, low temperature and low pressure are more conducive to the separation of CO2 molecules.

2023, 43 (2): 13-19. DOI: 10.12422/j.issn.1672-6952.2023.02.003