Accurate Evaluation of the Dispersion Energy in the Simulation of Gas Adsorption into Porous Zeolites

Alberto Fraccarollo, Lorenzo Canti, Leonardo Marchese, Maurizio Cossi

Risultato della ricerca: Contributo su rivistaArticolo in rivistapeer review

Abstract

The force fields used to simulate the gas adsorption in porous materials are strongly dominated by the van der Waals (vdW) terms. Here we discuss the delicate problem to estimate these terms accurately, analyzing the effect of different models. To this end, we simulated the physisorption of CH4, CO2, and Ar into various Al-free microporous zeolites (ITQ-29, SSZ-13, and silicalite-1), comparing the theoretical results with accurate experimental isotherms. The vdW terms in the force fields were parametrized against the free gas densities and high-level quantum mechanical (QM) calculations, comparing different methods to evaluate the dispersion energies. In particular, MP2 and DFT with semiempirical corrections, with suitable basis sets, were chosen to approximate the best QM calculations; either Lennard-Jones or Morse expressions were used to include the vdW terms in the force fields. The comparison of the simulated and experimental isotherms revealed that a strong interplay exists between the definition of the dispersion energies and the functional form used in the force field; these results are fairly general and reproducible, at least for the systems considered here. On this basis, the reliability of different models can be discussed, and a recipe can be provided to obtain accurate simulated adsorption isotherms. © 2017 American Chemical Society.
Lingua originaleInglese
pagine (da-a)1756-1768
Numero di pagine13
RivistaJournal of Chemical Theory and Computation
Volume13
Numero di pubblicazione4
DOI
Stato di pubblicazionePubblicato - 11 apr 2017

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