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Abstract
The adsorption of solutes from a dilute liquid solution is of great technical importance but calculations of the local density of the solute and of the adsorption isotherm by standard molecular simulation yield large scattering with increasing dilution. As alternative the mean force (MF) method was suggested where the MF on a constrained solute molecule is integrated over a path from the bulk fluid to the wall. It has already been shown that the MF method gives reliable results for the relative local density, even at high dilution. Here, an extension of this method is introduced, where the absolute value of the bulk density is determined by particle balance. Thus, it is possible to calculate adsorption isotherms from the Henry regime to any finite concentration. Molecular dynamics simulations for the local density and the adsorption isotherm were performed for a model solution consisting of tetrahedral Lennard–Jones (LJ) solvent and linear LJ solute molecules in contact with a plane wall. It is found that the MF-results show less scattering than the results from standard simulations. Moreover, results for the orientation and the selectivity are given.
Acknowledgements
Financial support by Deutsche Forschungsgemeinschaft for the project “Adsorption aus wässrigen Lösungen”, Az Fi 287/13–2, within the priority research programme “Molekulare Modellierung und Simulation in der Verfahrenstechnik” is gratefully acknowledged (R.T. and L.S.). The MACSIMUS development has been supported by the The Ministry of Education, Youth and Sports of the Czech Republic under the project LC512 (Center for Biomolecules and Complex Molecular Systems). Moreover, we thank the John von Neumann Institute für Computing, Jülich, Germany, for allocation of computer time at JUMP, project ID hvi020.
Notes
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