Analysis of Guest Adsorption on Crystal Surfaces Based on the Fragment Molecular Orbital Method

Taiji Nakamura; Tomoko Yokaichiya; Dmitri G. Fedorov

doi:10.1021/acs.jpca.1c10229

Analysis of Guest Adsorption on Crystal Surfaces Based on the Fragment Molecular Orbital Method

Taiji Nakamura, Tomoko Yokaichiya, Dmitri G. Fedorov

Research output: Contribution to journal › Article › peer-review

3 Citations (Scopus)

Abstract

For gaining insights into interactions in periodic systems, an analysis is developed based on the fragment molecular orbital method combined with periodic boundary conditions. The adsorption energy is decomposed into guest and surface polarization and deformation energy, guest-surface and guest-guest interactions, and the vibrational free energy. The analysis is applied to the adsorption of guest molecules to Ih (001) ice surface. The cooperativity effects result in a non-linear change in the adsorption energy with coverage due to many-body effects. The role of dispersion is found to be dominant for guests with long hydrophobic tails. A rule is proposed relating the length of the alkyl tail with the formation of the guest layer. The computed binding enthalpies are in good agreement with experimental values. For high coverage, adsorbed molecules can form an ordered layer known as self-assembled monolayer.

Original language	English
Pages (from-to)	957-969
Number of pages	13
Journal	Journal of Physical Chemistry A
Volume	126
Issue number	6
DOIs	https://doi.org/10.1021/acs.jpca.1c10229
Publication status	Published - Feb 17 2022
Externally published	Yes

All Science Journal Classification (ASJC) codes

Physical and Theoretical Chemistry

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10.1021/acs.jpca.1c10229

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title = "Analysis of Guest Adsorption on Crystal Surfaces Based on the Fragment Molecular Orbital Method",

abstract = "For gaining insights into interactions in periodic systems, an analysis is developed based on the fragment molecular orbital method combined with periodic boundary conditions. The adsorption energy is decomposed into guest and surface polarization and deformation energy, guest-surface and guest-guest interactions, and the vibrational free energy. The analysis is applied to the adsorption of guest molecules to Ih (001) ice surface. The cooperativity effects result in a non-linear change in the adsorption energy with coverage due to many-body effects. The role of dispersion is found to be dominant for guests with long hydrophobic tails. A rule is proposed relating the length of the alkyl tail with the formation of the guest layer. The computed binding enthalpies are in good agreement with experimental values. For high coverage, adsorbed molecules can form an ordered layer known as self-assembled monolayer.",

author = "Taiji Nakamura and Tomoko Yokaichiya and Fedorov, {Dmitri G.}",

note = "Funding Information: The financial support by JSPS KAKENHI (grant number 19H02682) is gratefully acknowledged. Publisher Copyright: {\textcopyright} 2022 American Chemical Society",

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doi = "10.1021/acs.jpca.1c10229",

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T1 - Analysis of Guest Adsorption on Crystal Surfaces Based on the Fragment Molecular Orbital Method

AU - Nakamura, Taiji

AU - Yokaichiya, Tomoko

AU - Fedorov, Dmitri G.

PY - 2022/2/17

Y1 - 2022/2/17

N2 - For gaining insights into interactions in periodic systems, an analysis is developed based on the fragment molecular orbital method combined with periodic boundary conditions. The adsorption energy is decomposed into guest and surface polarization and deformation energy, guest-surface and guest-guest interactions, and the vibrational free energy. The analysis is applied to the adsorption of guest molecules to Ih (001) ice surface. The cooperativity effects result in a non-linear change in the adsorption energy with coverage due to many-body effects. The role of dispersion is found to be dominant for guests with long hydrophobic tails. A rule is proposed relating the length of the alkyl tail with the formation of the guest layer. The computed binding enthalpies are in good agreement with experimental values. For high coverage, adsorbed molecules can form an ordered layer known as self-assembled monolayer.

AB - For gaining insights into interactions in periodic systems, an analysis is developed based on the fragment molecular orbital method combined with periodic boundary conditions. The adsorption energy is decomposed into guest and surface polarization and deformation energy, guest-surface and guest-guest interactions, and the vibrational free energy. The analysis is applied to the adsorption of guest molecules to Ih (001) ice surface. The cooperativity effects result in a non-linear change in the adsorption energy with coverage due to many-body effects. The role of dispersion is found to be dominant for guests with long hydrophobic tails. A rule is proposed relating the length of the alkyl tail with the formation of the guest layer. The computed binding enthalpies are in good agreement with experimental values. For high coverage, adsorbed molecules can form an ordered layer known as self-assembled monolayer.

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Analysis of Guest Adsorption on Crystal Surfaces Based on the Fragment Molecular Orbital Method

Abstract

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