The existence of a strongly bonded layer in associating liquids within silica pores - a spectral and molecular dynamics study

The existence of a strongly bonded layer in associating liquids within silica pores - a spectral and molecular dynamics study

The properties of confined materials are assumed to be governed by the phenomena occurring at the interface, especially the formation of an irreversible adsorption layer (IAL), which has been widely discussed and detected in the case of thin polymer films and silica nanoparticles. In this paper, we...

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Veröffentlicht in:Nanoscale 2024-03, Vol.16 (13), p.6636-6647
Hauptverfasser: Soszka, Natalia, Tarnacka, Magdalena, Hachu a, Barbara, W odarczyk, Patryk, Wrzalik, Roman, Hreczka, Marek, Paluch, Marian, Kami ski, Kamil
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Sprache:eng
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Alcohol
Alcohols
Bonding strength
Clustering
Hydrogen bonds
Infrared spectra
Molecular dynamics
Nanoparticles
Polymer films
Silicon dioxide
Simulation
Thin films
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container_end_page 6647
container_issue 13
container_start_page 6636
container_title Nanoscale
container_volume 16
creator Soszka, Natalia
Tarnacka, Magdalena
Hachu a, Barbara
W odarczyk, Patryk
Wrzalik, Roman
Hreczka, Marek
Paluch, Marian
Kami ski, Kamil
description The properties of confined materials are assumed to be governed by the phenomena occurring at the interface, especially the formation of an irreversible adsorption layer (IAL), which has been widely discussed and detected in the case of thin polymer films and silica nanoparticles. In this paper, we present a novel experimental approach allowing us to reveal the formation of an IAL in two phenyl alcohols infiltrated into various mesoporous silica templates. The proposed methodology (based on evaporation) allowed us to detect the alterations in the OH and aromatic CH stretching vibration bands in infrared spectra, which were considered as evidence of the existence of IAL in constrained systems. Such interpretation was also confirmed by complementary molecular dynamics (MD) simulations that indicated the creation of much stronger hydrogen bonds between alcohols and silanol units than between alcohols themselves. Moreover, computation allowed us to identify additional enormously strong π-stacking interactions between phenyl rings stabilizing the interfacial layer. MD simulations also shed new light on the clustering process of both alcohols under confinement. Simulation and experimental data presented in this paper allowed a much deeper understanding of the processes occurring at the interface-formation of IAL and the association phenomenon at the nanoscale level. In this paper, we present a novel experimental approach allowing us to reveal the formation of an irreversible adsorption layer in two phenyl alcohols infiltrated into mesoporous silica templates.
doi_str_mv 10.1039/d3nr06187f
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source Royal Society Of Chemistry Journals 2008-
subjects Alcohol
Alcohols
Bonding strength
Clustering
Hydrogen bonds
Infrared spectra
Molecular dynamics
Nanoparticles
Polymer films
Silicon dioxide
Simulation
Thin films
title The existence of a strongly bonded layer in associating liquids within silica pores - a spectral and molecular dynamics study
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