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Main Authors: Tara, Huang, Petek, Evon S., Katsumata, Reika
Format: Preprint
Published: 2025
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Online Access:https://arxiv.org/abs/2506.03387
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author Tara
Huang
Petek, Evon S.
Katsumata, Reika
author_facet Tara
Huang
Petek, Evon S.
Katsumata, Reika
contents Although wettability is a macroscopic manifestation of molecular-level forces, such as van der Waals (vdW) forces, the impact of nanoconfinement on material properties in reduced film thickness remains unexplored in predicting film stability. In this work, we investigate how nanoconfinement influences intermolecular interactions using a model trilayer system composed of a thick polystyrene (PS) base, a poly(methyl methacrylate) (PMMA) middle layer with tunable thickness (15-95 nm), and a 10 nm top PS film. We find that the dewetting behavior of the top PS layer is highly sensitive to middle PMMA thickness, deviating from classical vdW-based predictions that assume bulk material properties. By incorporating nanoconfinement-induced changes in PMMA refractive index into the calculation of the Hamaker constant, we present a modified theoretical framework that successfully captures the observed behavior. This study links dewetting behavior and material property change as a function of underlayer thickness, providing direct evidence that nanoconfinement in soft matter systems significantly influences long-range intermolecular interactions. We show that film stability can be tuned solely by adjusting underlying layer thickness, while preserving both chemistry and thickness of top functional film. This finding carries broad implications for thin-film technologies across scientific and engineering disciplines by enabling performance-targeted interface design.
format Preprint
id arxiv_https___arxiv_org_abs_2506_03387
institution arXiv
publishDate 2025
record_format arxiv
spellingShingle Nanoconfinement Effects on Intermolecular Forces Observed via Dewetting
Tara
Huang
Petek, Evon S.
Katsumata, Reika
Soft Condensed Matter
Although wettability is a macroscopic manifestation of molecular-level forces, such as van der Waals (vdW) forces, the impact of nanoconfinement on material properties in reduced film thickness remains unexplored in predicting film stability. In this work, we investigate how nanoconfinement influences intermolecular interactions using a model trilayer system composed of a thick polystyrene (PS) base, a poly(methyl methacrylate) (PMMA) middle layer with tunable thickness (15-95 nm), and a 10 nm top PS film. We find that the dewetting behavior of the top PS layer is highly sensitive to middle PMMA thickness, deviating from classical vdW-based predictions that assume bulk material properties. By incorporating nanoconfinement-induced changes in PMMA refractive index into the calculation of the Hamaker constant, we present a modified theoretical framework that successfully captures the observed behavior. This study links dewetting behavior and material property change as a function of underlayer thickness, providing direct evidence that nanoconfinement in soft matter systems significantly influences long-range intermolecular interactions. We show that film stability can be tuned solely by adjusting underlying layer thickness, while preserving both chemistry and thickness of top functional film. This finding carries broad implications for thin-film technologies across scientific and engineering disciplines by enabling performance-targeted interface design.
title Nanoconfinement Effects on Intermolecular Forces Observed via Dewetting
topic Soft Condensed Matter
url https://arxiv.org/abs/2506.03387