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Main Authors: Cammarata, María del Mar, Negri, R. Martín, Semino, Rocio
Format: Preprint
Published: 2025
Subjects:
Online Access:https://arxiv.org/abs/2508.20960
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author Cammarata, María del Mar
Negri, R. Martín
Semino, Rocio
author_facet Cammarata, María del Mar
Negri, R. Martín
Semino, Rocio
contents Additives are essential to enhance or modify the properties of plastics for target applications. However, finding appropriate additives may be challenging, since we lack knowledge on their interactions with the plastics and with moisture, and the interplay between them. In this work, we study a commercial additive as well as two new potential additives for their antistatic and slip properties in polyethylene by means of atomistic molecular dynamics simulations. We reveal the most favorable interactions between polyethylene, each of these molecules and water, along with providing a microscopic picture of their interfacial structure. All additives interact with water mainly by their polar heads, with water acting as a hydrogen bond acceptor or donor depending on the additive. As expected, water does not enter the polyethylene matrix; it accumulates at its surface instead, without any preferencial orientation. The additives studied exhibit remarkably different structures when they are mixed with the polymer: two of them enter the polymer matrix to various degrees, either by intercalating their chains with the polyethylene ones or by forming miscellar-like structures, while the third one stays at the surface. When water is incorporated into the system, the structure of some of the additive/polyethylene systems changes. The magnitude and nature of these changes depend on the relative concentrations of all species. If the additives are in low concentrations, water stays at the surface of the material, in a drop-like shape. The additives penetrate and organize the polymer more or less depending on whether water is present or not. We predict that one of our two proposed molecules has promising antistatic properties while the other one could be applied as a slip agent. We hope that our predictions will spark interest in testing these molecules in the laboratory as polyethylene additives.
format Preprint
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publishDate 2025
record_format arxiv
spellingShingle Intermolecular Interactions between Polyethylene, Water, and Potential Antistatic and Slip Additives: a Molecular Dynamics Study
Cammarata, María del Mar
Negri, R. Martín
Semino, Rocio
Chemical Physics
Soft Condensed Matter
Additives are essential to enhance or modify the properties of plastics for target applications. However, finding appropriate additives may be challenging, since we lack knowledge on their interactions with the plastics and with moisture, and the interplay between them. In this work, we study a commercial additive as well as two new potential additives for their antistatic and slip properties in polyethylene by means of atomistic molecular dynamics simulations. We reveal the most favorable interactions between polyethylene, each of these molecules and water, along with providing a microscopic picture of their interfacial structure. All additives interact with water mainly by their polar heads, with water acting as a hydrogen bond acceptor or donor depending on the additive. As expected, water does not enter the polyethylene matrix; it accumulates at its surface instead, without any preferencial orientation. The additives studied exhibit remarkably different structures when they are mixed with the polymer: two of them enter the polymer matrix to various degrees, either by intercalating their chains with the polyethylene ones or by forming miscellar-like structures, while the third one stays at the surface. When water is incorporated into the system, the structure of some of the additive/polyethylene systems changes. The magnitude and nature of these changes depend on the relative concentrations of all species. If the additives are in low concentrations, water stays at the surface of the material, in a drop-like shape. The additives penetrate and organize the polymer more or less depending on whether water is present or not. We predict that one of our two proposed molecules has promising antistatic properties while the other one could be applied as a slip agent. We hope that our predictions will spark interest in testing these molecules in the laboratory as polyethylene additives.
title Intermolecular Interactions between Polyethylene, Water, and Potential Antistatic and Slip Additives: a Molecular Dynamics Study
topic Chemical Physics
Soft Condensed Matter
url https://arxiv.org/abs/2508.20960