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Main Authors: Pollak, Hannah, Degiacomi, Matteo T., Erastova, Valentina
Format: Preprint
Published: 2024
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Online Access:https://arxiv.org/abs/2407.18882
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author Pollak, Hannah
Degiacomi, Matteo T.
Erastova, Valentina
author_facet Pollak, Hannah
Degiacomi, Matteo T.
Erastova, Valentina
contents Clays are a broad class of ubiquitous layered materials. Their specific chemophysical properties are intimately connected to their molecular structure, featuring repeating patterns broken by substitutions. Molecular dynamics simulations can provide insight into the mechanisms leading to the emergent properties of these layered materials, however up to now idealised clay structures have been simulated to make the modelling process tractable. We present ClayCode, software facilitating the modelling of clay systems closely resembling experimentally determined structures. By comparing a realistic model to a commonly used montmorillonite clay model, we demonstrate that idealised models feature noticeably different ionic adsorption patterns. We then present an application of ClayCode to the study the competitive barium and sodium adsorption on Wyoming montmorillonite, Georgia kaolinite, and Montana illite, of interest in the context of nuclear waste disposal.
format Preprint
id arxiv_https___arxiv_org_abs_2407_18882
institution arXiv
publishDate 2024
record_format arxiv
spellingShingle Modelling realistic clay systems with ClayCode
Pollak, Hannah
Degiacomi, Matteo T.
Erastova, Valentina
Materials Science
Clays are a broad class of ubiquitous layered materials. Their specific chemophysical properties are intimately connected to their molecular structure, featuring repeating patterns broken by substitutions. Molecular dynamics simulations can provide insight into the mechanisms leading to the emergent properties of these layered materials, however up to now idealised clay structures have been simulated to make the modelling process tractable. We present ClayCode, software facilitating the modelling of clay systems closely resembling experimentally determined structures. By comparing a realistic model to a commonly used montmorillonite clay model, we demonstrate that idealised models feature noticeably different ionic adsorption patterns. We then present an application of ClayCode to the study the competitive barium and sodium adsorption on Wyoming montmorillonite, Georgia kaolinite, and Montana illite, of interest in the context of nuclear waste disposal.
title Modelling realistic clay systems with ClayCode
topic Materials Science
url https://arxiv.org/abs/2407.18882