<?xml version='1.0' encoding='UTF-8'?><metadata xmlns:xsi="http://www.w3.org/2001/XMLSchema-instance" xmlns:dc="http://purl.org/dc/elements/1.1/" xmlns:dcterms="http://purl.org/dc/terms/" xmlns="http://dublincore.org/documents/dcmi-terms/"><dcterms:title>Simulation data for: The anisotropy of barite during crystal growth and the uptake of Radium</dcterms:title><dcterms:identifier>https://doi.org/10.26165/JUELICH-DATA/TMXM7D</dcterms:identifier><dcterms:creator>Rudin, Stefan</dcterms:creator><dcterms:creator>Kowalski, Piotr</dcterms:creator><dcterms:creator>Klinkenberg, Martina</dcterms:creator><dcterms:creator>Bosbach, Dirk</dcterms:creator><dcterms:creator>Brandt, Felix</dcterms:creator><dcterms:publisher>Jülich DATA</dcterms:publisher><dcterms:issued>2024-03-20</dcterms:issued><dcterms:modified>2024-03-20T15:55:03Z</dcterms:modified><dcterms:description>The role of Ba2+ kink-site nucleation and step growth for the kinetics of anisotropic barite-(001) growth and Ra2+ kink-site nucleation for the activation energy of Ra uptake into the barite structure was investigated using atomistic modeling approaches. &#xd;
Ba2+ and Ra2+ kink-site nucleation processes were performed with a hybrid Density-functional theory – continuum solvation method, the last steps of further step growth via Ba2+ attachment was performed by classical Molecular dynamics simulations. &#xd;
This dataset contains the input and output files of all simulations performed in this study.</dcterms:description><dcterms:subject>Earth and Environmental Sciences</dcterms:subject><dcterms:language>English</dcterms:language><dcterms:contributor>Rudin, Stefan</dcterms:contributor><dcterms:dateSubmitted>2024-03-19</dcterms:dateSubmitted><dcterms:license>CCBY</dcterms:license></metadata>