The choice of a thermodynamic formulation dramatically affects modelled chemical zoning in minerals

Abstract Quantifying natural processes that shape our planet is a key to understanding the geological observations. Many phenomena in the Earth are not in thermodynamic equilibrium. Cooling of the Earth, mantle convection, mountain building are examples of dynamic processes that evolve in time and s...

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Main Authors: L. Tajčmanová, Y. Podladchikov, E. Moulas, L. Khakimova
Format: Article
Language:English
Published: Nature Publishing Group 2021-09-01
Series:Scientific Reports
Online Access:https://doi.org/10.1038/s41598-021-97568-x
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spelling doaj-8c33b0c1e5d34b75a77bef448677a2622021-09-26T11:31:40ZengNature Publishing GroupScientific Reports2045-23222021-09-011111910.1038/s41598-021-97568-xThe choice of a thermodynamic formulation dramatically affects modelled chemical zoning in mineralsL. Tajčmanová0Y. Podladchikov1E. Moulas2L. Khakimova3Institute of Earth Sciences, Heidelberg UniversityInstitute of Earth Science, University of LausanneInstitute of Geosciences & Mainz Institute of Multiscale Modeling (M3ODEL), Johannes-Gutenberg University of MainzFaculty of Mechanics and Mathematics, Moscow State UniversityAbstract Quantifying natural processes that shape our planet is a key to understanding the geological observations. Many phenomena in the Earth are not in thermodynamic equilibrium. Cooling of the Earth, mantle convection, mountain building are examples of dynamic processes that evolve in time and space and are driven by gradients. During those irreversible processes, entropy is produced. In petrology, several thermodynamic approaches have been suggested to quantify systems under chemical and mechanical gradients. Yet, their thermodynamic admissibility has not been investigated in detail. Here, we focus on a fundamental, though not yet unequivocally answered, question: which thermodynamic formulation for petrological systems under gradients is appropriate—mass or molar? We provide a comparison of both thermodynamic formulations for chemical diffusion flux, applying the positive entropy production principle as a necessary admissibility condition. Furthermore, we show that the inappropriate solution has dramatic consequences for understanding the key processes in petrology, such as chemical diffusion in the presence of pressure gradients.https://doi.org/10.1038/s41598-021-97568-x
collection DOAJ
language English
format Article
sources DOAJ
author L. Tajčmanová
Y. Podladchikov
E. Moulas
L. Khakimova
spellingShingle L. Tajčmanová
Y. Podladchikov
E. Moulas
L. Khakimova
The choice of a thermodynamic formulation dramatically affects modelled chemical zoning in minerals
Scientific Reports
author_facet L. Tajčmanová
Y. Podladchikov
E. Moulas
L. Khakimova
author_sort L. Tajčmanová
title The choice of a thermodynamic formulation dramatically affects modelled chemical zoning in minerals
title_short The choice of a thermodynamic formulation dramatically affects modelled chemical zoning in minerals
title_full The choice of a thermodynamic formulation dramatically affects modelled chemical zoning in minerals
title_fullStr The choice of a thermodynamic formulation dramatically affects modelled chemical zoning in minerals
title_full_unstemmed The choice of a thermodynamic formulation dramatically affects modelled chemical zoning in minerals
title_sort choice of a thermodynamic formulation dramatically affects modelled chemical zoning in minerals
publisher Nature Publishing Group
series Scientific Reports
issn 2045-2322
publishDate 2021-09-01
description Abstract Quantifying natural processes that shape our planet is a key to understanding the geological observations. Many phenomena in the Earth are not in thermodynamic equilibrium. Cooling of the Earth, mantle convection, mountain building are examples of dynamic processes that evolve in time and space and are driven by gradients. During those irreversible processes, entropy is produced. In petrology, several thermodynamic approaches have been suggested to quantify systems under chemical and mechanical gradients. Yet, their thermodynamic admissibility has not been investigated in detail. Here, we focus on a fundamental, though not yet unequivocally answered, question: which thermodynamic formulation for petrological systems under gradients is appropriate—mass or molar? We provide a comparison of both thermodynamic formulations for chemical diffusion flux, applying the positive entropy production principle as a necessary admissibility condition. Furthermore, we show that the inappropriate solution has dramatic consequences for understanding the key processes in petrology, such as chemical diffusion in the presence of pressure gradients.
url https://doi.org/10.1038/s41598-021-97568-x
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