Computational investigation of the Mg-ion conductivity and phase stability of MgZr(4)(PO(4))(6)

Solid electrolyte materials exhibiting high Mg-ion conductivity are required to develop Mg-ion batteries. In this study, we focused on a Mg-ion-conducting solid phosphate based electrolyte, MgZr(4)(PO(4))(6) (MZP), and evaluated the ionic conductivity of NASICON-type and β-iron sulfate-type MgZr(4)(...

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Autores principales: Nakano, Koki, Noda, Yusuke, Tanibata, Naoto, Nakayama, Masanobu, Kajihara, Koichi, Kanamura, Kiyoshi
Formato: Online Artículo Texto
Lenguaje:English
Publicado: The Royal Society of Chemistry 2019
Materias:
Chemistry
Acceso en línea:https://www.ncbi.nlm.nih.gov/pmc/articles/PMC9063713/
https://www.ncbi.nlm.nih.gov/pubmed/35515861
http://dx.doi.org/10.1039/c9ra00513g
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author Nakano, Koki
Noda, Yusuke
Tanibata, Naoto
Nakayama, Masanobu
Kajihara, Koichi
Kanamura, Kiyoshi
author_facet Nakano, Koki
Noda, Yusuke
Tanibata, Naoto
Nakayama, Masanobu
Kajihara, Koichi
Kanamura, Kiyoshi
author_sort Nakano, Koki
collection PubMed
description Solid electrolyte materials exhibiting high Mg-ion conductivity are required to develop Mg-ion batteries. In this study, we focused on a Mg-ion-conducting solid phosphate based electrolyte, MgZr(4)(PO(4))(6) (MZP), and evaluated the ionic conductivity of NASICON-type and β-iron sulfate-type MgZr(4)(PO(4))(6) structures via density functional theory calculations. The calculations suggest that the migration energy of Mg is 0.63 eV for the NASICON-type structure and 0.71 eV for the β-iron sulfate-type one, and the NASICON-type structure has higher ion conductivity. Although the NASICON-type MZP structure has not been experimentally realised, there is only an energy difference of 14 meV per atom with respect to that of the β-iron sulfate-type structure. Therefore, in order to develop a synthesis method for the NASICON-type structure, we investigated pressure- and temperature-dependent variations in the free energy of formation using density functional perturbation theory calculations. The results suggest that the formation of the NASICON-type structure is disfavoured under the 0–2000 K and 0–20 GPa conditions.
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spelling pubmed-90637132022-05-04 Computational investigation of the Mg-ion conductivity and phase stability of MgZr(4)(PO(4))(6) Nakano, Koki Noda, Yusuke Tanibata, Naoto Nakayama, Masanobu Kajihara, Koichi Kanamura, Kiyoshi RSC Adv Chemistry Solid electrolyte materials exhibiting high Mg-ion conductivity are required to develop Mg-ion batteries. In this study, we focused on a Mg-ion-conducting solid phosphate based electrolyte, MgZr(4)(PO(4))(6) (MZP), and evaluated the ionic conductivity of NASICON-type and β-iron sulfate-type MgZr(4)(PO(4))(6) structures via density functional theory calculations. The calculations suggest that the migration energy of Mg is 0.63 eV for the NASICON-type structure and 0.71 eV for the β-iron sulfate-type one, and the NASICON-type structure has higher ion conductivity. Although the NASICON-type MZP structure has not been experimentally realised, there is only an energy difference of 14 meV per atom with respect to that of the β-iron sulfate-type structure. Therefore, in order to develop a synthesis method for the NASICON-type structure, we investigated pressure- and temperature-dependent variations in the free energy of formation using density functional perturbation theory calculations. The results suggest that the formation of the NASICON-type structure is disfavoured under the 0–2000 K and 0–20 GPa conditions. The Royal Society of Chemistry 2019-04-23 /pmc/articles/PMC9063713/ /pubmed/35515861 http://dx.doi.org/10.1039/c9ra00513g Text en This journal is © The Royal Society of Chemistry https://creativecommons.org/licenses/by/3.0/
spellingShingle Chemistry
Nakano, Koki
Noda, Yusuke
Tanibata, Naoto
Nakayama, Masanobu
Kajihara, Koichi
Kanamura, Kiyoshi
Computational investigation of the Mg-ion conductivity and phase stability of MgZr(4)(PO(4))(6)
title Computational investigation of the Mg-ion conductivity and phase stability of MgZr(4)(PO(4))(6)
title_full Computational investigation of the Mg-ion conductivity and phase stability of MgZr(4)(PO(4))(6)
title_fullStr Computational investigation of the Mg-ion conductivity and phase stability of MgZr(4)(PO(4))(6)
title_full_unstemmed Computational investigation of the Mg-ion conductivity and phase stability of MgZr(4)(PO(4))(6)
title_short Computational investigation of the Mg-ion conductivity and phase stability of MgZr(4)(PO(4))(6)
title_sort computational investigation of the mg-ion conductivity and phase stability of mgzr(4)(po(4))(6)
topic Chemistry
url https://www.ncbi.nlm.nih.gov/pmc/articles/PMC9063713/
https://www.ncbi.nlm.nih.gov/pubmed/35515861
http://dx.doi.org/10.1039/c9ra00513g
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