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Main Authors: Walters, Lauren N., Fei, Yuxing, Rendy, Bernardus, Yang, Xiaochen, Diallo, Mouhamad, Jun, KyuJung, Wei, Grace, McDermott, Matthew J., Giunto, Andrea, Mishra, Tara, Shen, Fengyu, Milsted, David, Oo, May Sabai, Kim, Haegyeom, Tucker, Michael C., Ceder, Gerbrand
Format: Preprint
Published: 2025
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Online Access:https://arxiv.org/abs/2501.03165
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author Walters, Lauren N.
Fei, Yuxing
Rendy, Bernardus
Yang, Xiaochen
Diallo, Mouhamad
Jun, KyuJung
Wei, Grace
McDermott, Matthew J.
Giunto, Andrea
Mishra, Tara
Shen, Fengyu
Milsted, David
Oo, May Sabai
Kim, Haegyeom
Tucker, Michael C.
Ceder, Gerbrand
author_facet Walters, Lauren N.
Fei, Yuxing
Rendy, Bernardus
Yang, Xiaochen
Diallo, Mouhamad
Jun, KyuJung
Wei, Grace
McDermott, Matthew J.
Giunto, Andrea
Mishra, Tara
Shen, Fengyu
Milsted, David
Oo, May Sabai
Kim, Haegyeom
Tucker, Michael C.
Ceder, Gerbrand
contents Advancement of solid state electrolytes (SSEs) for all solid state batteries typically focuses on modification of a parent structural framework for improved conductivity, \textit{e.g.} cation substitution for an immobile ion or varying the concentration of the mobile ion. Therefore, novel frameworks can be disruptive by enabling fast ion conduction aided by different structure and diffusion mechanisms, and unlocking optimal conductors with different properties (\textit{e.g.} mechanical properties, sintering needs, electrochemical stability) than previously published. Herein, we perform a high throughput survey of an understudied structural framework for sodium ion conduction, Na$_{8-x}$A$^x$P$_2$O$_9$ (NAP), to understand the family's thermodynamic stability, synthesizability, and ionic conduction. We first show that the parent phase Na$_4$TiP$_2$O$_9$ (NTP) undergoes a structural distortion (with accompanying conductivity transition) due to unstable phonons from a pseduo-Jahn Teller mode in the 1D titanium chains. Then, screening of cation-substituted structural candidates with \textit{ab initio} and machine-learned potential calculations reveal a number of candidates that are thermodynamically stable, likely synthesizable, and have high predicted ionic conductivities. High throughput experimental trials and subsequent methodology optimization of one Na$_4$SnP$_2$O$_9$ (NSP) highlight collective challenges to the synthesis pathways for sodium phosphate materials via solid state synthesis. Our results demonstrate that NAP is a highly tunable conduction framework whose high temperature conductivity transition has heretofore eliminated it from significant research interest. By expanding the structural toolkit for SSE design, we increase the number of useful sodium ion electrolytes for integration into safe and accessible solid state batteries.
format Preprint
id arxiv_https___arxiv_org_abs_2501_03165
institution arXiv
publishDate 2025
record_format arxiv
spellingShingle Synthetic accessibility and sodium ion conductivity of the Na$_{8-x}$A$^{x}$P$_2$O$_9$ (NAP) high-temperature sodium superionic conductor framework
Walters, Lauren N.
Fei, Yuxing
Rendy, Bernardus
Yang, Xiaochen
Diallo, Mouhamad
Jun, KyuJung
Wei, Grace
McDermott, Matthew J.
Giunto, Andrea
Mishra, Tara
Shen, Fengyu
Milsted, David
Oo, May Sabai
Kim, Haegyeom
Tucker, Michael C.
Ceder, Gerbrand
Materials Science
Advancement of solid state electrolytes (SSEs) for all solid state batteries typically focuses on modification of a parent structural framework for improved conductivity, \textit{e.g.} cation substitution for an immobile ion or varying the concentration of the mobile ion. Therefore, novel frameworks can be disruptive by enabling fast ion conduction aided by different structure and diffusion mechanisms, and unlocking optimal conductors with different properties (\textit{e.g.} mechanical properties, sintering needs, electrochemical stability) than previously published. Herein, we perform a high throughput survey of an understudied structural framework for sodium ion conduction, Na$_{8-x}$A$^x$P$_2$O$_9$ (NAP), to understand the family's thermodynamic stability, synthesizability, and ionic conduction. We first show that the parent phase Na$_4$TiP$_2$O$_9$ (NTP) undergoes a structural distortion (with accompanying conductivity transition) due to unstable phonons from a pseduo-Jahn Teller mode in the 1D titanium chains. Then, screening of cation-substituted structural candidates with \textit{ab initio} and machine-learned potential calculations reveal a number of candidates that are thermodynamically stable, likely synthesizable, and have high predicted ionic conductivities. High throughput experimental trials and subsequent methodology optimization of one Na$_4$SnP$_2$O$_9$ (NSP) highlight collective challenges to the synthesis pathways for sodium phosphate materials via solid state synthesis. Our results demonstrate that NAP is a highly tunable conduction framework whose high temperature conductivity transition has heretofore eliminated it from significant research interest. By expanding the structural toolkit for SSE design, we increase the number of useful sodium ion electrolytes for integration into safe and accessible solid state batteries.
title Synthetic accessibility and sodium ion conductivity of the Na$_{8-x}$A$^{x}$P$_2$O$_9$ (NAP) high-temperature sodium superionic conductor framework
topic Materials Science
url https://arxiv.org/abs/2501.03165