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Bibliographic Details
Main Authors: Miura, Akira, Baek, Woohyeon, Fujii, Yuta, Tadanaga, Kiyoharu, Hossain, Rana, Yamashita, Aichi, Mizuguchi, Yoshikazu, Moriyoshi, Chikako, Kobayashi, Shintaro, Kawaguchi, Shogo, Ding, Jiong, Mori, Shigeo, Sakuda, Atsushi, Hayashi, Akitoshi, Sun, Wenhao
Format: Preprint
Published: 2025
Subjects:
Online Access:https://arxiv.org/abs/2512.05841
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Table of Contents:
  • $α$-Li$_3$PS$_4$ is a promising solid-state electrolyte with the highest ionic conductivity among its polymorphs. However, its formation presents a thermodynamic paradox: the $α$-phase is the equilibrium phase at high temperature and transforms to the stable $γ$-Li$_3$PS$_4$ polymorph when cooled to room temperature; however, $α$-Li$_3$PS$_4$ can be synthesized and quenched in a metastable state via rapid heating at relatively low temperatures. The origin of this synthesizability and anomalous stability has remained elusive. Here, we resolve this paradox by establishing a comprehensive time-temperature-transformation (TTT) diagram, constructed from a computational temperature-size phase diagram and experimental high-time-resolution isothermal measurements. Our density functional theory calculations reveal that at the nanoscale, the $α$-phase is stabilized by its low surface energy, which drastically lowers the nucleation barrier across a wide temperature range. This size-dependent stabilization is directly visualized using in-situ synchrotron X-ray diffraction and electron microscopy, capturing the rapid nucleation of nano-sized $α$-phase and its subsequent slow transformation. This work presents a generalizable framework that integrates thermodynamic and kinetic factors for understanding nucleation and phase transformation mechanisms, providing a rational strategy for the targeted synthesis of functional metastable materials.