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Li‐Ion Cooperative Migration and Oxy‐Sulfide Synergistic Effect in Li<sub>14</sub>P<sub>2</sub>Ge<sub>2</sub>S<sub>16−6</sub><i><sub>x</sub></i>O<i><sub>x</sub></i> Solid‐State‐Electrolyte Enables Extraordinary Conductivity and High Stability

Bingkai Zhang, Mouyi Weng, Zhan Lin, Yancong Feng, Luyi Yang, Lin‐Wang Wang, Feng Pan

2020Small39 citationsDOI

Abstract

Abstract Critical to the development of all‐solid‐state lithium‐ion batteries technology are novel solid‐state electrolytes with high ionic conductivity and robust stability under inorganic solid‐electrolyte operating conditions. Herein, by using density functional theory and molecular dynamics, a mixed oxygen‐sulfur‐based Li‐superionic conductor is screened out from the local chemical structure of β‐Li 3 PS 4 to discover novel Li 14 P 2 Ge 2 S 8 O 8 (LPGSO) with high ionic conductivity and high stability under thermal, moist, and electrochemical conditions, which causes oxygenation at specific sites to improve the stability and selective sulfuration to provide an O‐S mixed path by Li‐S/O structure units with coordination number between 3 and 4 for fast Li‐cooperative conduction. Furthermore, LPGSO exhibits a quasi‐isotropic 3D Li‐ion cooperative diffusion with a lesser migration barrier (≈0.19 eV) compared to its sulfide‐analog Li 14 P 2 Ge 2 S 16 . The theoretical ionic conductivity of this conductor at room temperature is as high as ≈30.0 mS cm −1 , which is among the best in current solid‐state electrolytes. Such an oxy‐sulfide synergistic effect and Li‐ion cooperative migration mechanism would enable the engineering of next‐generation electrolyte materials with desirable safety and high ionic conductivity, for possible application in the near future.

Topics & Concepts

IonSulfideMaterials scienceCrystallographyChemistryMetallurgyOrganic chemistryAdvancements in Battery MaterialsAdvanced Battery Materials and TechnologiesExtraction and Separation Processes