Mesoscopic Framework Enables Facile Ionic Transport in Solid Electrolytes for Li Batteries

Cheng Ma, Yongqiang Cheng, Kai Chen, Juchuan Li, Bobby G. Sumpter, Ce Wen Nan, Karren L. More, Nancy J. Dudney, Miaofang Chi

Research output: Contribution to journalArticlepeer-review

52 Scopus citations

Abstract

Li-ion-conducting solid electrolytes can simultaneously overcome two grand challenges for Li-ion batteries: the severe safety concerns that limit the large-scale application and the poor electrolyte stability that forbids the use of high-voltage cathodes. Nevertheless, the ionic conductivity of solid electrolytes is typically low, compromising the battery performances. Precisely determining the ionic transport mechanism(s) is a prerequisite for the rational design of highly conductive solid electrolytes. For decades, the research on this subject has primarily focused on the atomic and microscopic scales, where the main features of interest are unit cells and microstructures, respectively. Here, it is shown that the largely overlooked mesoscopic scale lying between these extremes could be the key to fast ionic conduction. In a prototype system, (Li0.33La0.56)TiO3, a mesoscopic framework is revealed for the first time by state-of-the-art scanning transmission electron microscopy. Corroborated by theoretical calculations and impedance measurements, it is demonstrated that such a unique configuration maximizes the number of percolation directions and thus most effectively improves the ionic conductivity. This discovery reconciles the long-standing structure–property inconsistency in (Li0.33La0.56)TiO3 and also identifies mesoscopic ordering as a promising general strategy for optimizing Li+ conduction.

Original languageEnglish
Article number1600053
JournalAdvanced Energy Materials
Volume6
Issue number11
DOIs
StatePublished - Jun 8 2016

Keywords

  • Li batteries
  • coherence length
  • ionic transport
  • scanning transmission electron microscopy
  • solid electrolytes

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