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Mechanochemical Synthesis and Characterization of Na3−xIn1−xZrxCl6 Solid Electrolyte (Supporting Information)

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Version 2 2023-07-24, 05:46
Version 1 2023-07-13, 06:25
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posted on 2023-07-24, 05:46 authored by Yuya OKADA, Takuya KIMURA, Kota MOTOHASHI, Atsushi SAKUDA, Akitoshi HAYASHI

All-solid-state batteries (ASSBs) have attracted significant attention as alternatives to Li-ion batteries. In ASSBs, solid electrolytes (SEs) play a key role. While many halide Li-ion conductors have been reported, only a few Na-ion conductors have been reported. In this study, a new phase of Na3InCl6 with a cryolite-type monoclinic structure was prepared using a mechanochemical method. The new phase showed higher conductivity than the previously reported trigonal Na3InCl6 and underwent a phase transition to trigonal phase when heat-treated at 90 °C. A Zr-substituted system of Na3−xIn1−xZrxCl6 was mechanochemically prepared. The obtained solid solutions with monoclinic structures based on Na3InCl6 were formed in the compositions of x = 0.1–0.9. The Rietveld refinement results showed a decrease in Na occupancy at the octahedral sites and slight change at the prismatic sites. Bond valence sum mapping results showed that Na ions diffused alternately through two types of sites, suggesting that the introduction of Na vacancies at either site had a positive effect on Na-ion conduction. The ionic conductivity increased to approximately 10−5 S cm−1 with an increase in the number of Na vacancies when x was greater than 0.6. This report describes one of the few Na-ion conducting chlorides with high conductivity.

Funding

Development of New Solid State Ionics Materials through Design of Functional Interface

Japan Society for the Promotion of Science

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Development of innovative materials for all-solid-state Na/S batteries that operate at room temperature

Japan Society for the Promotion of Science

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Ministry of Education, Culture, Sports, Science and Technology

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Corresponding author email address

akitoshihayashi@omu.ac.jp

Copyright

© 2023 The Author(s).

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