Freestanding all-solid-state rechargeable lithium batteries with in-situ formed positive electrodes

Abstract

Abstracts Freestanding all-solid-state rechargeable lithium batteries (Li/LiPON/LATP sheet/Au, SSB) operating at 2.3 V were developed. The electrochemical insertion of lithium into a white-colored Li+ conductive glass-ceramic solid electrolyte (LATP) sheet transformed the electrolyte into a blue-colored in-situ formed electrode, which provided a low-resistance electrode/solid electrolyte interface of ca. 100 Ω cm2. In addition, the interfacial resistances at both Li/LiPON and LiPON/LATP were less than 100 Ω cm2, and all the components in the SSB were combined with low-resistance interfaces. As a consequence, the resultant SSB delivered a clear redox peak at 100 mV s−1 in the cyclic voltammetry measurements at 25 °C. The reaction region of the in-situ formed electrode was limited around the Au/LATP interface at 25 °C, but this region expanded into the LATP sheet at higher temperatures. At 100 °C, the resultant SSB delivered ca. 300 μΑh cm−2 and a volumetric energy density of 53 Wh L−1. The electronic conductivity of the in-situ formed electrode appeared to control the reaction region, and thus a SSB using a carbon-LATP composite sheet delivered a larger discharge capacity at 25 °C than that of the SSB using only LATP operated at 100 °C. The use of conductive LATP sheets may be a possible solution for developing SSBs that can be rationally designed according to the operational environments of the IoTs.