Antiperovskite K3OI for K-Ion Solid State Electrolyte

Discovering new K-ion solid-state electrolytes is crucial for the emerging K-batteries to improve energy density, cycle life, and safety. Here, we present a combined experimental and theoretical study of antiperovskite K3OI as a K-ion solid-state electrolyte. A solid-solid phase transition at approximately 240 degrees C induces an increase in ionic conductivity by 2 orders of magnitude. Anion disorder in the I-O sublattice is found to be a potential mechanism for the observed phase transition. The Ba-doped K3OI sample K2.9Ba0.05OI achieves 3.5 mS cm(-1) after the phase transition with a low activation energy of 0.36 eV. Stable cycling of K/K2.9Ba0.05OI/K symmetric cells are observed with a low over-potential of 50 mV at 0.5 mA/cm(2) at 270 degrees C. This study not only reports K3OI as a promising K-ion solid-state electrolyte that is compatible with reactive K metal but also improves the understanding of alkali antiperovskite solid-state electrolytes in general.

Automated summary

K-ion solid-state electrolyte K3OI shows high ionic conductivity, with a solid-solid phase transition at 240 degrees Celsius leading to a 2 order of magnitude increase in ionic conductivity. Anion disorder in the I-O sublattice is found to be a potential mechanism for the observed phase transition. Ba-doped K3OI sample exhibits low activation energy and stability at high temperature after the phase transition.