Enabling high-temperature processing of thin film Li-ion batteries using a LISICON based solid-state electrolyte
Mohammadhossein Montazerian, Kyle J. Stephens, Vladimir Roddatis, Christof Vockenhuber, Arnold Müller, Anders J. Barlow, Thomas Lippert, Nick A. Shepelin, Daniele Pergolesi
Journal of Materials Chemistry A (2025) https://doi.org/10.1039/D5TA07144E
Lithium-ion batteries employing solid-state electrolytes (SSEs) are emerging as a safer and more compact alternative to conventional batteries using liquid electrolytes, especially for miniaturized energy storage systems. However, the industry-standard SSE, LiPON, imposes limitations due to its incompatibility with high-temperature processing. In this study, we investigate Li4−xGe1−xPxO4 (LGPO), a LISICON-type oxide, as a promising alternative thin-film SSE. LGPO thin films are fabricated using pulsed laser deposition under four distinct deposition conditions, with in situ impedance spectroscopy enabling precise conductivity measurements without ambient exposure. We systematically correlate deposition temperature, background pressure, chemical composition, crystallinity, and morphology with ionic transport properties. Polycrystalline LGPO films grown at high temperature (535 °C) and low oxygen pressure (0.01 mbar) exhibited the highest room-temperature ionic conductivity (∼10−5 S cm−1), exceeding that of LiPON by an order of magnitude, with an activation energy of 0.47 eV. In contrast, amorphous films show significantly lower conductivity (∼5.2 × 10−8 S cm−1) and higher activation energy (0.72 eV). The results reveal that crystallinity, chemical composition, and grain boundary density critically affect ion transport, highlighting the importance of microstructural control. This work establishes LGPO as a viable, high-performance oxide SSE compatible with high-temperature processing for next-generation microbattery architectures.
Our expertise and capabilities in this research
-
Anders Barlow
Anders leads the Electron and Ion Microscopy and Vibrational Spectroscopy nodes of the MCFP. He is a materials and surface analysis specialist who can help you with all manner of identification and characterisation of hard and soft materials.
-
Helium ion microscopy and dual-beam nanofabrication
The Zeiss ORION NanoFab is an advanced scanning ion microscope that utilises an interchangeable dual-ion beam (helium and neon) for nanofabrication and sub-nanometre imaging