Abstract

This paper describes an investigation of the properties of superionic glass–ceramic specimens synthesized from the lithium–aluminum–germanium–phosphate system. The specimens were characterized using differential scanning calorimetry, X-ray diffraction, scanning electron microscopy, and impedance spectroscopy. The concentration of lithium oxide in the glass–ceramic formulations was the primary variable investigated. It is shown that the ionic conductivity of the specimens was dependent on the lithium oxide concentration. An optimized composition exhibited a conductivity approaching at around room temperature. The superionic conductivity in these specimens is attributed to the space-charge-mediated effect resulting from the presence of the dielectric phase. The specimens also displayed different conductivities during heating and cooling scans, referred to in this paper as hysteresis effect.