Abstract
Lithium aluminum germanium phosphate (LAGP) glass-ceramics are considered as promising solid-state electrolytes for Li-ion batteries. LAGP glass was prepared via the regular conventional melt-quenching method. Thermal, chemical analyses and X-ray diffraction (XRD) were performed to characterize the prepared glass. The crystallization of the prepared LAGP glass was done using conventional heating and high frequency microwave (MW) processing. Thirty GHz microwave (MW) processing setup were used to convert the prepared LAGP glass into glass-ceramics and compared with the conventionally crystallized LAGP glass-ceramics that were heat-treated in an electric conventional furnace. The ionic conductivities of the LAGP samples obtained from the two different routes were measured using impedance spectroscopy. These samples were also characterized using XRD and scanning electron microscopy (SEM). Microwave processing was successfully used to crystallize LAGP glass into glass-ceramic without the aid of susceptors. The MW treated sample showed higher total, grains and grain boundary ionic conductivities values, lower activation energy and relatively larger-grained microstructure with less porosity compared to the corresponding conventionally treated sample at the same optimized heat-treatment conditions. The enhanced total, grains and grain boundary ionic conductivities values along with the reduced activation energy that were observed in the MW treated sample was considered as an experimental evidence for the existence of the microwave effect in LAGP crystallization process. MW processing is a promising candidate technology for the production of solid-state electrolytes for Li-ion battery.
Highlights
The electrical energy storage systems have attracted a lot of attention in the past few decades because of the urgent need and the development of alternative energy sources
The use of microwave processing in the crystallization process of other glass systems into glass-ceramics materials with high mechanical properties such as lit hium disilicate (LS2) glass-ceramics has been successfully accomplished and reported by the author [49,50,51,52,53]. This accumulated experience and knowledge in the microwave processing of glass-ceramics and materials will be used to accomplish the goals of the current study
The chemical composition of the prepared Lithium aluminum germanium phosphate (LAGP) glass from the above mentioned starting materials is shown in Table 2 with the chemical formula Li1.71 Al0.53 Ge1.36 P2.99 O11.9
Summary
The electrical energy storage systems have attracted a lot of attention in the past few decades because of the urgent need and the development of alternative energy sources. The use of microwave processing in the crystallization process of other glass systems into glass-ceramics materials with high mechanical properties such as lit hium disilicate (LS2) glass-ceramics has been successfully accomplished and reported by the author [49,50,51,52,53]. This accumulated experience and knowledge in the microwave processing of glass-ceramics and materials will be used to accomplish the goals of the current study
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