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Challenges and perspectives on high and intermediate-temperature sodium batteries
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Journal Article
Challenges and perspectives on high and intermediate-temperature sodium batteries
2017
Overview
Energy storage systems are selected depending on factors such as storage capacity, available power, discharge time, self-discharge, efficiency, or durability. Additional parameters to be considered are safety, cost, feasibility, and environmental aspects. Sodium-based batteries (Na-S, NaNiC12) typically require operation temperatures of 300-350 ~C. The high operating temperatures substantially increase the operating costs and raise safety issues. This updated review describes the state-of-the-art materials for high-temperature sodium batteries and the trends towards the development and optimization of intermediate and low-temperature devices. Recent advances in inorganic solid electrolytes, glass-ceramic electrolytes, and polymer solid electrolytes are of immense importance in all-solid-state sodium batteries. Systems such as Na~ super ionic conductor (NASICON, Nal~xZr2PB-~SixOl2 (0 -〈 x _〈 3)), glass-ceramic 94Na3PS4"6Na4SiS4, and polyethylene oxide (PEO)-sodium triflate (NaCF3SO3) are also discussed. Room temperature ionic liquids (RTILs) are also included as novel electrolyte solvents. This update discusses the progress of on-going strategies to enhance the conductivity, optimize the electrolyte/electrode interface, and improve the cell design of emerging technologies. This work aims to cover the recent advances in electrode and electrolyte materials for sodium- sulfur and sodium-metal-halide (zeolite battery research Africa project (ZEBRA)) batteries for use at high and intermediate temperatures.
Publisher
Tsinghua University Press
Subject
