Controlling the Changes in Electrolyte Composition in the Cathode to Reduce the Voltage Decay of NiCl<sub>2</sub> Thermal Batteries
Mengjie Huang, Jianying Li, Shaomin Li, Bo Yue, Maoxia Yang, Jidong Duan, Jianqiang Guo, Yanhua Cui, Hao Liu
Abstract
Because of the high open-circuit voltage and good performance under high current loading, NiCl 2 has become a promising cathode material for thermal batteries. Unfortunately, the high resistivity and the occurrence of voltage decay during the discharge process limit the application of NiCl 2 . In this work, Br-doped NiCl 2 is synthesized to reduce this voltage decay. The ion mobility of NiCl 2 is improved by bromine doping, and the rise of the melting point of the electrolyte in the positive electrode is delayed by releasing both LiCl and LiBr in the discharge process. Thus, the voltage decay is reduced. The capacity of NiCl 1.6 Br 0.4 at its voltage platform (>2.0 V) is 255 mA h g –1 and that of NiCl 2 is only 200 mA h g –1 (under 200 mA cm –2 ). Moreover, Br doping also improves the conductivity of NiCl 2 . Therefore, the maximum voltage at the discharge of NiCl 1.6 Br 0.4 (2.02 V) is higher than that of NiCl 2 (1.76 V) under 500 mA cm –2 constant current loading.