Abstract
A high-voltage electrolyte can match high-voltage positive electrode material to fully exert its capacity. In this research, a sulfolane plasticized polymer electrolyte was prepared by in situ photocuring. First, the effect of the sulfolane content on the ionic conductivity of the gel polymer electrolyte was investigated. Results showed that the ionic conductivity variation trend was in good agreement with the exponential function model for curve fitting. Second, the activation energy was calculated from the results of the variable temperature conductivity tests. The activation energy was inversely proportional to the sulfolane content. For the sulfolane content of 80 wt. % in gel polymer electrolyte (GPE)-80 (19.5 kJ/mol), the activation energy was close to conventional liquid electrolyte (9.5 kJ/mol), and the conductivity and electrochemical window were 0.64 mS/cm and 5.86 V, respectively. The battery cycle performance test showed that the initial specific discharge capacities of GPE-80 and liquid electrolyte were 176.8 and 148.3 mAh/g, respectively. After 80 cycles, the discharge capacities of GPE-80 and liquid electrolyte were 115.8 and 41.1 mAh/g, and the capacity retention rates were 65.5% and 27.7%, respectively; indicating that GPE-80 has a better specific discharge capacity and cycling performance than the liquid electrolyte. SEM images indicated that GPE-80 can suppress the growth of lithium dendrites. The EDS test showed that GPE-80 can inhibit the dissolution of metal ions in the cathode material.
Highlights
The lithium-ion batteries are being widely used, because of the growing requirement for mobile phones, electric vehicles and drones [1,2,3]
Results show that activation energy of gel polymer electrolyte (GPE)-80 (19.5 kJ/mol) is closer to that of conventional electrolyte
The results show that the oxidation potentials of liquid electrolyte and GPE-80 are 4.1 and 5.8 V, results show that the oxidation potentials of liquid electrolyte and GPE-80 are 4.1 and 5.8 V, respectively
Summary
The lithium-ion batteries are being widely used, because of the growing requirement for mobile phones, electric vehicles and drones [1,2,3]. The traditional lithium-ion battery has a low capacity and cannot meet long-life application demands. There is an urgent need to develop a battery with a higher specific capacity [4]. To greatly increase the specific capacity of a battery, it is necessary to develop positive and negative materials. Synthetic, higher capacity positive and negative materials increase the use voltage of the positive electrode material, and the use of lithium metal or silicon negative electrodes. The NCM (Ni-rich transition metal oxide) cathode material has a high specific capacity (>200 mAh/g) and is typically used at a voltage of 4.3 V [5,6]. It is necessary to develop a higher voltage electrolyte to match the cathode material
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