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Thermal Stability of Nanocrystalline NiS<sub>2</sub> as High Specific Capacity Thermal Battery Cathode Material

Wenju Yang, Lingping Zhou, Zeshunji Luo, Jiajun Zhu, Wulin Yang, Deyi Li, Licai Fu

2020Advanced Engineering Materials19 citationsDOI

Abstract

Nanocrystallization can shorten the Li + transport distance, resulting in the enhancement of electrochemical activity for cathode materials. However, nanocathode materials tend to be thermally unstable, further leading to poor electrochemical performance of a battery system. This disadvantage can be especially detrimental for thermal batteries because they are often operated at high temperatures (≥450 °C). Herein, the decomposition character of NiS 2 at 500 °C is investigated. The decomposition temperatures of NiS 2 are found to decrease from 510 to 350 °C with the grain size decreasing to 39 nm, due to the dramatically increased surface energy. The decomposition product is confirmed to be NiS, evidenced by a high‐temperature X‐ray diffractometer. The useful mass of the cathode will reduce once the discharging temperature is higher than 500 °C. Namely, although the small grain size shorthens the Li + transport distance, the discharge performance of the NiS 2 cathode may also decrease due to its inferior thermal stability. For the Li‐B/LiF–LiCl–LiBr/NiS 2 system, the NiS 2 with the grain size of 70 nm shows the highest specific capacity of 831 mAh g −1 under the discharging temperature of 500 °C, with the cut‐off voltage of 0.5 V, compared with other grain sizes from 39 to 112 nm.

Topics & Concepts

Nanocrystalline materialMaterials scienceCathodeGrain sizeThermal decompositionDiffractometerThermal stabilityBattery (electricity)ElectrochemistryGrain growthChemical engineeringGrain boundaryAnalytical Chemistry (journal)Composite materialNanotechnologyScanning electron microscopeMicrostructureElectrodeThermodynamicsChemistryPhysical chemistryEngineeringOrganic chemistryChromatographyPower (physics)PhysicsAdvancements in Battery MaterialsAdvanced Battery Materials and TechnologiesMolten salt chemistry and electrochemical processes