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Precisely synthesized LiF-tipped CoF 2 -nanorod heterostructures improve energy storage capacities.

Siyuan WangHao FuJiamin MaXiaomeng ShiHuimin WangZongyou YinShuai ZhangMengdie JinZiyun ZhongXinyun ZhaiYaping Du
Published in: Chemical science (2022)
CoF 2 , with a relatively high theoretical capacity (553 mA h g -1 ), has been attracting increasing attention in the energy storage field. However, a facile and controllable synthesis of monodispersed CoF 2 and CoF 2 -based nano-heterostructures have been rarely reported. In this direction, an eco-friendly and precisely controlled colloidal synthesis strategy to grow uniformly sized CoF 2 nanorods and LiF-tipped CoF 2 -nanorod heterostructures based on a seeded-growth method is established. The unveiled selective growth of LiF nanoparticles onto the two end tips of the CoF 2 nanorods is associated with the higher energy of tips, which favors the nucleation of LiF nanocrystals. Notably, it was found that LiF could protect CoF 2 from corrosion even after 9 months of aging. In addition, the as-obtained heterostructures were employed in supercapacitors and lithium sulfur batteries as cathode materials. The heterostructures consistently exhibited higher specific capacities than the corresponding two single components in both types of energy storage devices, making it a potential electrode material for energy storage applications.
Keyphrases
  • room temperature
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  • solid state
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  • ionic liquid
  • carbon nanotubes
  • energy transfer