Study And Application of Nanotechnology in Lithium Batteries
DOI:
https://doi.org/10.54097/h19wrh82Keywords:
Lithium batteries, Energy storage, Nanotechnology, Cycling stability, Electrode materials.Abstract
Lithium batteries have completely changed energy storage due to their high energy density, long lifespan and inherent stability. However, scientists are committed to researching more advanced technologies that enable lithium batteries to have higher efficiency, safety and longer lifespan. Nanotechnology has become a transformative approach, significantly assisting lithium batteries’ materials, design, and performance. This article explores the research and application of nanotechnology in lithium batteries, focusing on its role in improving capacity, enhancing safety, and cycling stability. The results of this paper show that silicon nanowire anode can effectively mitigate volume expansion, while graphene-reinforced cathode can improve electrical conductivity and thermal stability. In addition, nanostructured materials significantly enhance lithium-ion transport, increase Coulombic efficiency, and extend cycle life. Despite challenges such as scalability and cost, advancements in nanotechnology continue to drive innovation in battery development. This study emphasizes the potential of nanotechnology to create safer, high-performance lithium batteries and highlights future research directions for large-scale applications.
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