The development of electric vehicles (EVs) is highly dependent on the advancement of high-energy-density battery technology, as this directly determines the range, charging efficiency, and overall performance of EVs. However, current battery systems still have significant limitations: the instability of materials (such as the structural collapse of electrode materials during charging and discharging cycles) and interface issues (including poor ion transport and interface side reactions) severely restrict their practical application. This paper systematically reviews strategies based on nanotechnology, aiming to overcome these key obstacles, with a focus on the design and application of new nanomaterials and nanostructures in the field of materials chemistry. The key findings of the reviewed studies include: nano-coatings (such as oxide films) and element doping of high-nickel electrodes significantly improve structural stability and inhibit capacity degradation; silicon-based nanomaterials effectively alleviate the severe volume expansion of anode materials, thereby improving cycle life. In addition, artificially constructed interface layers (such as solid electrolyte interface layers) can optimize ion selectivity and enhance mechanical durability, while thick electrodes combined with nanoscale conductive networks (such as carbon nanotubes) can promote efficient charge transfer and increase energy density without reducing rate performance. Overall, these methods driven by nanotechnology not only increase the energy density of EV batteries but also ensure excellent cycle performance and safety. This research further emphasizes the crucial and irreplaceable role of nanotechnology in driving the innovation and development of next-generation high-performance EV battery technologies.
W. Lai (Tue,) studied this question.
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