Nanotechnology has increased electric vehicle (EV) battery production, efficiency and use. Nanotechnology is explored in this electric car battery illustration. Nanoscale materials and topologies research has increased battery energy density, charge time and cycle life. Nanotubes, graphene and metal oxides improve energy storage, flow and charging/discharge. Solid-state and lithium-air high-energy batteries are safer, more energy dense and more stable using nanoscale catalysts. Nanotechnology improves battery parts. Nanostructured fluids reduce lithium dendrite, improving batteries. Nanocoating electrodes may reduce damage and extend battery life. Nanotechnology benefits the planet. Nanomaterials allow battery parts to employ ordinary, safe materials instead of rare, harmful ones. Nanotechnology promotes battery recycling, reducing waste. Change does not influence stable, cost-effective or scalable items. Business opportunities for nanotechnology-based EV batteries need more research. High-performance, robust and environmentally friendly batteries might make electric cars more popular and transportation more sustainable with research and development. An outline of EV battery nanotechnology researchexamines the publication patterns, notable articles, collaborators and contributions. This issue was researched extensively, indicating interest. Research focuses on anode materials, energy storage and battery performance. A research landscape assessment demonstrates EV battery nanotechnology’s growth and future. A comprehensive literature review examined nanosensors in EVs. Our study provides a solid foundation for understanding the current state of research, identifying major trends and discovering nanotechnology breakthroughs in EV sensors by carefully reviewing, characterizing and rating important papers.
