Nanostructured Materials for Advanced Rechargeable Battery Systems
POSTER
Abstract
As the demand for portable devices and electric vehicles continues to skyrocket, there is an urgent need to develop rechargeable batteries with enhanced capabilities. These include high energy density for extended runtimes, increased cycle life for longer usage, advanced discharge performance to provide an optimal power output, low thermal decay to protect internal stability, minimal environmental impact and ethical resource collection, and many more.
This research conducted at the University of Arkansas aimed to improve the performance of Nickel-rich Lithium-ion batteries (LIBs), as well as address their associated challenges (i.e. capacity fade, voltage decay, dendrite formation). The findings of this research provide insight into the development of high-performance, reliable, and safe Nickel-rich LIBs, and contributes to the advancement of renewable energy storage systems.
This research conducted at the University of Arkansas aimed to improve the performance of Nickel-rich Lithium-ion batteries (LIBs), as well as address their associated challenges (i.e. capacity fade, voltage decay, dendrite formation). The findings of this research provide insight into the development of high-performance, reliable, and safe Nickel-rich LIBs, and contributes to the advancement of renewable energy storage systems.
Presenters
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Colin Walters
Marietta College
Authors
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Colin Walters
Marietta College
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Xiangbo Meng
University of Arkansas