石墨烯
材料科学
电池(电)
纳米技术
箔法
储能
纳米结构
能量密度
功率密度
氧化物
复合数
超级电容器
石墨
电容器
电极
混合材料
人口
纳米材料
氧化石墨
铜
电化学储能
电化学
电流密度
作者
Aswini Ramakrishnan,Akshay Manohar,Lee Yun-Sung,Vanchiappan Aravindan
摘要
ABSTRACT The rapid development of energy storage technologies has increased the demand for lithium‐based solutions due to their superior efficiency and scalability. Simultaneously, the growing global population and heavy reliance on electronic devices have resulted in substantial e‐waste generation. This study focuses on converting e‐waste, specifically spent battery components, into active materials for lithium‐ion capacitors (LICs). Through a straightforward wet‐chemical process, copper foil and graphite are recovered and converted into CuO‐NiO hybrid nanostructures and reduced graphene oxide (rGO), respectively. These materials are subsequently used as the negative and positive electrodes, respectively, in the LIC assembly. The fabricated half‐cell (Li/CuO‐NiO) demonstrated a reversible specific capacity of approximately 657 mAh g −1 . Prior to the LIC assembly with the rGO electrode, the hybrid nanostructures were pre‐lithiated (Cu 0 +Ni 0 +xLi 2 O). The assembled rGOǁ(Cu 0 +Ni 0 +xLi 2 O) LIC exhibited an energy density of 57.8 Wh kg −1 and a power density of 6.6 kW kg −1 , along with long cyclic stability. This approach emphasises the recycling of discarded battery components into functional active materials for LICs, presenting a sustainable pathway to convert e‐waste into high‐performance, value‐added products for next‐generation energy storage.
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