Utilizing Waste Cable Wires for High‐Performance Fiber‐Based Hybrid Supercapacitors: An Effective Approach to Electronic‐Waste Management

In recent years, electronic waste (e‐waste) such as old cable wires, fans, circuit boards, etc., can be often seen in large piles of leftover in dumping yards. Employing these e‐waste sources for energy storage devices not only increases the economic value but also decreases the reliance on fossil f...

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Bibliographic Details
Published in:Advanced energy materials 2018-03, Vol.8 (7), p.n/a
Main Authors: Nagaraju, Goli, Sekhar, S. Chandra, Yu, Jae Su
Format: Article
Language:English
Subjects:
Activated carbon
Batteries
Braiding
Carbon
Carbon fibers
Carbon nanotubes
Circuit boards
Coated electrodes
Copper
copper fibers
Copper oxides
Electrochemical analysis
Electrodes
Electrolytes
Electronic devices
Electronic waste
energy density
Energy storage
fiber‐based supercapacitors
forest‐like composite materials
Fossil fuels
Nanowires
Nickel oxides
Supercapacitors
waste cable wires
Waste management
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Summary:In recent years, electronic waste (e‐waste) such as old cable wires, fans, circuit boards, etc., can be often seen in large piles of leftover in dumping yards. Employing these e‐waste sources for energy storage devices not only increases the economic value but also decreases the reliance on fossil fuels. In this context, waste cable wires are utilized to obtain precious copper (Cu) fibers and used as a cost‐effective current collector for the fabrication of fiber‐based hybrid supercapacitor (FHSC). With the braided Cu fibers, forest‐like nickel oxide nanosheet grafted carbon nanotube coupled copper oxide nanowire arrays (NiO NSs@CNTs@CuO NWAs/Cu fibers) are designed via simple wet‐chemical approaches. As a battery‐type material, the forest‐like NiO NSs@CNTs@CuO NWAs/Cu fiber electrode shows superior electrochemical properties including high specific capacity (230.48 mA h g−1) and cycling stability (82.72%) in aqueous alkaline electrolyte. Moreover, a solid‐state FHSC is also fabricated using forest‐like NiO NSs@CNTs@CuO NWAs/Cu fibers as a positive electrode and activated carbon coated carbon fibers as a negative electrode with a gel electrolyte, which also shows a higher energy and power densities of 26.32 W h kg−1 and 1218.33 W kg−1, respectively. The flexible FHSC is further employed as an energy source for various electronic gadgets, demonstrating its suitability for wearable applications. A cost‐effective fiber‐based hybrid supercapacitor is fabricated using waste cable wires. The forest‐like composite nanostructures coated on copper fibers serve as a positive electrode with superior electro­­chemical performance. Such rationally designed nanoarchitectures prepared on flexible and fiber‐based electrodes provide a step forward for the development of wearable energy storage devices with improved energy storage performance.
ISSN:1614-6832
1614-6840
DOI:10.1002/aenm.201702201