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Design of high-performance binary carbonate/hydroxide Ni-based supercapacitors for photo-storage systems

Title
Design of high-performance binary carbonate/hydroxide Ni-based supercapacitors for photo-storage systems
Author(s)
Lee, DaminKeppetipola, Nilanka M.Kim, Dong-HwanRoh, Jong WookCojocaru, LudmilaToupance, ThierryKim, Jeongmin
Issued Date
2024-12
Citation
Energy, v.313
Type
Article
Author Keywords
Faradaic capacitorsSupercapacitorsBinary-transition metalPhoto-storageCarbonate hydroxideHydrothermal method
Keywords
LAYERED DOUBLE HYDROXIDESTEMPLATE-FREE SYNTHESISELECTRODE MATERIALSCUCO2O4 NANOSHEETS3D GRAPHENECO3O4NANOPARTICLESNANOFLAKESSPHERESSHELL
ISSN
0360-5442
Abstract
Silicon solar cells were used to convert solar energy into electrical energy, and a supercapacitor was designed to store this energy. To maximize the surface area of the electrodes, a three-dimensional Ni foam substrate was employed, onto which Ni-based compounds were deposited to enhance the electrochemical performance of the electrodes. Specifically, to address the conductivity reduction problem that arises when using only Ni ions, we introduced transition metal ions such as Mn, Co, Cu, Fe, and Zn to create binary compounds as electrode material. These binary metal compounds provided high electronic conductivity, structural stability, and reversible capacity, thereby optimizing the performance of the supercapacitor. As a result, the optimized NiCo(CO3)(OH)2 electrode demonstrated high capacity and excellent cycle stability, exhibiting an energy density of 35.5 Wh kg−1 and a power density of 2555.6 W kg−1 as an asymmetric supercapacitor device. Furthermore, when this device was combined directly with silicon solar cells, it achieved a storage efficiency of 63 % and an overall efficiency of 5.17 % under an illumination intensity of 10 mW cm−2. These findings suggest the potential for commercializing high-performance self-charging energy storage devices and contribute significantly to the advancement of energy storage technology. © 2024 Elsevier Ltd
URI
http://hdl.handle.net/20.500.11750/57201
DOI
10.1016/j.energy.2024.133593
Publisher
Elsevier
Related Researcher
  • 김정민 Kim, Jeongmin
  • Research Interests Transport Measurement in Low-dimensional Materials; 저차원소재 수송물성측정; Rare-earth Magnets for Electric Vehicle Traction Motors; 전기차 구동모터용 희토자석; Thermoelectric Materials; 열전소재
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Division of Nanotechnology 1. Journal Articles

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