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Sustainable Energy. 2022, 10(1), 29-42
DOI: 10.12691/rse-10-1-3
Open AccessReview Article

Review of Recent Advances of Supercapacitors Energy Storage Systems

A. T. Jee1, Jehad H. Alsluimani1, A. S. Alqurashi1, A. A. Akkur1 and Ahmed M. Nahhas1,

1Department of Electrical Engineering, Faculty of Engineering and Islamic Architecture, Umm Al Qura University, Makkah, Saudi Arabia

Pub. Date: October 16, 2022
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Cite this paper:
A. T. Jee, Jehad H. Alsluimani, A. S. Alqurashi, A. A. Akkur and Ahmed M. Nahhas. Review of Recent Advances of Supercapacitors Energy Storage Systems. Sustainable Energy. 2022; 10(1):29-42. doi: 10.12691/rse-10-1-3

Abstract

This paper presents a review of the recent advances of the supercapacitors energy storage systems. The recent development of the supercapacitors devices is presented and discussed. The need for highly dependable backup and emergency power is fueling growth in the energy storage and power transmission industries. One of the most advanced types of energy storage devices is the supercapacitor. At the electrode-electrolyte interface, these supercapacitors can store electrical charge in an electric double layer. Different materials are considered for creating the supercapacitors, such as graphene, carbon black, and charcoal. This paper focuses on the electrode material, rare earth and their composites-based electrode materials for supercapacitors, atomic layer deposition in the development of transition-metal-oxide and conducting polymer-based fibers for supercapacitors, and atomic layer deposition in the development of transition-metal-oxide and conducting polymer-based fibers for supercapacitors.

Keywords:
supercapacitors storage electrode material rare earth atomic layer deposition energy storage

Creative CommonsThis work is licensed under a Creative Commons Attribution 4.0 International License. To view a copy of this license, visit http://creativecommons.org/licenses/by/4.0/

References:

[1]  Zhu, F., Yang, Z., Xia, H., Fei, L, “Hierarchical Control and Ful Range Dynamic Performance Optimization of the Supercapacitor Energy Storage System in Urban Railway,” IEEE Transactions on Industrial Electronics, 65, 8, 6646-6656, 2018.
 
[2]  “Maxwell Technologies; Document number: 3000489.1, <. com>.”.
 
[3]  Allaoua, B., Asnoune, K., Mebarki, B. “Energy management of PEM fuel cell/supercapacitor hybrid power sources for an electric vehicle” Int. J. Hydrog. Energy, 42,21158-21166, 2017.
 
[4]  Liu, C., Wang Y., Chen Z., Ling Q. “A variable capacitance-based modeling and power capability predicting method for supercapacitors”. J. Power Sources 374,121e33, 2018.
 
[5]  Feroldi, D. Serra, M. Riera, J. “Energy management strategies based on efficiency map for fuel cell hybrid vehicles”, J. Power Sources 190, 2,387-401, 2020.
 
[6]  Conway, B. “Electrochemical Capacitors: Scientific Fundamentals and Technological Applications”, Kluwer Academic / Plenum, 2018.
 
[7]  Xiong, R. Duan, Y. Cao, J. et al., “Battery and supercapacitors in-the-loop approach to validate a real-time power management method for an all-climate electric vehicle”, Appl. Energy 217, 153-165, 2018.
 
[8]  Andrew B., “Supercapacitors: why, how, and where is the technology” Institute of Transportation Studies, University of California-Davis, Davis, USA.
 
[9]  Wang Y., Sun Z., Chen Z. “Energy management strategy for battery/supercapacitor/fuel cell hybrid source vehicles based on finite state machine” Appl Energy 254,113707, 2019.
 
[10]  Rocabert, J. Capَ-Misut, R. Muٌoz-Aguilar, R.S. Candela, J.I. Rodriguez, P. “Control of energy storage system integrating electrochemical batteries and supercapacitors for grid-connected applications”, IEEE Trans. Ind. Appl. 55 ,2,1853-1862, 2018.
 
[11]  Xu, L. Mueller, C.D. Li, J. Ouyang, Hu, M Z. “Multi-objective component sizing based on optimal energy management strategy of fuel cell electric vehicles”, Appl. Energy 157 664-674, 2019.
 
[12]  Wieczorek, M. Lewandowski, M. “A mathematical representation of an energy management strategy for hybrid energy storage system in electric vehicle and real time optimization using a genetic algorithm”, Appl. Energy 192, 222-233, 2017.
 
[13]  Noor I. Jalal et al, “A review on Supercapacitors: types and components. J. Phys,1973 012015, 2021.
 
[14]  Eftekhar, A., “The mechanism of ultrafast supercapacitors” J. Mater. Chem. A,6, 2866, 2018.
 
[15]  Patel, K., Singhal, T., Pandey, V., Sumangala, T. and Sreekanth, M., “Evolution and recent developments of high-performance electrode material for supercapacitors: A review” Journal of Energy Storage, 44, p.103366, 2021.
 
[16]  Arunachalam, S., Kirubasankar, B., Pan, D., Liu, H., Yan, C., Guo, Z. and Angaiah, S., “Research progress in rare earths and their composites-based electrode materials for supercapacitors”. Green Energy & Environment, 5, 3, 259-273, 2020.
 
[17]  Li, Z., Su, J. and Wang, X., “Atomic layer deposition in the development of supercapacitor and lithium-ion battery devices” Carbon, 179, 299-326, 2021.
 
[18]  Mohd Abdah, M. Azman, N. Kulandaivalu S. and Sulaiman, Y. “Review of the use of transition-metal-oxide and conducting polymer-based fibers for high-performance supercapacitors”, Materials & Design, 186, 108199, 2020.
 
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