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NTIS 바로가기멤브레인 = Membrane Journal, v.32 no.1, 2022년, pp.43 - 49
문승재 (연세대학교 화공생명공학과) , 김영준 (연세대학교 화공생명공학과) , 강두루 (연세대학교 화공생명공학과) , 이소연 (연세대학교 화공생명공학과) , 김종학 (연세대학교 화공생명공학과)
Solid-state supercapacitors with high safety and robust mechanical properties are attracting global attention as next-generation energy storage devices. As an electrode of a supercapacitor, an economical carbon-based electrode is widely used. However, when an aqueous electrolyte is introduced, the c...
C. Zhong, Y. Deng, W. Hu, J. Qiao, L. Zhang, and J. Zhang, "A review of electrolyte materials and compositions for electrochemical supercapacitors", Chem. Soc. Rev., 44, 7484 (2015).
P. Li, T. Shang, X. Dong, H. Li, Y. Tao, and Q. H. Yang, "A Review of compact carbon design for supercapacitors with high volumetric performance", Small, 17, 2007548 (2021).
H. J. Min, M. S. Park, M. Kang, and J. H. Kim, "Excellent film-forming, ion-conductive, zwitterionic graft copolymer electrolytes for solid-state supercapacitors", Chem. Eng. J., 412, 127500 (2021).
P. Gajewski, and F. Beguin, "Hydrogel-polymer electrolyte for electrochemical capacitors with high volumetric energy and life span", ChemSusChem, 13, 1876 (2020).
H. Zhang, X. Liu, H. Li, I. Hasa, and S. Passerini, "Challenges and strategies for high-energy aqueous electrolyte rechargeable batteries", Angew. Chem. Int. Ed., 60, 598 (2021).
J. Huang, K. Yuan, and Y. Chen, "Wide voltage aqueous asymmetric supercapacitors: advances, strategies, and challenges", Adv. Funct. Mater., 2108107 (2021).
Q. Liu, J. Zhou, C. Song, X. Li, Z. Wang, J. Yang, J. Cheng, H. Li, and B. Wang, "2.2 V high performance symmetrical fiber-shaped aqueous supercapacitors enabled by "water-in-salt" gel electrolyte and N-Doped graphene fiber", Energy Storage Mater., 24, 495 (2020).
S. Thiemann, S. J. Sachnov, F. Pettersson, R. Bollstrom, R. Osterbacka, P. Wasserscheid, and J. Zaumseil, "Cellulose-based ionogels for paper electronics", Adv. Funct. Mater., 24, 625 (2014).
T. Mao, S. Wang, Z. Yong, X. Wang, X. Wang, H. Chen, G. Liu, D. Wang, and Z. Wang, "High-stable, outstanding heat resistance ionogel electrolyte and the poly(3,4-ethylenedioxythiophene) electrodes with excellent long-term stability for all-solid-state supercapacitor", Chem. Eng. J., 417, 129269 (2021).
J. Zhao, J. Gong, G. Wang, K. Zhu, K. Ye, J. Yan, and D. Cao, "A self-healing hydrogel electrolyte for flexible solid-state supercapacitors", Chem. Eng. J., 401, 125456 (2020).
M. Sandhiya, Vivekanand, S. Suresh Balaji, and M. Sathish, "Na 2 MoO 4 -Incorporated polymer gel electrolyte for high energy density flexible supercapacitor", ACS Appl. Energy Mater., 3, 11368 (2020).
H. Dai, G. Zhang, D. Rawach, C. Fu, C. Wang, X. Liu, M. Dubois, C. Lai, and S. Sun, "Polymer gel electrolytes for flexible supercapacitors: Recent progress, challenges, and perspectives", Energy Storage Mater., 34, 320 (2021).
J. Wu, G. Xia, S. Li, L. Wang, and J. Ma, "A flexible and self-healable gelled polymer electrolyte based on a dynamically cross-Linked PVA ionogel for high-performance supercapacitors", Ind. Eng. Chem. Res., 59, 22509 (2020).
C. S. Lee, S. H. Ahn, D. J. Kim, J. H. Lee, A. Manthiram, and J. H. Kim, "Flexible, all-solid-state 1.4 V symmetric supercapacitors with high energy density based on comb polymer electrolyte and 1D hierarchical carbon nanotube electrode", J. Power Sources, 474, 228477 (2020).
J. H. Lee, J. Y. Lim, J. T. Park, J. M. Lee, and J. H. Kim, "Polymethacrylate-comb-copolymer electrolyte for solid-state energy storage devices", Mater. Des., 149, 25 (2018).
S. J. Moon, H. J. Min, C. S. Lee, D. R. Kang, and J. H. Kim, "Adhesive, free-standing, partially fluorinated comb copolymer electrolyte films for solid flexible supercapacitors", Chem. Eng. J., 429, 132240 (2022).
D. A. Kang, K. Kim, S. S. Karade, H. Kim, and J. H. Kim, "High-performance solid-state bendable supercapacitors based on PEGBEM-g-PAEMA graft copolymer electrolyte", Chem. Eng. J., 384, 123308 (2020).
M. Fu, R. Lv, Y. Lei, and M. Terrones, "Ultralight flexible electrodes of nitrogen-doped carbon macrotube sponges for high-performance supercapacitors", Small, 17, 2004827 (2021).
G. Lota, J. Tyczkowski, R. Kapica, K. Lota, and E. Frackowiak, "Carbon materials modified by plasma treatment as electrodes for supercapacitors", J. Power Sources, 195, 7535 (2010).
Z. Hou, B. Cai, H. Liu, and D. Xu, "Ar, O 2 , CHF 3 , and SF 6 plasma treatments of screen-printed carbon nanotube films for electrode applications", Carbon, 46, 405 (2008).
I. Kondratowicz, M. Nadolska, S. Sahin, M. Lapinski, M. Przesniak-Welenc, M. Sawczak, H. Y. Eileen, W. Sadowski, and K. Zelechowska, "Tailoring properties of reduced graphene oxide by oxygen plasma treatment", Appl. Surf. Sci., 440, 651 (2018).
S. Ali, I. A. Shah, A. Ahmad, J. Nawab, and H. Huang, "Ar/O 2 plasma treatment of carbon nanotube membranes for enhanced removal of zinc from water and wastewater: A dynamic sorptionfiltration process", Sci. Total Environ., 655, 1270 (2019).
X. Yuan, L. Ma, J. Zhang, and Y. Zheng, "Simple pre-treatment by low-level oxygen plasma activates screen-printed carbon electrode: Potential for mass production", Appl. Surf. Sci., 544, 148760 (2021).
J. K. Kim, C. S. Lee, J. H. Lee, J. T. Park, and J. H. Kim, "Ni, Co-double hydroxide wire structures with controllable voids for electrodes of energy-storage devices", J. Mater. Sci. Technol., 55, 126 (2020).
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