Korean Journal of Chemical Engineering, Vol.36, No.2, 312-320, 2019
Mesoporous carbon nanofiber engineered for improved supercapacitor performance
Carbon nanofiber is a well-known carbon nanostructure employed in flexible supercapacitor electrode. Despite recent developments, improvement in the performance of carbon nanofiber-based electrode is still the subject of intense research. We investigated the supercapacitor performance of porosity-induced carbon nanofibers (CNFs). The fabrication process involves electrospinning, calcination, and subsequent etching. The porous CNF not only delivers a higher capacitance of 248 F/g at a current density of 1 A/g, but also exhibits a higher rate performance of 73.54%, lower charge transfer resistance and only 1.1% capacitance loss after 2000 charge-discharge cycles, compared to pristine CNF. The excellent electrochemical behavior of porous CNF is correlated with the degree of graphitization, a higher volume of mesopores, and enhanced surface area. The as-fabricated symmetric device comprising porous CNF exhibits an energy density of 9.9Wh/kg, the power density of 0.69 kW/kg and capacitance retention of 89% after 5000 charge-discharge cycles. The introduction of porosity in CNFs is a promising strategy to achieve high-performance supercapacitor electrode.
[References]
Lin Z, Goikolea E, Balducci A, Naoi K, Taberna PL, Salanne M, Yushin G, Simon P, Mater. Today , 21 , 419, 2018
Conway BE, Electrochemical supercapacitors, Kluwer Academic/Plenum Publishers (1999).
Borenstein A, Hanna O, Attias R, Luski S, Brousse T, Aurbach D, J. Mater. Chem. A , 5 , 12653, 2017
Xia L, Yu L, Hu D, Chen GZ, Mater. Chem. Front. , 1 , 584, 2017
Inagaki M, Konno H, Tanaike O, J. Power Sources , 195 (24), 7880, 2010
Ghosh S, Jeong SM, Polaki SR, Korean J. Chem. Eng. , 35 (7), 1389, 2018
Jin EM, Lim JG, Jeong SM, J. Ind. Eng. Chem. , 54 , 421, 2017
Sahoo G, Polaki SR, Ghosh S, Krishna NG, Kamruddin M, J. Power Sources , 401 , 37, 2018
Ghosh S, Polaki SR, Ajikumar P, Krishna NG, Kamruddin M, Indian J. Phys. , 92 , 337, 2018
Schutter C, Ramirez-Castro C, Oljaca M, Passerini S, Winter M, Balducci A, J. Electrochem. Soc. , 162 (1), A44, 2015
Chodankar NR, Ji SH, Kim DH, J. Electrochem. Soc. , 165 (11), A2446, 2018
Ghosh S, Sahoo G, Polaki SR, Krishna NG, Kamruddin M, Mathews T, J. Appl. Phys. , 122 , 214902, 2017
Mao X, Hatton TA, Rutledge GC, Curr. Org. Chem. , 17 , 1390, 2013
Choudhury A, Dey B, Mahapatra SS, Kim DW, Yang KS, Yang DJ, Nanotechnology , 29 , 165401, 2018
Islam N, Hoque MNF, Zu Y, Wang S, Fan Z, MRS Adv. , 3 , 855, 2018
Kim C, Yang KS, Lee WJ, Electrochem. Solid State Lett. , 7 (11), A397, 2004
Samuel E, Joshi B, Jo HS, Kim YI, An S, Swihart MT, Yun JM, Kim KH, Yoon SS, Chem. Eng. J. , 328 , 776, 2017
Kim CH, Kim BH, J. Power Sources , 274 , 512, 2015
Cakici M, Reddy KR, Alonso-Marroquin F, Chem. Eng. J. , 309 , 151, 2017
Lee WJ, Jeong SM, Lee H, Kim BJJ, An KH, Park YK, Jung SC, Korean J. Chem. Eng. , 34 (11), 2993, 2017
Inagaki M, Yang Y, Kang FY, Adv. Mater. , 24 (19), 2547, 2012
Kim C, Yang K, Appl. Phys. Lett. , 83 , 1216, 2003
Zhou DD, Li WY, Dong XL, Wang YG, Wang CX, Xia YY, J. Mater. Chem. A , 1 , 8488, 2013
Park SJ, Im SH, Bull. Korean Chem. Soc. , 29 , 777, 2008
Liu Y, Zhou J, Chen L, Zhang P, Fu W, Zhao H, Ma Y, Pan X, Zhang Z, Han W, Xie E, ACS Appl. Mater. Interfaces , 7 , 23515, 2015
Wang J, Tang J, Xu Y, Ding B, Chang Z, Wang Y, Hao X, Dou H, Kim JH, Zhang X, Yamauchi Y, Nano Energy , 28 , 232, 2016
Kim M, Kim Y, Lee KM, Jeong SY, Lee E, Baeck SH, Shim SE, Carbon , 99 , 607, 2016
Jeong JH, Kim BH, J. Taiwan Inst. Chem. Eng. , 84 , 179, 2018
Kim YS, Kumar K, Fisher FT, Yang EH, Nanotechnology , 23 , 015301, 2012
Fan L, Yang L, Ni X, Han J, Guo R, Zhang C, Carbon , 107 , 629, 2016
Ghosh S, Mathews T, Gupta B, Das A, Krishna NG, Kamruddin M, Nano-Struct. Nano-Objects , 10 , 42, 2017
Ismar E, Karazehir T, Ates M, Sarac AS, J. Appl. Polym. Sci. , 135 , 45723, 2018
Stoller MD, Ruoff RS, Energy Environ. Sci. , 3 , 1294, 2010
Ding R, Wu H, Thunga M, Bowler N, Kessler MR, Carbon , 100 , 126, 2016
Ghosh S, Ganesan K, Polaki SR, Mathews T, Dhara S, Kamruddin M, Tyagi AK, Appl. Surf. Sci. , 349 , 576, 2015
Sahoo G, Polaki SR, Ghosh S, Krishna NG, Kamruddin M, Ostrikov K, Energy Storage Mater. , 14 , 297, 2018
Ghosh S, Polaki SR, Kamruddin M, Jeong SM, Ostrikov KK, J. Phys. D-Appl. Phys. , 51 , 145303, 2018
Kim BH, Yang KS, J. Ind. Eng. Chem. , 20 (5), 3474, 2014
Chee WK, Lim HN, Zainal Z, Harrison I, Andou Y, Huang NM, Altarawneh M, Jiang ZT, Mater. Lett. , 199 , 200, 2017
Cheng Y, Huang L, Xiao X, Yao B, Yuan L, Li T, Hu Z, Wang B, Wan J, Zhou J, Nano Energy , 15 , 66, 2015
Dong Q, Wang G, Hu H, Yang J, Qian BQ, Ling Z, Qiu JS, J. Power Sources , 243 , 350, 2013
Hong S, Lee S, Paik U, Electrochim. Acta , 141 , 39, 2014
Eftekhari A, J. Mater. Chem. A , 6 , 2866, 2018
Cai J, Niu HT, Wang HX, Shao H, Fang J, He JR, Xiong HG, Ma CJ, Lin T, J. Power Sources , 324 , 302, 2016
Sankar KV, Selvan RK, RSC Adv. , 4 , 17555, 2014
[Cited By]
Saroha R, Ahn JH, Cho JS, Korean Journal of Chemical Engineering , 38 (3), 461, 2021
Baasanjav E, Bandyopadhyay P, Saeed G, Lim SM, Jeong SM, Journal of Industrial and Engineering Chemistry , 99 , 299, 2021
Chang HS, Lee BM, Yun JM, Choi JH, Korean Journal of Chemical Engineering , 39 (5), 1232, 2022
Ramkumar R, Dhakal G, Shim JJ, Kim WK, Korean Journal of Chemical Engineering , 39 (8), 2192, 2022
이전 논문 다음 논문
Result Search