Pomegranate rind-derived activated carbon as electrode material for high-performance supercapacitors
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- 作者:Furong Qin ; Kai Zhang ; Jie Li ; Yanqing Lai…
- 关键词:Activated carbon ; Electrode materials ; Pomegranate rind ; Supercapacitors
- 刊名:Journal of Solid State Electrochemistry
- 出版年:2016
- 出版时间:February 2016
- 年:2016
- 卷:20
- 期:2
- 页码:469-477
- 全文大小:2,262 KB
- 参考文献:1.Hao P, Zhao Z, Tian J, Li H, Sang Y, Yu G, Cai H, Liu H, Wong CP, Umar A (2014) Nanoscale 6:12120–12129CrossRef
2.Biswas S, Drzal LT (2010) ACS Appl Mater Interfaces 2:2293–2300CrossRef
3.Tamailarasan P, Ramaprabhu S (2012) J Phys Chem C 116:14179–14187CrossRef
4.Zhang JT, Zhao XS (2012) J Phys Chem C 116:5420–5426CrossRef
5.Han J, Zhang LL, Lee S, Oh J, Lee KS, Potts JR, Ji J, Zhao X, Ruoff RS, Park S (2013) ACS Nano 7:19–26CrossRef
6.Kim T, Jung G, Yoo S, Suh KS, Ruoff RS (2013) ACS Nano 7:6899–6905CrossRef
7.Xiong Z, Liao C, Wang X (2014) J Mater Chem A 2:19141–19144CrossRef
8.Kalugin ON, Chaban VV, Loskutov VV, Prezhdo OV (2008) Nano Lett 8:2126–2130CrossRef
9.Chen X, Wang HW, Yi H, Wang XF, Yan XR, Guo ZH (2014) J Phys Chem C 118:8262–8270CrossRef
10.Subramanian V, Luo C, Stephan AM, Nahm KS, Thomas S, Wei B (2007) J Phys Chem C 111:7527–7531CrossRef
11.Liu X, Zheng M, Xiao Y, Yang Y, Yang L, Liu Y, Lei B, Dong H, Zhang H, Fu H (2013) ACS Appl Mater Interfaces 5:4667–4677CrossRef
12.Liu X, Zhou L, Zhao Y, Bian L, Feng X, Pu Q (2013) ACS Appl Mater Interfaces 5:10280–10287CrossRef
13.Qian H, Kucernak AR, Greenhalgh ES, Bismarck A, Shaffer MS (2013) ACS Appl Mater Interfaces 5:6113–6122CrossRef
14.Sun H, He W, Zong C, Lu L (2013) ACS Appl Mater Interfaces 5:2261–2268CrossRef
15.Wang H, Chen Z, Liu HK, Guo Z (2014) RSC Adv 4:65074–65080CrossRef
16.Wang C, Wang Y (2013) ACS Nano 7:11156–11165CrossRef
17.Dai YH, Jiang H, Hu YJ, Fu Y, Li CZ (2014) Ind Eng Chem Res 53:3125–3130CrossRef
18.Kim C, Choi Y-O, Lee W-J, Yang K-S (2004) Electrochim Acta 50:883–887CrossRef
19.Lin J-H, Ko T-H, Lin Y-H, Pan C-K (2009) Energy Fuel 23:4668–4677CrossRef
20.Barranco V, Lillo-Rodenas MA, Linares-Solano A, Oya A, Pico F, Ibanez J, Agullo-Rueda F, Amarilla JM, Rojo JM (2010) J Phys Chem C 114:10302–10307CrossRef
21.Feng S, Li W, Wang J, Song Y, Elzatahry AA, Xia Y, Zhao D (2014) Nanoscale 6:14657–14661CrossRef
22.Balathanigaimani MS, Shim WG, Lee MJ, Kim C, Lee JW, Moon H (2008) Electrochem Commun 10:868–871CrossRef
23.Liu MC, Kong LB, Lu C, Li XM, Luo YC, Kang L (2012) RSC Adv 2:1890–1896CrossRef
24.Bhattacharjya D, Yu JS (2014) J Power Sources 262:224–231CrossRef
25.Wang Y, Zhang L, Wang H, Wang J, Yu W, Peng B, Yang Z, Chai L (2014) J Solid State Electrochem 18:3209–3214CrossRef
26.Zhang L, Wang Y, Peng B, Yu W, Wang H, Wang T, Deng B, Chai L, Zhang K, Wang J (2014) Green Chem 16:3926–3934CrossRef
27.Wang H, Li X, Chai L, Zhang L (2015) Chem Commun 51:8524–8527CrossRef
28.Wang S, Ren Z, Li J, Ren Y, Zhao L, Yu J (2014) RSC Adv 4:31300CrossRef
29.Rufford TE, Hulicova-Jurcakova D, Khosla K, Zhu Z, Lu GQ (2010) J Power Sources 195:912–918CrossRef
30.Ismanto AE, Wang S, Soetaredjo FE, Ismadji S (2010) Bioresour Technol 101:3534–3540CrossRef
31.He X, Ling P, Yu M, Wang X, Zhang X, Zheng M (2013) Electrochim Acta 105:635–641CrossRef
32.Biswal M, Banerjee A, Deo M, Ogale S (2013) Energy Environ Sci 6:1249–1259CrossRef
33.Raymundo-Piñero E, Cadek M, Béguin F (2009) Adv Funct Mater 19:1032–1039CrossRef
34.Groen JC, LAA P, Perez-Ramirez J (2003) Microporous Mesoporous Mater 60:1–17CrossRef
35.Elazari R, Salitra G, Garsuch A, Panchenko A, Aurbach D (2011) Adv Mater 23:5641–5644CrossRef
36.Puthusseri D, Aravindan V, Anothumakkool B, Kurungot S, Madhavi S, Ogale S (2014) Small 10:4395–4402
37.Chmiola J, Yushin G, Gogotsi Y, Portet C, Simon P, Taberna PL (2006) Science 313:1760–1763CrossRef
38.Kalpana D, Cho SH, Lee SB, Lee YS, Misra R, Renganathan NG (2009) J Power Sources 190:587–591CrossRef - 作者单位:Furong Qin (1)
Kai Zhang (1)
Jie Li (1)
Yanqing Lai (1)
Hai Lu (1)
Wenwen Liu (1)
Fan Yu (1)
Xiaoke Lei (1)
Jing Fang (1)
1. School of Metallurgy and Environment, Central South University, Changsha, 410083, China - 刊物类别:Chemistry and Materials Science
- 刊物主题:Chemistry
Physical Chemistry
Analytical Chemistry
Industrial Chemistry and Chemical Engineering
Characterization and Evaluation Materials
Condensed Matter
Electronic and Computer Engineering - 出版者:Springer Berlin / Heidelberg
- ISSN:1433-0768
文摘
In this paper, activated carbon materials were synthesized from pomegranate rind through carbonization and alkaline activation processes. The effects of pyrolytic temperature on the textual properties and electrochemical performance were investigated. The surface area of the activated carbon can reach at least 2200 m2 g−1 at different pyrolytic temperatures. It was found that, at the range of 600–900 °C, decreasing the carbonization temperature leads to the increase of t-plot micropore area, t-plot micropore volume, and capacitance. Further decreasing the carbonization temperature to 500 °C also leads to the increase of t-plot micropore area and t-plot micropore volume, but the capacitance is slightly poorer. The activated carbon carbonized at 600 °C and activated at 800 °C possesses very high specific area (2931 m2 g−1) and exhibits very high capacitance (∼268 F g−1 at 0.1 A g−1 and ∼242 F g−1 at 1 A g−1). There is no capacitance fading after 2000th cycle. Keywords Activated carbon Electrode materials Pomegranate rind Supercapacitors