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Flexible solid-state supercapacitors based on shrunk high-density aligned carbon nanotube arrays

Zhu Qi Yuan Xie-Tao Zhu Yi-Hao Zhang Xiao-Hua Yang Zhao-Hui

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Flexible solid-state supercapacitors based on shrunk high-density aligned carbon nanotube arrays

Zhu Qi, Yuan Xie-Tao, Zhu Yi-Hao, Zhang Xiao-Hua, Yang Zhao-Hui
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  • Nowadays flexible solid-state supercapacitors (FSCs) have received more and more attention than conventional capacitors due to the good operability and flexible fabrication process as well as high specific/volumetric energy density. In general, carbon based materials including amorphous carbon, carbon nanotube, grapheme, etc. can be used to fabricate electrolytic double-layer capacitance (EDLC)-type FSCs due to its extraordinary cyclic stability at high current density. Aligned carbon nanotube (ACNT) arrays are one of the ideal electrode candidates for energy storage due to their good capacity, highly efficient charge transfer rate, excellent rate performance and long cycle life compared with those of other carbon-based materials carbon nanotubes. However, the low density and the weak interaction between the carbon tubes cause the CNT arrays to tend to easily collapse during processing and transferring. Thus pure carbon nanotube arrays are unable to be directly used to assemble flexible electronic devices. In this paper, we use ethyl alcohol to shrink the CNT array to increase the density and mechanical strength. At the same time we embed the conductive polyvingle alcohol (PVA) gel into the carbon nanotube array to fabricate a flexible solid supercapacitor. Hydrogel-based solid electrolytes have been long considered to be used to prepare FSCs, because this method possesses obvious advantages including low cost, good environmental compatibility and simple manufacturing process. The ACNT/PVA complex can maintain good mechanical stability and flexibility during its folding and bending, and can also keep the high orientation of carbon nanotubes. The maximum capacitance of the hybrid flexible device can reach 458 mFcm-3 at a current density of 10 mAcm-3, which is much higher than the capacitance reported in the literature. After 5000 charging-discharging cycles, a capacity still keeps nearly 100%. The maximum energy density of CNTs/gel composite device can reach 0.04 mWhcm-3 with an average power density of 3.7 mWcm-3. The capacitance can be further increased to 618 mFcm-3 by a simple in-situ electrochemical oxidation treatment. The energy density can be further increased to 0.07 mWhcm-3 by the electro-oxidation treatment. The electrochemical performance of the device is far superior to that of EDLC-typed FSC reported in the literature. Additionally the equivalent series resistance (RESR) of the devices decreases from 120 to 30 and also the charge transfer resistance declines from 90 to 10 . This is mainly due to the effect of pseudo capacitance and electro-wetting effect caused by electro-oxidation. This easy-to-assemble hybrid devices thus potentially pave the way for manufacturing wearable devices and implantable medical devices.
      Corresponding author: Yang Zhao-Hui, yangzhaohui@suda.edu.cn
    • Funds: Project supported by the National Natural Science Foundation of China (Grant No. 21204059), the Specially-Appointed Professor Plan in Jiangsu Province, China, and the State Key Laboratory of Separation Membranes and Membrane Processes, Tianjin Polytechnic University, China (Grant No. M2-201501).
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    Holdren J P 2007 Science 315 737

    [2]

    Arunachalam V S, Fleischer E L 2008 MRS Bull. 33 261

    [3]

    Wang K, Zhang X, Li C, Sun X, Meng Q, Ma Y, Wei Z 2015 Adv. Mater. 27 7451

    [4]

    Li Y, Xu J, Feng T, Yao Q, Xie J, Xia H 2017 Adv. Functional Mater. 27 1606728

    [5]

    Frackowiak E, Khomenko V, Jurewicz K, Lota K, Bguin F 2006 J. Power Sources 153 413

    [6]

    Zhai T, Wan L, Sun S, Chen Q, Sun J, Xia Q, Xia H 2017 Adv. Mater. 29 1604167

    [7]

    Lu X, Yu M, Wang G, Tong Y, Li Y 2014 Energy Environ. Sci. 7 2160

    [8]

    He Y, Chen W, Gao C, Zhou J, Li X, Xie E 2013 Nanoscale 5 8799

    [9]

    Yang P, Mai W 2014 Nano Energy 8 274

    [10]

    Liu L, Niu Z, Chen J 2016 Chem. Soc. Rev. 45 4340

    [11]

    Simon P, Gogotsi Y 2013 Accounts of Chemical Research 46 1094

    [12]

    Fic K, Lota G, Meller M, Frackowiak E 2012 Energy Environ. Sci. 5 5842

    [13]

    Lin Z, Zeng Z, Gui X, Tang Z, Zou M, Cao A 2016 Adv. Energy Mater. 6 1600554

    [14]

    Jiang H, Lee P S, Li C 2013 Energy Environ. Sci. 6 41

    [15]

    Zhang H, Cao G, Yang Y 2009 Energy Environ. Sci. 2 932

    [16]

    Talapatra S, Kar S, Pal S K, Vajtai R, Ci L, Victor P, Shaijumon M M, Kaur S, Nalamasu O, Ajayan P M 2006 Nature Nanotechnol. 1 112

    [17]

    Pushparaj V L, Shaijumon M M, Kumar A, Murugesan S, Ci L, Vajtai R, Linhardt R J, Nalamasu O, Ajayan P M 2007 Proc. Nat. Acad. Sci. USA 104 13574

    [18]

    Futaba D N, Hata K, Yamada T, Hiraoka T, Hayamizu Y, Kakudate Y, Tanaike O, Hatori H, Yumura M, Iijima S 2006 Nat. Mater. 5 987

    [19]

    Hata K, Futaba D N, Mizuno K, Namai T, Yumura M, Iijima S 2004 Science 306 1362

    [20]

    Liu Z, Liao G, Li S, Pan Y, Wang X, Weng Y, Zhang X, Yang Z 2013 J. Mater. Chem. A 1 13321

    [21]

    Hsia B, Marschewski J, Wang S, In J B, Carraro C, Poulikakos D, Grigoropoulos C P, Maboudian R 2014 Nanotechnology 25 055401

    [22]

    Kang Y J, Chung H, Han C H, Kim W 2012 Nanotechnology 23 065401

    [23]

    Kaempgen M, Chan C K, Ma J, Cui Y and Gruner G 2009 Nano Lett. 9 1872

    [24]

    El-Kady M F, Strong V, Dubin S, Kaner R B 2012 Science 335 1326

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Publishing process
  • Received Date:  17 August 2017
  • Accepted Date:  20 October 2017
  • Published Online:  20 January 2019

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