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H. Qian, A. Kucernak, E. Greenhalgh, A. Bismarck, M. Shaffer (2013)
Multifunctional structural supercapacitor composites based on carbon aerogel modified high performance carbon fiber fabric.ACS applied materials & interfaces, 5 13
B. Mas, J. Fernández‐Blázquez, Jonathan Duval, Humphrey Bunyan, J. Vilatela (2013)
Thermoset curing through Joule heating of nanocarbons for composite manufacture, repair and solderingCarbon, 63
Yuanbin Kang, Haegeun Chung, C. Han, Woong Kim (2012)
All-solid-state flexible supercapacitors based on papers coated with carbon nanotubes and ionic-liquid-based gel electrolytesNanotechnology, 23
R. Mora, J. Vilatela, A. Windle (2009)
Properties of composites of carbon nanotube fibresComposites Science and Technology, 69
Hengxing Ji, Xin Zhao, Z. Qiao, Jeil Jung, Yanwu Zhu, Yalin Lu, Li Zhang, A. Macdonald, R. Ruoff (2014)
Capacitance of carbon-based electrical double-layer capacitorsNature Communications, 5
Eric Jacques, M. Kjell, D. Zenkert, G. Lindbergh (2013)
Piezo-electrochemical effect in lithium-intercalated carbon fibresElectrochemistry Communications, 35
Yuqing Liu, B. Weng, J. Razal, Qun Xu, Chen Zhao, Yuyang Hou, Shayan Seyedin, R. Jalili, G. Wallace, Jun Chen (2015)
High-Performance Flexible All-Solid-State Supercapacitor from Large Free-Standing Graphene-PEDOT/PSS FilmsScientific Reports, 5
(1835)
Mater
Zhiyuan Xiong, C. Liao, Weihua Han, Xiaogong Wang (2015)
Mechanically Tough Large‐Area Hierarchical Porous Graphene Films for High‐Performance Flexible Supercapacitor ApplicationsAdvanced Materials, 27
Charan Masarapu, Lian-Ping Wang, Xin Li, B. Wei (2012)
Tailoring Electrode/Electrolyte Interfacial Properties in Flexible Supercapacitors by Applying PressureAdvanced Energy Materials, 2
M. Bayazıt, S. Hodge, A. Clancy, R. Menzel, Shu Chen, M. Shaffer (2016)
Carbon nanotube anions for the preparation of gold nanoparticle-nanocarbon hybrids.Chemical communications, 52 9
Y. Kumar, G. Pandey, S. Hashmi (2012)
Gel Polymer Electrolyte Based Electrical Double Layer Capacitors: Comparative Study with Multiwalled Carbon Nanotubes and Activated Carbon ElectrodesJournal of Physical Chemistry C, 116
Ramya Mantravadi, Parameswara Chinnam, D. Dikin, S. Wunder (2016)
High Conductivity, High Strength Solid Electrolytes Formed by in Situ Encapsulation of Ionic Liquids in Nanofibrillar Methyl Cellulose Networks.ACS applied materials & interfaces, 8 21
L. Asp, E. Greenhalgh (2014)
Structural power compositesComposites Science and Technology, 101
Yuanbin Kang, Yongju Yoo, Woong Kim (2016)
3-V Solid-State Flexible Supercapacitors with Ionic-Liquid-Based Polymer Gel Electrolyte for AC Line Filtering.ACS applied materials & interfaces, 8 22
Recep Yuksel, Zeynep Sarioba, A. Çırpan, P. Hiralal, H. Unalan (2014)
Transparent and flexible supercapacitors with single walled carbon nanotube thin film electrodes.ACS applied materials & interfaces, 6 17
O. Kimizuka, O. Tanaike, J. Yamashita, T. Hiraoka, D. Futaba, K. Hata, K. Machida, S. Suematsu, Kenji Tamamitsu, Susumu Saeki, Yoshio Yamada, H. Hatori (2008)
Electrochemical doping of pure single-walled carbon nanotubes used as supercapacitor electrodesCarbon, 46
J. Bisquert (2003)
Chemical capacitance of nanostructured semiconductors: its origin and significance for nanocomposite solar cellsPhysical Chemistry Chemical Physics, 5
Zhiqiang Niu, Weiya Zhou, Jun Chen, Guoxing Feng, Hong Li, Yong‐Sheng Hu, W. Ma, Haibo Dong, Jinzhu Li, S. Xie (2013)
A repeated halving approach to fabricate ultrathin single-walled carbon nanotube films for transparent supercapacitors.Small, 9 4
M. Schauer, M. White (2015)
Tailoring Industrial Scale CNT Production to Specialty MarketsMRS Proceedings, 1752
Ping Xu, Junmo Kang, Jae-boong Choi, J. Suhr, Jianyong Yu, Faxue Li, J. Byun, Byung-sun Kim, T. Chou (2014)
Laminated ultrathin chemical vapor deposition graphene films based stretchable and transparent high-rate supercapacitor.ACS nano, 8 9
E. Senokos, E. Senokos, V. Reguero, J. Palma, J. Vilatela, R. Marcilla (2016)
Macroscopic fibres of CNTs as electrodes for multifunctional electric double layer capacitors: from quantum capacitance to device performance.Nanoscale, 8 6
M. El‐Kady, R. Kaner (2013)
Scalable fabrication of high-power graphene micro-supercapacitors for flexible and on-chip energy storageNature Communications, 4
A. Westover, J. Tian, S. Bernath, L. Oakes, R. Edwards, F. Shabab, Shahana Chatterjee, A. Anilkumar, C. Pint (2014)
A multifunctional load-bearing solid-state supercapacitor.Nano letters, 14 6
M. El‐Kady, Veronica Strong, S. Dubin, R. Kaner (2012)
Laser Scribing of High-Performance and Flexible Graphene-Based Electrochemical CapacitorsScience, 335
Yuxi Xu, Zhaoyang Lin, Xiaoqing Huang, Yuan Liu, Yu Huang, X. Duan (2013)
Flexible solid-state supercapacitors based on three-dimensional graphene hydrogel films.ACS nano, 7 5
G. Pandey, S. Hashmi (2013)
Performance of solid-state supercapacitors with ionic liquid 1-ethyl-3-methylimidazolium tris(pentafluoroethyl) trifluorophosphate based gel polymer electrolyte and modified MWCNT electrodesElectrochimica Acta, 105
Zhiqiang Niu, Li Zhang, Lili Liu, Bowen Zhu, Haibo Dong, Xiaodong Chen (2013)
All‐Solid‐State Flexible Ultrathin Micro‐Supercapacitors Based on GrapheneAdvanced Materials, 25
Geyou Ao, Quanli Hu, M. Kim (2008)
Properties of Activated Carbon Blacks Filled SBR Rubber CompositesCarbon letters, 9
Ya-li Li, I. Kinloch, A. Windle (2004)
Direct Spinning of Carbon Nanotube Fibers from Chemical Vapor Deposition SynthesisScience, 304
Kezheng Gao, Ziqiang Shao, J. Li, Xi Wang, Xiaoqing Peng, Wenjun Wang, Feijun Wang (2013)
Cellulose nanofiber–graphene all solid-state flexible supercapacitorsJournal of Materials Chemistry, 1
Yuanbin Kang, S. Chun, Sung-Suk Lee, B. Kim, J. Kim, Haegeun Chung, Sunyoung Lee, Woong Kim (2012)
All-solid-state flexible supercapacitors fabricated with bacterial nanocellulose papers, carbon nanotubes, and triblock-copolymer ion gels.ACS nano, 6 7
Xu Xiao, Tianqi Li, Peihua Yang, Yuan Gao, Huanyu Jin, Wei-yuan Ni, Wenhui Zhan, Xianghui Zhang, Yuanzhi Cao, Junwen Zhong, L. Gong, Wen-Chun Yen, W. Mai, Jian Chen, K. Huo, Y. Chueh, Zhong Wang, Jun Zhou (2012)
Fiber-based all-solid-state flexible supercapacitors for self-powered systems.ACS nano, 6 10
J. Snyder, E. Gienger, E. Wetzel (2015)
Performance metrics for structural composites with electrochemical multifunctionalityJournal of Composite Materials, 49
R. Gibson (2010)
A review of recent research on mechanics of multifunctional composite materials and structuresComposite Structures, 92
Lirong Kong, Wei Chen (2014)
Ionic liquid directed assembly of wrinkled and porous composite electrode for high-power flexible supercapacitorsRSC Advances, 4
J. Vilatela, R. Marcilla (2015)
Tough Electrodes: Carbon Nanotube Fibers as the Ultimate Current Collectors/Active Material for Energy Management DevicesChemistry of Materials, 27
B. Alemán, Bartolome, Mas, Juan Jose, Vilatela (2014)
Controlling Carbon Nanotube Type in Macroscopic Fibers Synthesized by the Direct Spinning ProcessChemistry of Materials, 26
H. Jung, M. Karimi, M. Hahm, P. Ajayan, Y. Jung (2012)
Transparent, flexible supercapacitors from nano-engineered carbon filmsScientific Reports, 2
(2016)
All-inkjet-printed, solid-state flexible supercapacitors on paperEnergy and Environmental Science, 9
Bin Wang, Jinzhang Liu, F. Mirri, M. Pasquali, N. Motta, J. Holmes (2016)
High-performance graphene-based supercapacitors made by a scalable blade-coating approachNanotechnology, 27
Cheng Zhou, Jinping Liu (2014)
Carbon nanotube network film directly grown on carbon cloth for high-performance solid-state flexible supercapacitorsNanotechnology, 25
N. Shirshova, H. Qian, M. Shaffer, Joachim Steinke, E. Greenhalgh, Paul Curtis, A. Kucernak, A. Bismarck (2013)
Structural composite supercapacitorsComposites Part A-applied Science and Manufacturing, 46
D. Dunn, J. Newman (2000)
Predictions of Specific Energies and Specific Powers of Double‐Layer Capacitors Using a Simplified ModelJournal of The Electrochemical Society, 147
T. Chen, Yuhua Xue, A. Roy, L. Dai (2014)
Transparent and stretchable high-performance supercapacitors based on wrinkled graphene electrodes.ACS nano, 8 1
Longyan Yuan, Xihong Lu, Xu Xiao, Teng Zhai, J. Dai, Fengchao Zhang, Bin Hu, Xue Wang, L. Gong, Jian Chen, Chenguo Hu, Y. Tong, Jun Zhou, Zhong Wang (2012)
Flexible solid-state supercapacitors based on carbon nanoparticles/MnO2 nanorods hybrid structure.ACS nano, 6 1
Chuizhou Meng, Changhong Liu, Luzhuo Chen, C. Hu, S. Fan (2010)
Highly flexible and all-solid-state paperlike polymer supercapacitors.Nano letters, 10 10
B. Alemán, V. Reguero, B. Mas, J. Vilatela (2015)
Strong Carbon Nanotube Fibers by Drawing Inspiration from Polymer Fiber Spinning.ACS nano, 9 7
P. Yang, W. Cui, Libo Li, Lei Liu, M. An (2012)
Characterization and properties of ternary P(VdF-HFP)-LiTFSI-EMITFSI ionic liquid polymer electrolytesSolid State Sciences, 14
T. Chen, Huisheng Peng, M. Durstock, L. Dai (2014)
High-performance transparent and stretchable all-solid supercapacitors based on highly aligned carbon nanotube sheetsScientific Reports, 4
Kyu-Nam Jung, Ji-In Lee, Jong-Hyuk Jung, Kyung-Hee Shin, Jong‐Won Lee (2014)
A quasi-solid-state rechargeable lithium-oxygen battery based on a gel polymer electrolyte with an ionic liquid.Chemical communications, 50 41
Li-Feng Chen, Zhi-Hong Huang, Haiwei Liang, Wei-Tang Yao, Zi-You Yu, Shuhong Yu (2013)
Flexible all-solid-state high-power supercapacitor fabricated with nitrogen-doped carbon nanofiber electrode material derived from bacterial celluloseEnergy and Environmental Science, 6
Gerald Gourdin, A. Meehan, Thomas Jiang, Patricia Smith, D. Qu (2011)
Investigation of the impact of stacking pressure on a double-layer supercapacitorJournal of Power Sources, 196
This work presents a scalable method to produce robust all‐solid electric double layer capacitors (EDLCs), compatible with roll‐to‐roll processes and structural laminate composite fabrication. It consists in sandwiching and pressing an ionic liquid‐based polymer electrolyte membrane between two carbon nanotube (CNT) fiber sheet electrodes at room temperature, and laminating with ordinary plastic film. This fabrication method is demonstrated by assembling large‐area devices of up to 100 cm2 with electrodes fabricated in‐house, as well as with commercial CNT fiber sheets. Freestanding flexible devices operating at 3.5 V exhibit 28 F g−1 of specific capacitance, 11.4 W h kg−1 of energy density, and 46 kW kg−1 of power density. These values are nearly identical to control samples with pure ionic liquid. The solid EDLCs could be repeatedly bent and folded 180° without degradation of their properties, with a reversible 25% increase in energy density in the bent state. Devices produced using CNT fiber electrodes with a higher degree of orientation and therefore better mechanical properties show similar electrochemical properties combined with composite specific strength and modulus of 39 and 577 MPa SG−1 for a fiber mass fraction of 11 wt%, similar to a structural thermoplastic and with higher specific strength than copper.
Advanced Materials Technologies – Wiley
Published: Jul 1, 2017
Keywords: ; ; ; ;
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