Three-dimensional hierarchical self-supported NiCo<sub>2</sub>O<sub>4</sub>/carbon nanotube core–shell networks as high performance supercapacitor electrodes

Li, Xiaocheng; Sun, Wei; Wang, Liqun; Qi, Yongdong; Guo, T.; Zhao, Xinqing; Yan, Xingbin

doi:10.1039/c4ra09048a

Cited by 53 publications

(21 citation statements)

References 58 publications

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“…Hence these are effectively utilized in variety of applications such as electromechanical actuators, 1 field-effect transistors, 2 sensors, 3 catalyst support materials for proton exchange membrane fuel cells, 4 electrodes for supercapacitors, 5 etc. Hence these are effectively utilized in variety of applications such as electromechanical actuators, 1 field-effect transistors, 2 sensors, 3 catalyst support materials for proton exchange membrane fuel cells, 4 electrodes for supercapacitors, 5 etc.…”

Section: Introductionmentioning

confidence: 99%

Self-standing carbon nanotube forest electrodes for flexible supercapacitors

Cherusseri

Kar

2015

RSC Adv.

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Self-standing, vertically aligned carbon nanotube forest grown on unidirectional carbon fibers have been fabricated by using chemical vapour deposition. The vertically aligned carbon nanotube forest grown on carbon fiber (VACNTF/UCF) was further used as electrode-cumcurrent collector integrated system for fabricating a flexible supercapacitor. Highly bendable, electrically conductive unidirectional carbon fibers were used both as substrate for the growth of carbon nanotube forest and as current collectors for the supercapacitor. No other separate current collectors were used in this study. The Brunauer-Emmett-Teller surface area of VACNTF/UCF is found to be 553.8 m 2 g -1 . The flexibility of VACNTF/UCF supercapacitor is tested by galvanostatic charge/discharge measurements by bending the supercapacitor at various angles. No significant variations in the supercapacitive properties were observed at different bending angles. Galvanostatic charge/discharge measurements show that the supercapacitor exhibits a volume specific capacitance of 3.4 F cm -3 with a high volume specific power density of 1195 mW cm -3 . The VACNTF/UCF supercapacitor also exhibits good cycling stability of more than 27000 cycles.3 for supercapacitors require properties such as large surface area, good electronic conductivity, and low mass density. 6-8 As a result CNTs are the best candidates those can fulfil these requirements.Among the various available methods of CNT production, chemical vapor deposition (CVD) is more suitable due to its simplicity. 9,10 The preparation of CNT electrodes for supercapacitors include electrochemical deposition of CNTs on to electrically conducting substrates such as metal plates. 11,12 These substrates are further used as secondary current collectors while assembling the supercapacitor device. But a major drawback of electrophoretic deposition method is that the procedure increases the contact resistance between the CNTs and substrate. An increased electrochemical series resistance is found to condemn the performance of the supercapacitor. 13 Another drawback of using CNTs in an electrochemical deposition bath is the formation of aggregates in the form of CNT bundles by joining tens to hundreds of nanotubes together. CNTs may joined in parallel and entangled manner in order to form a hair-ball like structure with a reduction in its specific surface area.This results in decaying the electrochemical properties as the CNT electrode/electrolyte interaction diminishes due to its lower surface area. A best solution to these problems is avoiding the electrochemical deposition used for manufacturing the CNT electrodes and synthesize CNTs directly on carbon substrates by CVD. By this way, CNTs grown on carbon substrates help in reducing the electrochemical series resistance and also avoids the electrochemical deposition for manufacturing the CNT electrodes for supercapacitors.Agnihotri et al. have used carbon fibers as substrate for the growth of entangled CNTs with less density 14 but they couldn't achieve vertically ...

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Section: Introductionmentioning

confidence: 99%

Self-standing carbon nanotube forest electrodes for flexible supercapacitors

Cherusseri

Kar

2015

RSC Adv.

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“…Among the various hybrid electrode materials, C-TMO composite has gained particular interest since it combines the advantages of both components while reducing their shortcomings. [36,60,[72][73][74][75] Here, we present recent development on the preparation of C-TMO composite material as an active electrode towards SCs. This section will give insight on the specific role of carbon as well as TMOs, with particular emphasis on the carbon as active support, core element, and conductive substrate.…”

Section: Recent Progress In the Development Of C-tmo Hybrid Electrodementioning

confidence: 99%

“…In particular, the distinct rectangular CV curve at lower potential window was due to the electric double layer formed between the electrode and hydroxyl ions, and the pair of clear redox peaks displayed at higher potential is an indication of the rapid and reversible redox reactions between metal and hydroxyl ions. [74,81] Attributed to the synergistic effects of CNF and NCO, the hybrid material displays high specific capacitance and energy density of 1188.19 F g À 1 and 37.23 W. h kg À 1 , respectively even at high current density of 50 A g À 1 . Similarly, Nitin et al reported the facile and efficient glycine-assisted hydrothermal route for the cube-like iron oxide nanoparticles supported on ordered multimodal porous carbon (OMPC).…”

Section: Carbon As Active Supportmentioning

confidence: 99%

Carbon Transition‐metal Oxide Electrodes: Understanding the Role of Surface Engineering for High Energy Density Supercapacitors

Tomboc

Gadisa

Jun

et al. 2020

Chemistry An Asian Journal

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Supercapacitors store electrical energy by ion adsorption at the interface of the electrode-electrolyte (electric double layer capacitance, EDLC) or through faradaic process involving direct transfer of electrons via oxidation/ reduction reactions at one electrode to the other (pseudocapacitance). The present minireview describes the recent developments and progress of carbon-transition metal oxides (C-TMO) hybrid materials that show great promise as an efficient electrode towards supercapacitors among various material types. The review describes the synthetic methods and electrode preparation techniques along with the changes in the physical and chemical properties of each component in the hybrid materials. The critical factors in deriving both EDLC and pseudocapacitance storage mechanisms are also identified in the hope of pointing to the successful hybrid design principles. For example, a robust carbon-metal oxide interaction was identified as most important in facilitating the charge transfer process and activating high energy storage mechanism, and thus methodologies to establish a strong carbon-metal oxide contact are discussed. Finally, this article concludes with suggestions for the future development of the fabrication of high-performance C-TMO hybrid supercapacitor electrodes.[a] Dr.

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“…Carbon nanotubes (CNTs), have been introduced to increase the conductivity and cycle life of Ni(OH) 2 due to theirs well-defined nanostructure, high electrical conductivity and chemical stability, [21][22]. Recently, many works of CNTs/NiO or CNTs/Ni(OH) 2 have been reported, such as three-dimensional hierarchical self-supported NiCo 2 O 4 /carbon nanotube core-shell networks [23], ultrathin β Ni(OH) 2 nanoplates vertically grown on nickel-coated carbon nanotubes [24], and carbon nanotube/NiO x (OH) y nanocomposite [25]. But, the degradation in specific capacitance caused by the materials aggregation is also a handicap to provide excellent electrochemical stability and cycle life [26].…”

Section: Introductionmentioning

confidence: 99%

Lamellar-crossing-structured Ni(OH)2/CNTs/Ni(OH)2 nanocomposite for electrochemical supercapacitor materials

Wang

Wen

Chen

et al. 2015

Journal of Alloys and Compounds

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Three-dimensional hierarchical self-supported NiCo₂O₄/carbon nanotube core–shell networks as high performance supercapacitor electrodes

Cited by 53 publications

References 58 publications

Self-standing carbon nanotube forest electrodes for flexible supercapacitors

Self-standing carbon nanotube forest electrodes for flexible supercapacitors

Carbon Transition‐metal Oxide Electrodes: Understanding the Role of Surface Engineering for High Energy Density Supercapacitors

Lamellar-crossing-structured Ni(OH)2/CNTs/Ni(OH)2 nanocomposite for electrochemical supercapacitor materials

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Three-dimensional hierarchical self-supported NiCo2O4/carbon nanotube core–shell networks as high performance supercapacitor electrodes

Cited by 53 publications

References 58 publications

Self-standing carbon nanotube forest electrodes for flexible supercapacitors

Self-standing carbon nanotube forest electrodes for flexible supercapacitors

Carbon Transition‐metal Oxide Electrodes: Understanding the Role of Surface Engineering for High Energy Density Supercapacitors

Lamellar-crossing-structured Ni(OH)2/CNTs/Ni(OH)2 nanocomposite for electrochemical supercapacitor materials

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Three-dimensional hierarchical self-supported NiCo₂O₄/carbon nanotube core–shell networks as high performance supercapacitor electrodes