2020
DOI: 10.1016/j.jechem.2019.06.009
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Dual-ion hybrid supercapacitor: Integration of Li-ion hybrid supercapacitor and dual-ion battery realized by porous graphitic carbon

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Cited by 41 publications
(23 citation statements)
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“…Recently, Zhan et al [ 64 ] fabricated a dual‐ion hybrid capacitors (Li‐dual‐ion hybrid supercapacitor [Li‐DIHSC] and lithium‐ion hybrid supercapacitors [Li‐HSC]) by the integration of a LIC and a DIB by using partially graphitized meso‐carbon microbeads (MCMB)‐based porous graphitic carbon (PGC) as the active material. The assembled device exhibited good EDLC behavior at the low to middle range potential as a LIC and exhibited additional plateau capacity with a pair of broad redox peaks at 4.5–5.0 V and 4–4.5 V corresponding to intercalation/deintercalation of the anion in the graphitic carbon as in DIB.…”
Section: Licsmentioning
confidence: 99%
“…Recently, Zhan et al [ 64 ] fabricated a dual‐ion hybrid capacitors (Li‐dual‐ion hybrid supercapacitor [Li‐DIHSC] and lithium‐ion hybrid supercapacitors [Li‐HSC]) by the integration of a LIC and a DIB by using partially graphitized meso‐carbon microbeads (MCMB)‐based porous graphitic carbon (PGC) as the active material. The assembled device exhibited good EDLC behavior at the low to middle range potential as a LIC and exhibited additional plateau capacity with a pair of broad redox peaks at 4.5–5.0 V and 4–4.5 V corresponding to intercalation/deintercalation of the anion in the graphitic carbon as in DIB.…”
Section: Licsmentioning
confidence: 99%
“…10a). Contrasting with conventional symmetric supercapacitors, the cathodes and anodes of LICs work within different electrochemical potential ranges [144][145][146][147]. In the charge process, Li ions in intercalates into anode to decrease the potential in this battery-type electrode, while anions are transported to the surface of cathode to elevate the voltage of this capacitor-type electrode [148,149].…”
Section: Controllable Self-sustaining Reaction With Comentioning
confidence: 99%
“…(3) The structure and configuration of carbon-based supercapacitor needs innovation to better support the practical application of novel carbon nanostructures and CO 2 conversion technology. New electrolytes with low viscosity and high conductivity should be tried in order to further improve the upper voltage limit of device, including high-voltage aqueous electrolytes, various organic solvents and conducting salts or modified aprotic ionic liquids or gel polymer electrolytes with higher ionic conductivity of (~10 -4 -10 -1 S cm À1 ) for flexible energy storage [147,[154][155]. In this case, the proper densification of carbon materials on thick electrodes should be taken into serious consideration, which should ensure both surface utilization and pore interconnection of active materials to effectively promote the volumetric energy storage level of device [156].…”
Section: Conclusion and Future Perspectivesmentioning
confidence: 99%
“…Hence, porous carbon-based materials, which permit more surface-like anion diffusion, are studied recently for dual-ion host with rapid charge/discharge capability and long life span, e.g. activated carbon, N-doped porous carbon foam and porous graphitic carbon [4][5][6]. However, given the low density of porous carbon-based materials, their application in compact devices may be limited [7].…”
Section: Introductionmentioning
confidence: 99%